Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

MicroRNA-3906 Regulates Fast Muscle Differentiation through Modulating the Target Gene homer-1b in Zebrafish Embryos

  • Cheng-Yung Lin,

    Affiliation Institute of Molecular and Cellular Biology, National Taiwan University, Taipei, Taiwan

  • Jie-Shin Chen,

    Affiliation Institute of Molecular and Cellular Biology, National Taiwan University, Taipei, Taiwan

  • Moo-Rung Loo,

    Affiliation Institute of Molecular and Cellular Biology, National Taiwan University, Taipei, Taiwan

  • Chung-Ching Hsiao,

    Affiliation Institute of Molecular and Cellular Biology, National Taiwan University, Taipei, Taiwan

  • Wen-Yen Chang,

    Affiliation Institute of Molecular and Cellular Biology, National Taiwan University, Taipei, Taiwan

  • Huai-Jen Tsai

    hjtsai@ntu.edu.tw

    Affiliation Institute of Molecular and Cellular Biology, National Taiwan University, Taipei, Taiwan

Abstract

A microRNA, termed miR-In300 or miR-3906, suppresses the transcription of myf5 through silencing dickkopf-related protein 3 (dkk3r/dkk3a) during early development when myf5 is highly transcribed, but not at late stages when myf5 transcription is reduced. Moreover, after 24 hpf, when muscle cells are starting to differentiate, Dkk3a could not be detected in muscle tissue at 20 hpf. To explain these reversals, we collected embryos at 32 hpf, performed assays, and identified homer-1b, which regulates calcium release from sarcoplasmic reticulum, as the target gene of miR-3906. We further found that either miR-3906 knockdown or homer-1b overexpression increased expressions of fmhc4 and atp2a1 of calcium-dependent fast muscle fibrils, but not slow muscle fibrils, and caused a severe disruption of sarcomeric actin and Z-disc structure. Additionally, compared to control embryos, the intracellular calcium concentration ([Ca2+]i) of these treated embryos was increased as high as 83.9–97.3% in fast muscle. In contrast, either miR-3906 overexpression or homer-1b knockdown caused decreases of [Ca2+]i and, correspondingly, defective phenotypes in fast muscle. These defects could be rescued by inducing homer-1b expression at later stage. These results indicate that miR-3906 controls [Ca2+]i homeostasis in fast muscle through fine tuning homer-1b expression during differentiation to maintain normal muscle development.

Introduction

MicroRNAs (miRNAs) are short (19–22 nt) endogenous non-coding RNAs that regulate gene expression at the post-transcriptional level by binding the seed sequence(s) located at the 3′-untranslated region (3′UTR) of target mRNA(s), resulting in degradation, deadenylation or activation of target mRNA(s) [1][3]. Therefore, miRNAs play important roles in translational control by fine tuning the protein level to reach a dynamic equilibrium in cells.

In vertebrates, the regulatory mechanisms of many myogenic genes involved in muscle development at the transcriptional level have been studied [4]. Skeletal muscle development is mainly controlled by myogenic regulatory factors (MRFs), including myogenic factor 5 (myf5), myoblast determination protein (myod), muscle-specific regulatory factor 4 (mrf4; also known as myf6) and myogenin (myog), which enable activation of muscle-specific gene expression [5]. Several muscle-specific miRNAs were found in higher vertebrates, and it is known that these miRNAs are involved in muscle development at the translational level [6]. For example, the main function of miR-1, miR-133 and miR-206 is inhibition of their target genes in order to promote differentiation of muscle cells [7][9]. Both miR-208b and miR-499, which are expressed in skeletal muscles, regulate the specification of muscle fiber identity by activating slow myofiber genes, while repressing fast myofiber genes [10]. The target genes for zebrafish miR-1 and miR-133 are involved in actin-binding, as well as actin-related and vesicular transport [11]. Absence of miR-1 and miR-133 by co-injection of mopholinos (MOs) into embryos disturbs the organization of actin in muscle fibers. The expressions of miR-1, miR-133, miR-206 and miR-208 in muscle cells are mainly controlled by MRFs, serum response factor (SRF) and MEF2 [12][15].

In a previous study, we identified a 300-nucleotide repressive cis-element located at the first intron of zebrafish myf5, which is able to inhibit the promoter activity of myf5 [16]. Upon further study, we uncovered a novel miRNA, termed miR-3906, or miR-In300, which exists in this intron [17]. During early embryonic muscle development, we used our Labeled miRNA pull-down (LAMP) assay [18] to search for the putative target genes of miR-3906 from extracts of embryos at 16 hpf when myf5 expression reaches its highest expression during embryogenesis [19]. We found that dickkopf-related protein 3 (dkk3r/dkk3a) is the target gene of miR-3906 [17]. Dkk3a is an activator which controls the ability of zebrafish myf5 promoter to affect trunk muscle development through phosphorylated p38a-dependent Smad4 activity [20]. However, in mature trunk somites, miR-3906 silences Dkk3a production through binding the 3′UTR of dkk3a mRNA, resulting in the decrease of myf5 promoter activity and, hence, the reduction of Myf5 in mature somites [17]. Therefore, the intronic element of host gene myf5 produces miR-3906 to silence the upstream regulator Dkk3a, which, in turn, serves as a negative modulator of control.

Based on whole-mount in situ hybridization (WISH) analysis of embryos at 20 hpf, myf5 is expressed in the newly forming somites, but absent in mature somites. On the other hand, miR-3906 is absent in the newly forming somites, but present in mature somites, gradually enhancing its expression as somites mature [17]. This finding indicates that miR-3906 is derived from the myf5 transcripts in somites. In a previous study, we used LAMP to search for the target gene of miR-3906 in 16-hpf embryos when the muscle cells are at the stages of specification and proliferation. However, at the later developmental stages, e.g., after 24 hpf, when muscle cells are starting to differentiate, we noticed that Dkk3a could not be detected in muscle tissue at 20 hpf [17]. Since the promoter activity of myf5 is no longer activated by Dkk3a, myf5 is greatly reduced in the trunk, resulting in the differentiation of muscle cells. Thus, when muscle cells are at the differentiation stage, we do not know (a) the status of miR-3906 expression in somites, (b) the target gene of miR-3906, or (c) the biological function of miR-3906 in the context of its target gene during late developmental stage.

In general, target genes that are predicted, either from bioinformatics methods or from cell lines, cannot be easily attached to particular developmental stages. Therefore, to learn how miR-3906 functions in muscle development at late stage through controlling the target gene, we collected embryos at late stage, such as 32 hpf, when muscle development is at the differentiation stage, and performed a LAMP assay combined with Zebrafish Whole Genome Microarray to obtain putative target genes of miR-3906. We identified homer-1b, which is a scaffolding protein that binds ryanodine receptor to regulate calcium release from sarcoplasmic reticulum [21], as a target of miR-3906 at late stage in embryos. While dkk3a had previously been identified as the target gene of miR-3906 at early developmental stage [17], assays performed on embryos collected at 32 hpf indicated that both miR-3906 and homer-1b are expressed in mature somites and that their presence affects the expressions of fmhc4 and atp2a1 of calcium-dependent fast muscle fibrils, but not slow muscle fibrils. Finally, miR-3906 was found to control homeostasis of intracellular calcium concentration ([Ca2+]i) in fast muscle fibrils during differentiation through fine tuning homer-1b expression.

Materials and Methods

Fish Embryos

The wild-type zebrafish (Danio rerio) AB strain (University of Oregon, Eugene, OR) and the transgenic line Tg(α-actin:RFP) [22] were used. They were cultured at 28.5°C under a light and dark cycle of 14 and 10 hours, respectively. Production and stage identification of embryos followed the description by Westerfield [23] and Kimmel et al. [24]. For drug treatment, WT embryos at 20 hpf were moved from clean water and soaked in water containing 150 ppm caffeine or 10 µM 2-APB for four hr. The fluorescence signal was observed under a fluorescent stereomicroscope MZ FLIII (Leica).

Ethics Statement

The National Taiwan University Institutional Animal Care and Use Committee (IACUC) reviewed and approved the protocol described below (NTU-99-72). No specific ethics approval was required for this project, as all zebrafish (Danio rerio) used in this study were between 0 to 3 days old. This procedure is not considered painful since embryos at this early stage have no pain perception.

Searching for the Putative Target Genes of miR-3906

To search for the putative target genes of miR-3906, we performed a LAMP assay [18] with some modifications. The pre-miR-3906 was labeled with Biotin and then mixed with cell extracts. The putative target genes were precipitated by anti-Biotin agarose beads (Sigma) and transformed into cDNA by reverse transcriptase-polymerase chain reaction. Finally, these putative cDNAs for miR-3906-targeting were further combined with Zebrafish Whole Genome Microarray (Aligent).

Plasmid Constructs

Based on the NCBI database, we designed primers to perform PCR from the 32 hpf cDNA library to obtain the complete 3′UTR segments of each cDNA of colla2 (NM182968, +3963 to +4965), dnajc10 (NM001083547, +2377 to +2733), homer-1b (NM001002496, +1198 to +2222), six1a (NM207095, +856 to +1117), and trmt2a (NM199929, +1861 to +2011). Each PCR product was ligated into the downstream of luciferase (luc) gene in plasmid phRG-TK and designated as plasmid phRG-TK-col1a2-3′UTR, -dnajc10-3′UTR, -homer-1b-3′UTR, -six1a-3′UTR and -trmt2a-3′UTR, respectively. The 3′UTR sequence of each of the five genes was driven by thymidine kinase (TK) promoter.

Plasmids pHsp-miR-3906 and pHsp-wob-homer-1b contain pre-miR-3906 RNA and wobble homer-1b mRNA, respectively, driven by heat-shock treatment. Wobble homer-1b mRNA is a mutated form derived from homer-1b mRNA, in which the target sequences of homer-1b-MO are mutated, and the 3′UTR of homer-1b mRNA is not included, effectively eliminating targets for both miR-3906 and homer-1b-MO. Using microinjection of plasmids pHsp-miR-3906 and pHsp-wob-homer-1b in embryos, overexpression of miR-3906 RNA and wobble homer-1b mRNA, respectively, was generated at 20 hpf by heat-shock induction.

Validation of miR-3906-targeting Genes by luc Activity Assay

Dual luc reporter assay (Promega) was carried out in cell line HEK-293T and zebrafish embryos by following the method described previously [25] with some modifications. In control group, we co-transfected 40 ng of plasmid pGL3-TK, which served as an internal control, and 200 ng of each examined plasmid, including phRG-TK-col1a2-3′UTR, phRG-TK-dnajc10-3′UTR, phRG-TK-homer-1b-3′UTR, phRG-TK-six1a-3′UTR, and phRG-TK-trmt2-3′UTR. The luc activity of the control group was set 100%. In the experimental group, we co-transfected 40 ng of pGL3-TK, 200 ng of each examined plasmid and 2 µg of plasmid pCMV-RFP-miR-3906. In zebrafish embryos, we co-injected 5 ng/µl of pGL3-TK, which also served as an internal control, and 5 ng/µl of each examined plasmid as described above to serve as a control group; whereas we co-injected 5 ng/µl of pGL3-TK, 5 ng/µl of each examined plasmid and 200 pg of synthesized pre-miR-3906 RNA to serve as an experimental group. All plasmids were microinjected into one-cell embryos in a volume of 2.3 nl. Twenty embryos were harvested for luc assay after injection for 24 hr. The change of luc activity was calculated as follows: Fold change = [(Renilla luc+miR-3906)/(Firefly luc+miR-3906)] ÷ [(Renilla luc)/(Firefly luc)].

Whole-mount in situ Hybridization (WISH)

WISH followed the method described previously by Lee et al. [26], except that anti-sense sequences of miR-3906 (AAAATCTGCATTCAAAATGCTTT), miR-206 (CCACACACTTCCTTACATTCCT) and control 22 nt (CGGAACGGTGCGTA- GCACAATT) (EXIQON) [17] were used. The cDNA of homer-1b (NM001002496), myf5 (NM131576) [19], fmhc4 (NM001020485) [27], smhc1 (NM001020507) [27] and atp2a1 (NM001007029) [27] were used as probes.

Western Blot

Analysis of total proteins was performed by Western blot on a 10% SDS-PAGE following the procedures described previously [28], except that the yolk was removed, and the antibodies of anti-Homer-1 (Santa Cruz) and α-tubulin (Sigma) were used at the dilution of 1∶400 and 1∶1000, respectively.

Knockdown and Rescue Experiment

Antisense oligonucleotide morpholino (MO), homer-1b-MO, was designed specifically for translation inhibition of homer-1b (GGATCACCATTTCTTCATCCT-CCAT), which was complementary to nucleotides (nt) 131–155 of zebrafish homer-1b cDNA (NM001002496). Because Photo-MO can be induced at any desired stage to inhibit gene translation by UV light irradiation [29], [30], we also designed Photo-homer-1b-MO (GAGGATGAAPAAATGGTGATCC) which can release functional homer-1b-MO after UV exposure at 360 nm for 30 min. Additionally, miR-3906-MO (AAATCTGCATTCAAAATGCTTTTATCTACC) [17] was designed to knock down miR-3906. All MOs were prepared at 1 mM as a stock solution and were diluted to the desired concentration for microinjection, such as 8, 3, 2, or 1 ng per embryo. Capped mRNAs of homer-1b without the 3′ untranslated region (UTR), wobble mutated homer-1b without the 3′UTR, homer-1b-MO-target-egfp (in which the target sequence of homer-1b-MO was fused in frame with egfp cDNA), wobble mutated homer-1b-target-egfp (in which the mutated nucleotides of the target sequence of homer-1b-MO was fused in frame with egfp cDNA), and egfp, as well as pre-miR3906 RNA, were synthesized according to the manufacturer’s protocol (Epicentre). The resultant mRNAs were diluted with distilled water to 172 ng/µl, 88 ng/µl and 44 ng/µl for wobble mutated homer-1b mRNA, 88 ng/µl for pre-miR3906 RNA and 44 ng/µl for wobble mutated homer-1b-target-egfp, homer-1b-MO-target-egfp, and egfp mRNA. The total volume of approximately 2.3 nl was used for microinjection into one-cell embryos.

Detection of the Distribution of Calcium Concentration within Zebrafish Embryos

A solution containing calcium green-1 (2 mM, Invitrogen) and dextran (tetramethylrhodamine 10000 MW, 0.5 µM, Invitrogen) was mixed with 8 ng of miR-3906-MO, 1.15 ng miR-3906 dsR, 400 pg of homer-1b mRNA or 3 ng of homer-1b-MO and microinjected individually into one-cell zebrafish embryos. The fluorescent image of each embryo was captured by a Leica MZFLIII microscope equipped with a fluorescent system (Hg 100 W, with emission filters set at 488 and 583 nm) and a D3 camera (Nikon). The conditions for capturing the camera image were set at 1600 ISO and 2 sec exposure time for embryos at 24 hpf. We fixed a region consisting of 11 to 20 somites, except the artery and vein area, to calculate the emission reading of green and red for calcium green-1 and dextran, respectively, through ImageJ software. To rule out the injection volume difference of each embryo, the calcium green-1-light reading was divided by dextran red-light reading. To standardize the emission readings from embryos injected with miR-3906 dsR, miR-3906-MO, homer-1b mRNA or homer-1b-MO, the reading obtained from WT embryos, which were only injected with calcium green-1 and dextran, was set as 100%. For the control group in each experiment, we took six WT embryos and set the averaged reading at 100% after deleting the highest and lowest reading values. In the experimental groups, we took an averaged reading from more than three readings each time. We repeated this experiment more than three times (n ≥3).

Primary Cell Culture

The 24-hpf embryos derived from transgenic line Tg(α-actin:RFP) in which only the fast muscle cells are tagged by red fluorescence protein (RFP) [22] and microinjected separately with miR-3906 dsR, miR-3906-MO, homer-1b-mRNA, homer-1b-MO, Photo-homer-1b-MO, pHsp-miR-3906 or pHsp-wob-homer-1b were collected and washed three times with Hank’s saline. After washing, embryos were incubated in 0.5% bleach for 2–3 min and then washed three more times with Hank’s saline. The somites located at positions 11 through 20 of each embryo were dissected by forceps. The somites of 10 embryos were collected in a 1.5 ml Eppendorf tube and treated with 0.25% trypsin for 30 min at 28°C under a 5% CO2 incubator. Cells were pelleted by centrifugation and then resuspended in culture medium [31] in a volume of 600 µl. Cells cultured on dish at 28°C for eight hr under a 5% CO2 incubator were ready for [Ca2+]i measurement. Before detecting [Ca2+]i in the cells of embryos injected with plasmids pHsp-miR-3906 and pHsp-wob-homer-1b, we heat-shocked these cultured cells in 37°C for four hrs.

Quantification of [Ca2+]i in the Fast Muscle Cells of Zebrafish Somites

Since we wanted to quantify the [Ca2+]i in fast muscle-specific cells, we cultured cells from embryos of Tg(α-actin:RFP) whose fast muscle cells are tagged by RFP. After cells were specifically cultured for eight hr, they were incubated in the culture medium supplied with 5 µM Fura2-AM and 0.02% pluronic acid for 30 min in the dark at 28°C. To measure the [Ca2+]i value in the fast muscle cells of zebrafish somites, we employed a fluorescence microscope (Leica DMI 4000) equipped with a 75 W Xenon lamp using 340 nm and 380 nm to excite Fura2-AM. The emission signal at 510 nm was received by CoolSNAP HQ2 CCD (Photometrics), and fluorescence intensities were analyzed by Metamorph software. To quantify [Ca2+]i, we followed the formula established by Grynkiewicz et al. [32]: [Ca2+]i = Kd × [(R–Rmin)/(Rmax–R)] × [F380max/F380min], where Kd is the Fura-2 effective dissociation constant obtained from the Fura2-AM calcium imaging calibration kit (Molecular Probes). Somitic cells from Tg(α-actin:RFP) embryos without DNA/RNA injection served as an untreated control. When somitic cells were incubated for 4 hr with 772 µM of caffeine and 10 µM of 2-Aminoethoxydiphenyl borate (2-APB), which is a chemical that acts to block store-operated Ca 2+ entry, they served as positive and negative control, respectively.

Rescue Experiments

Three types of rescue experiments were performed before the mRNA levels of fmhc4, smhc1 and atp2a1 were quantified at 24 hpf. First, we examined whether the expression defect caused by Photo-homer-1b-MO and pHsp-miR-3906 could be rescued by coinjection of pHsp-wob-homer-1b and heat shock treatment at 20 hpf. The Photo-homer-1b-MO-injected embryos were exposed to UV at 20 hpf, and the pHsp-miR-3906-injected embryos were treated with heat shock. Second, we examined whether the expression defect caused by miR-3906 dsR and homer-1b-MO could be rescued by soaking with caffeine (772 µM) between 20–24 hpf. Third, we examined whether the expression defect caused by miR-3906-MO and pHsp-wob-homer-1b could be rescued by incubation with 2-APB (10 µM). To induce homer-1b overexpression, the pHsp-wob-homer-1b-injected embryos were heat shocked at 37°C for 30 min when embryos developed at 20 hpf. After this treatment, both miR-3906-MO- and pHsp-wob-homer-1b-injected embryos were incubated in medium containing 2-APB.

Quantitative RT–PCR (q-PCR)

Each experiment collected 100 embryos in 500 µl of Trizol Reagent (Invitrogen), which was stored at −80°C. Total RNA was isolated according to the manufacturer’s instructions. For quantitative PCR, first-strand cDNA was generated using 1 mg of total RNA. Both cDNA concentrations were adjusted to 200 ng/ml, and qPCR was performed using the 7900HT Fast Real-Time PCR System (Applied Biosystems, USA) according to the manufacturer’s instructions. Forward and reverse primers designed for cloning each gene by PCR were as follows, respectively: homer-1b, CCTTCATGGAAACTGCCTCAA and CACATCTACATCTCAGCGTC- TGC; fmhc4, GGAGGTTAAGGCTAAGAACGCACT and TCATGACGGGCTGAT- TGTACAG; smhc1, GTCAAGGATTCCCAAATGCAA and CCACAATGGCGAT- GTTCTCTTT; atp2a1 (known as SERCA in mammals) [27], TCTGATCCCAG- TTCAGCTGCT and CATAACCTCCAATGGCCAGGT; ef1a, CTCCTCTTGGTCG- CTTTGCT and CCGATTTTCTTCTCAACGCTCT. Expression levels were determined by comparison with a standard curve from total RNA isolated from WT embryos.

Phalloidin Staining and Transmission Electron Microscopy Examination

Phalloidin staining followed the procedures described previously [33], and Transmission Electron Microscopy followed the procedures described by Wang et al. [34] with some modifications. Embryos were fixed at 32 hpf with 2% paraformaldehyde and 2.5% glutaraldehyde in 0.1 M sodium cacodylate buffer, postfixed with 1% osmium tetroxide, dehydrated through a graded series of ethanol washes, and embedded in Spurr’s resin. Ultrathin (90 nm) sections were cut using an Ultracut E, stained with uranyl acetate followed by lead citrate (Reynolds), and the histological sections were examined under a Hitachi H-7650 transmission electron microscope (TEM) at 75 kV. To quantify the proportion of thick filaments (myosin heavy chain) versus thin filaments (sarcomeric actin) in the hexagonal arrangement shown on EM, we randomly selected five positions from the cross section of the EM image to count their numbers. The values were presented as the average of three independent trials.

Results

The Putative Target Genes of miR-3906 by LAMP Assay and Microarray Analysis

The expression of myf5, a host gene of miR-3906, begins at 7.5 hpf in zebrafish somites and is predominant in the newly formed somites, gradually reducing its expression in mature somites [19]. We detected miR-3906 in the front of mature trunk somites at 20 hpf [17], persisting up to eight days post-fertilization (8 dpf) in the muscle of zebrafish embryos (Fig. S1 in File S1). Therefore, we chose the stage during which zebrafish myf5 significantly reduces in trunk muscles to study whether the persistence of miR-3906 is able to functionally regulate its target genes in a manner that affects trunk muscle development.

We collected zebrafish embryos at 32 hpf and performed our LAMP assay, subsequently using the Zebrafish Whole Genome Microarray to analyze the RNA products pulled down by miR-3906. After normalization of the reading, we obtained 632 possible target genes of miR-3906 and then selected the top 150 genes for further analysis with the NCBI and ZFIN databases. Only one third out of 150 genes could be defined, including dkk3a, which has already been reported as the target gene of miR-3906 [17]. Based on the expression patterns of these 50 putative genes, we categorized them as genes belonging to the central nervous system, brain, eyes, muscles and other nonspecific regions (Fig. S2 in File S1). We focused on the following five muscle-specific genes for further study because we hypothesized that these genes would most likely be involved in the differentiation of muscle cells or modulation of muscle genes: collagen type I alpha 2 (colla2), dnaJ homolog subfamily C member 10 (dnajc10), homer homolog 1b (homer-1b), sine oculis homeobox homolog 1a (six1a) and tRNA methyltransferase 2 homolog A (trmt 2a).

miR-3906 Enables Silencing of Reporter Gene Fused by homer-1b-3'UTR Sequence

To examine whether col1a2, dnajc10, homer-1b, six1a and trmt2a are the target gene(s) of miR-3906, we constructed phRG-TK-col1a2-3′UTR, -dnajc10-3′UTR, -homer-1b-3′UTR, -six1a-3′UTR and -trmt2a-3′UTR (Fig. 1A). Compared with the luc activity from the control group in which pGL3-TK and each of above constructs were co-transfected, we normalized the luc reading from the experimental group in which pGL3-TK and each of examined constructs was co-transfected with pCMV-RFP-miR-3906 individually into cell line HEK-293T. We found that miR-3906 enabled reduction of luc expression through binding of the 3′UTR derived from dnajc10, homer-1b, six1a and trmt2a, compared to luc activity (100%) of the control group (Fig. 1B). We further performed in vivo screening of dnajc10, homer-1b, six1a and trmt2a in zebrafish embryos. After constructs of phRG-TK-dnajc10-3′UTR, -homer-1b-3′UTR, -six1a-3′UTR and -trmt2a-3′UTR were co-injected individually with pre-miR-3906 RNA into one-cell embryos, we found that miR-3906 enabled reduction of luc activity in embryos through binding of the 3′UTR derived only from homer-1b and six1a (Fig. 1B). Unexpectedly, when we compared the effects of miR-3906 silencing on the 3′UTRs of dnajc-10 and trmt2a, we noticed an inconsistency in the results between the HEK-293T cell line studied and the embryos. To explain this inconsistency, we speculated that (1) the special biological characteristics of various cell lines and (2) other unknown factor(s) that might be involved in the interaction between microRNAs and their target genes under a particular intracellular microenvironment. However, since investigating this interesting phenomenon is outside the scope of this paper, we decided to study homer-1b as its 3′UTRs could be greatly silenced by miR-3906, both in vivo and in vitro.

thumbnail
Figure 1. Luciferase (luc) activity assay of miR-3906 co-injected with plasmid constructs containing 3′UTR segment of putative miR-3906-target genes.

(A) Constructs for examining luc assay. The complete 3′UTR segments of col1a2, dnajc10, homer-1b, six1a and trmt2a, which are putative target genes of miR-3906, were ligated into the downstream of luc reporter gene contained in plasmid phRG-TK. (B) Plasmid pCMV-RFP-miR-3906 [miR-3906 (+)], a RFP reporter fused with pre-miR-3906 and driven by CMV promoter, was co-transfected with pGL3-TK (internal control) and each examined construct, as indicated, into HEK 293T cells. Injection of pGL3-TK and each examined construct without containing pCMV-RFP-miR-3906 [miR-3906 (−)] served as a control group, and its luc activity was 100%. In zebrafish embryos, we co-injected synthetic pre-miR-3906 RNA [miR-3906 (+)], pGL3-TK (internal control) and each examined construct in the experimental group. Injection of pGL3-TK and each examined construct without containing pre-miR-3906 RNA [miR-3906 (−)] served as control group, and its luc activity was 100%. Data were presented as means±SD from three independent experiments (n = 3). (C) Injection of plasmid phRG-TK, in which luc expression was driven by thymidine kinase (TK), served as a control, and its luc activity was 100%. The relative luc expression level of each combination, as indicated, was examined. All data were presented as means±SD from three independent experiments (n = 3). (D) Various lengths of 3′UTR segment derived from homer-1b mRNA (from 1198 to 2222 nt) fused with luc reporter gene and driven by TK promoter were constructed as indicated. Plasmid alone or plasmid plus pre-miR-3906 were individually injected in zebrafish embryos to perform luc assay. Data were presented as means±SD from three independent experiments (n = 3). Student's t-test determined significant differences between each group, and * indicates that the difference was significant at P<0.05. (black box: miR-3906-target sequences; cross filled box: miR-3906-target mutated sequences).

https://doi.org/10.1371/journal.pone.0070187.g001

To confirm whether endogenous miR-3906 in zebrafish embryos is able to inhibit reporter gene expression through binding homer-1b-3′UTR, we injected phRG-TK-homer-1b-3′UTR alone into embryos. Compared to the phRG-TK-injected control group, the luc activity of embryos injected with phRG-TK-homer-1b-3′UTR alone was greatly reduced (Fig. 1C), suggesting that endogenous miR-3906 can functionally inhibit gene expression through 3′UTR derived from homer-1b. However, when miR-3906 was knocked down by MO, which can specifically inhibit the generation of the mature form of miR-3906, and co-injected with phRG-TK-homer-1b-3′UTR, the luc expression level in zebrafish embryos increased (Fig. 1C). Furthermore, if miR-3906-MO was co-injected with phRG-TK, luc activity was close to that of embryos injected with phRG-TK alone (Fig. 1C), indicating that miR-3906-MO is not affected by TK activity. These lines of evidence suggest that the endogenous miR-3906 in zebrafish embryos can specifically silence luc expression through the 3′UTR from homer-1b mRNA.

Next, in order to explore which lengths of homer-1b-3′UTR sequence might affect the inhibitory capabilities of miR-3906, several plasmids containing various deletion fragments from the full-length (+1198/+2222) of homer-1b-3′UTR fused with luc and driven by TK promoter were constructed, including D1 (+1198/+1871) and D2 (+1198/+1588) (Fig. 1D). Compared to the luc activity of embryos injected phRG-TK-homer-1b-3′UTR, which was set as 100%, the luc activities of embryos injected with phRG-TK-homer-1b-3′UTR D1 and phRG-TK-homer-1b-3′UTR D2 were 161.33±7.50% and 205.00±6.55%, respectively (Fig. 1D). However, the luc activities of embryos injected with pre-miR-3906 RNA plus phRG-TK-homer-1b-3′UTR, phRG-TK-homer-1b-3′UTR D1 or phRG-TK-homer-1b-3′UTR D2 were 33.66±7.63%, 78.66±6.50% and 205.33±8.50%, respectively, suggesting that the full-length of 3′UTR sequence has the strongest miR-3906-mediated silencing ability. Furthermore, we used the FindTar [35], Rna22 [36], and RNAhybrid [37] software to analyze this 3′UTR segment, and we found three putative binding sequences for miR-3906 in homer-1b-3′UTR. We therefore mutated the nucleotides at these positions and constructed a plasmid phRG-TK-homer-1b-3′UTR mut (Fig. S3 in File S1). The luc activity of embryos injected with miR-3906 plus phRG-TK-homer-1b-3′UTR mut was 222.33±12.89%, which exhibited a significant difference (p<0.05) from that of embryos injected with pre-miR-3906 RNA plus phRG-TK-homer-1b-3′UTR (Fig. 1D). Taken together, we concluded that the miR-3906 motif is capable of silencing the reporter gene through the binding of homer-1b-3′UTR.

The Expressions of homer-1b and miR-3906 are Co-localized in Trunk Muscle Cells

We studied the spatiotemporal expressions of homer-1b in the muscle of zebrafish embryos (Fig. S4 in File S1), and we also studied the expression patterns of miR-3906 and its host gene myf5. At 20 hpf, myf5 was detected in the pre-somite mesoderms and some newly formed somites (Fig. 2A). At 20 hpf, miR-3906 was expressed in the front of mature somites (Fig. 2B), while homer-1b was only starting to express in the front of mature somites (Fig. 2C). At 24 hpf, myf5 expression was only detected in PSM (Fig. 2D). However, miR-3906 was detected in most somites (Fig. 2E), and the expression of homer-1b increased in the front of mature somites (Fig. 2F). At 32 hpf, myf5 was only detected at the edge of somites (Fig. 2G), while miR-3906 and homer-1b were expressed in all trunk muscles (Figs. 2H and 2I). Using frozen sections, we found that miR-3906 and homer-1b were expressed in the trunk fast muscle of zebrafish embryos (Figs. 2H’ and 2I’). Based on the significant reduction of host gene myf5 in the trunk somites, these findings suggest that miR-3906 and homer-1b were expressed in the fast twitch muscle tissue of somites in a co-localized manner.

thumbnail
Figure 2. The expression patterns of myf5, miR-3906 and homer-1b in the trunk somites of zebrafish embryos.

(A, D, G) Using whole-mount in situ hybridization to detect the temporal and spatial expression patterns of myf5, (B, E, H) miR-3906 and (C, F, I) homer-1b in zebrafish embryos at 20 hpf, 24 hpf and 32 hpf. At 20 hpf, (A) myf5 was expressed in the pre-somitic mesoderm and newly formed somites (indicated by { ), but it was absent in mature somites (indicated by [); (B) miR-3906 and (C) homer-1b were detected in mature somites. At 24 hpf, (D) myf5 was detected in the pre-somitic mesoderm, while (E) miR-3906 and (F) homer-1b gradually increased expression in mature somites. At 32 hpf, (G) myf5 was expressed in the edge region of trunk muscles (arrowhead), but (H) miR-3906 and (I) homer-1b were expressed in all trunk muscles. Cross section (dotted lines) showed that (F’) miR-3906 and (I’) homer-1b were expressed in fast muscle (arrows).

https://doi.org/10.1371/journal.pone.0070187.g002

miR-3906 Regulates the Expression Level of homer-1b mRNA in Zebrafish Embryos

To confirm any correlation between the expression level of miR-3906 and that of homer-1b, we injected either miR-3906-MO (8 ng) to inhibit the production of mature miR-3906 or double-strand of mature miR-3906 (miR-3906 dsR) (1.15 ng) to overexpress miR-3906 in zebrafish embryos before using WISH and q-PCR to detect the level of homer-1b mRNA. Compared with wild-type (WT) embryos at 24 and 32 hpf, the expression level of homer-1b mRNA increased in embryos injected miR-3906-MO (Figs. 3A and 3D vs. 3B and 3E). In contrast, the expression level of homer-1b mRNA in the embryos injected with miR-3906 dsR decreased greatly in both trunk tail muscle and mature somites located in the front of trunk (Figs. 3C and 3F). Furthermore, using relative quantitative PCR, we compared the expression levels of homer-1b mRNAs among WT embryos, miR-3906-MO-injected embryos and miR-3906 dsR-injected embryos, when the expression level of endogenous homer-1b mRNA in WT was set as 1. Results showed that the expression levels of homer-1b in the miR-3906-MO-injected and the miR-3906 dsR-injected embryos at 24 hpf were 1.85±0.20 and 0.74±0.10, respectively; at 32 hpf, they were 1.19±0.01 and 0.62±0.16, respectively (Figs. 3G). The agreement of data between the q-PCR and WISH assays suggests that miR-3906 negatively modulates the expression level of homer-1b mRNA.

thumbnail
Figure 3. Change of miR-3906 level affected the amount of homer-1b mRNA in zebrafish embryos.

(A, D) Compared with WT, injection of miR-3906-MO increased the expression level of homer-1b mRNA in embryos at 24 hpf (A vs. B) and 32 hpf (D vs. E). Injection of miR-3906 dsR (mature double-strand miR-3906) reduced the expression level of homer-1b mRNA in the front of trunk muscle and was absent in the tail region at 24 hpf (A vs. C) and 32-hpf (D vs. F). (G) The expression levels of homer-1b in WT embryos, miR-3906-MO-injected embryos and miR-3906 dsR-injected embryos at 24 hpf and 32 hpf were quantified. Each one was carried out with 100 embryos, and triplicate experiments were performed (n = 3). The numbers shown in the lower-right corner of panels A–F indicate the number of phenotypes out of the total number of embryos examined. SigmaPlot software was used to perform Student’s t-test. *: indicates the difference at P<0.05 level; **: indicates the difference at P<0.01 level.

https://doi.org/10.1371/journal.pone.0070187.g003

The Defective Phenotypes of miR-3906 dsR-injected Embryos and homer-1b-MO- Injected Embryos are Similar

To confirm that miR-3906 and homer-1b are involved in trunk muscle development through the same regulatory pathway, we injected miR-3906-MO, miR-3906 dsR, homer-1b-MO and homer-1b mRNA individually into embryos derived from transgenic line Tg(α-actin:RFP), in which the fast muscle is tagged by RFP. After injection, we were able to observe trunk muscle development in vivo. At 32 hpf, the morphological appearance of embryos injected with miR-3906-MO (8 ng) and homer-1b mRNA (400 pg) did not differ from that of WT (Figs. 4A, 4B and 4C). However, the swimming behavior of embryos injected with either miR-3906-MO or homer-1b mRNA was completely abnormal (Movie S1 in File S2). Injection of homer-1b-MO (Figs. 4D, 4E and 4F) or miR-3906 dsR (Figs. 4G, 4H and 4I) exhibited the same defective phenotypes, such as body axis bending and tail muscle shortening.

thumbnail
Figure 4. Defective phenotypes induced by injection of excessive miR-3906 and homer-1b-MO were similar.

(AI) Embryos derived from transgenic line Tg (α-actin:RFP), in which red fluorescence protein (RFP) is expressed specifically in skeletal muscles, were injected with miR-3906-MO, miR-3906 dsR (mature double- strand miR-3906), homer-1b-MO or homer-1b mRNA, as indicated. After injection, the development of trunk muscle was observed at 32 hpf. Compared with WT (A), the morphological trait of embryos injected with either miR-3906-MO (B) or homer-1b mRNA (C) was similar to that of WT. Embryos injected with homer-1b-MO (DF) and exogenous miR-3906 (miR-3906 dsR) (GI) displayed such defective phenotypes as body axis bending and trunk muscle shortening in tail. Based on the definition of three defective levels of muscle (see Materials and Methods), we calculated the defective percentages of embryos injected with homer-1b-MO alone (J) and homer-1b-MO plus wobble homer-1b mRNA (K). The occurrence percentages of severe and mild defects of embryos injected with 1.15 ng miR-3906 dsR alone, 1.15 ng miR-3906 dsR plus 3 ng homer-1b-MO and 1.15 ng miR-3906 dsR plus 400 pg homer-1b mRNA were calculated (L). n: indicates the total number of embryos after three injections. (M) Western blot analysis of Homer-1b (48 kD, arrow) in WT (lanes 1 and 4), 3 ng homer-1b-MO-injected embryos (lane 2), 8 ng miR-3906-MO-injected embryos (lane 3) and 1.15 ng miR-3906 dsR-injected embryos (lane 5). Detection of α-tubulin served as internal control (arrowhead). The relative intensity of Homer-1b protein among WT, homer-1b-MO, miR-3906-MO and miR-3906 dsR was also indicated.

https://doi.org/10.1371/journal.pone.0070187.g004

Based on the trunk muscle defects observed, three levels of abnormality were categorized: (a) severe defect, i.e., significantly reduced muscle size after the 18th somite and bent body axis (Figs. 4D and 4G); (b) mild defect, i.e., muscle size starting to shorten after the 20th somite (Figs. 4E and 4H); and (c) WT-like, i.e., morphological appearance similar to that of WT (Figs. 4F and 4I). As shown in Figure 4J, we injected 3 ng, 2 ng and 1 ng of homer-1b-MO into WT zebrafish embryos and calculated the occurrence percentage of phenotypes suffering severe defect, mild defect and WT-like at 32 hpf. We found that the degree of phenotypic abnormality induced by homer-1b-MO was dose-dependent. Furthermore, when we co-injected 3 ng of homer-1b-MO with wobble homer-1b mRNA, which cannot be bound by homer-1b-MO (Fig. S5 in File S1), the percentage of injected embryos having severe defect was decreased, while the percentage of WT-like embryos was increased (Fig. 4K), indicating that the muscle defect was specifically caused by the loss of homer-1b. Next, as shown in Figure 4L, we injected 2.3 ng, 1.15 ng and 0.575 ng of miR-3906 dsR into WT zebrafish embryos and calculated the occurrence percentage of phenotypes at 32 hpf. We found that the degree of phenotypic abnormality induced by miR-3906 dsR was also dose-dependent. Furthermore, when we injected with 1.15 ng miR-3906 dsR plus 3 ng homer-1b-MO, the percentages of injected embryos having severe defect, mild defect and WT-like were 54.5%, 26.8% and 18.7%, respectively. We also injected with 1.15 ng miR-3906 dsR plus 400pg wobble homer-1b mRNA, and the percentages of injected embryos having severe defect, mild defect and WT-like were 15.3%, 37.8%, and 48.9%, respectively. Based on this evidence, we suggested that miR-3906 and homer-1b are involved in trunk muscle development through the same regulatory pathways.

After WT embryos, homer-1b-MO-injected embryos, and miR-3906-MO- injected embryos were collected at 48 hpf, protein extracts were isolated, and Western blot analysis was performed using antibody against Homer-1b. We found that Homer-1b protein located at 48 kDa was present in the WT embryos (Fig. 4M, lanes 1, 4). However, Homer-1b protein was decreased in the embryos injected with homer-1b-MO (Fig. 4M, lane 2), indicating that the translation of homer-1b mRNA was specifically reduced by homer-1b-MO. In contrast, compared to WT, the protein level of Homer-1b was increased in the miR-3906-MO-injected embryos (Fig. 4M, lane 3) and reduced in the miR-3906 dsR-injected embryos (Fig. 4M, lane 5), suggesting that miR-3906 regulates Homer-1b protein expression and impacts the muscle development of zebrafish embryos.

The Expression Levels of miR-3906 and Homer-1b Affect Calcium Concentration in Fast Muscle Cells of Zebrafish Embryos

Homer-1b is a scaffold protein, not a transcription factor, in mammals [38]. It has been reported that Homer-1b binds ryanodine receptor to regulate calcium release from sarcoplasmic reticulum [21]. The calcium concentration in muscle cells is also known to affect muscle differentiation [39]. Therefore, we asked whether Homer-1b plays a role in fast-twitch muscle differentiation through modulating [Ca2+]i. To address this question, we injected calcium green-1, which can combine with intracellular calcium and release a green fluorescent signal [40], [41], in the one-cell stage of zebrafish embryos. Co-injection of tetramethylrhodamine, which is not affected by calcium ions [42], but appears as a red fluorescent signal, served as an internal control to monitor the volume of each injection. Based on the luminescent signal shown in Figure 5A, we observed the gradient distribution of calcium concentration in trunk from mature somites to newly forming somites in the WT embryos at 24 hpf. After the green signals were normalized, we found that the average reading score of green fluorescence in mature somites was higher than the calculated score for newly forming somites (data not shown). Thus, we selected somites from position 11 to 20, in which muscle cell differentiation is highly processed, for further study. The degree of green fluorescent signal indicated various concentrations of intracellular calcium in relation to the differentiation rate of muscle cells. Thus, in embryos injected with miR-3906-MO and homer-1b mRNA (Figs. 5C and 5D), results showed that the green fluorescence ratios were higher than WT. On the other hand, for embryos injected with miR-3906 dsR and homer-1b-MO, the green fluorescence ratio was lower than that of WT (Figs. 5B and 5E), indicating that the green fluorescent intensity is reflective of [Ca2+]i, which is controlled by the amount of Homer-1b protein in embryos. Additionally, when we quantified the relative luminescence value of signals among Figs. 5A–E, as shown in Fig. 5F, the reading from the WT group was set as 100. Compared to the WT control group, the readings of miR-3906 dsR-injected, miR-3906-MO-injected, homer-1b-mRNA-injected and homer-1b-MO-injected groups were 78.00±1.45 (n = 3), 118.73±13.47 (n = 4), 119.25±1.35 (n = 3) and 84.45±0.33 (n = 3), respectively. We suggested that either reduction of miR-3906 or enhancement of Homer-1b increased the amount of calcium in muscle cells. In other words, the decrease of Homer-1b resulted in lower [Ca2+]i in muscle cells.

thumbnail
Figure 5. Injection of either homer1b-mRNA or miR-3906-MO increases the calcium concentration within muscle cells.

(A) One-cell embryos were injected with buffer (A, as a control group WT), (B) miR-3906 dsR (1.15 ng), (C) miR-3906-MO (8 ng), (D) homer-1b mRNA (400 pg) or (E) homer-1b-MO (3 ng) with calcium green-1 and tetramethylrhodamine (as an internal control). The gradient distribution of Ca2+ concentration within the muscle cells in somites was analyzed at 24 hpf by ImageJ software analysis. There were 16 colors of signal images displaying the different intracellular Ca2+ concentrations from low to high. We sketched a fixed region comprised of 11 to 20 trunk somites, as indicated, to calculate the readings from excitation emission (the region was indicated by white line). (F) After normalization, the reading from the WT group was set as 100, and the readings of miR-3906 dsR-injected, miR-3906-MO-injected, homer-1b-mRNA-injected and homer-1b-MO-injected groups were compared. (G) The primary culture cells were stained with Fura2-AM, excited with 380 nm light, with emission at 510 nm. (H) The primary culture cells which displayed red fluorescence were the fast muscle cells. (I) The merge picture of F and G. Cells which had overlapping signals denoted in yellow were selected as detection samples (indicated by red box). (J) The image of fluorescence intensity shown on fast muscle cells that were excited by 340 nm, with emission at 510 nm. (K) The image of fluorescence intensity shown on fast muscle cells that were excited by 380 nm, with emission at 510 nm. (L) The value of [Ca2+]i was calculated by following the formula established by Grynkiewicz et al. [31] (see Materials and Methods). The values of [Ca2+]i were obtained from cells derived from WT, miR-3906 dsR-injected, miR-3906-MO-injected, homer-1b-mRNA-injected, homer-1b-MO-injected, Photo-homer-1b-MO-injected, caffeine-soaked and 2-APB-soaked embryos, followed by heat-shocked WT, pHsp-miR-3906-injected and pHsp-wob-homer-1b-injected embryos. SigmaPlot software was used to perform Student’s t-test. *: indicates the difference at P<0.05 level; **: indicates the difference at P<0.01 level. Ex: excitation; Em: emission.

https://doi.org/10.1371/journal.pone.0070187.g005

To accurately quantify [Ca2+]i in fast muscle cells of somites, we chose to culture cells that were derived from 1) Tg(α-actin:RFP) embryos, since their fast muscle cells are tagged with RFP, and 2) somites only located at positions 11 to 20, since their fast muscle is newly synthesized at 24 hpf. After the fast muscle cells were identified by red fluorescence signal (Figs. 5G, 5H and 5I), they were excited at 340 nm and 380 nm separately, with emission at 510 nm (Figs. 5J and 5K). Based on the formula established by Grynkiewicz et al. [32] and Kd of 420 nM, as obtained from the Fura2-AM calcium imaging calibration kit (Molecular Probes; see Materials and Methods), the calculated values of [Ca2+]i of cells from embryos injected with miR-3906 dsR, miR-3906-MO, homer-1b-mRNA, and homer-1b-MO were 104.78±10.4 nM (n = 21), 294.95±95.85 nM (n = 20), 274.11±60.81 nM (n = 28), and 127.62±14.73 nM (n = 22), respectively, whereas the calculated value of [Ca2+]i of noninjected WT fast muscle cells was 148.75±9.20 nM (n = 25) (Fig. 5L). Meanwhile, the [Ca2+]i values of cells from embryos incubated in caffeine, which served as positive control, and incubated in 2-APB, which served as negative control, were 501.92±132.99 nM (n = 24) and 102.97±8.17 nM (n = 22), respectively (Fig. 5L). Thus, compared to the noninjected WT control cells, the [Ca2+]i values of cells from the miR-3906-MO-injected embryos and homer-1b-mRNA-injected embryos were increased 97.3% and 83.9%, respectively.

To exclude the possibility that the observed [Ca2+]i change arising from the injection of miR-3906-MO and homer-1b mRNAs in embryos at the one-cell stage was the result of secondary effects, we further designed an experiment to induce the presence of MO and mRNA at the 20 hpf stage when endogenous homer-1b starts transcription (Fig. S4 in File S1). To accomplish this, we decided to employ Photo-morpholino technology whereby gene expression can be switched on and off by light. To first verify the efficiency and specificity of using Photo-homer-1b-MO, we introduced Photo-homer-1b-MO, together with homer-1b-MO-target-egfp mRNA, into zebrafish embryos. Results showed that reporter GFP was clearly expressed in embryos when not exposed to UV, whereas it was decreased dramatically when embryos were exposed to UV (Fig. S5 in File S1). This finding indicates that functional homer-1b-MO was released after UV exposure, resulting in downregulating the translation of the introduced homer-1b-MO-target-egfp mRNA. Thus, as a result of UV exposure, functional homer-1b-MO is released and then inhibits the translation of homer-1b mRNA, resulting in reducing Homer-1b protein. This evidence suggested that the use of Photo-homer-1b-MO to study late-stage embryo development is efficient and specific.

After we microinjected Photo-homer-1b-MO into one-cell embryos derived from transgenic line Tg(α-actin:RFP), embryos at 20 hpf were exposed to UV for 30 min. After UV exposure, the primary culture was carried out when embryos developed at 24 hpf. Fura2-AM staining showed that [Ca2+]i of fast muscle of the Photo-homer-1b-MO-injected embryos was 116.03±4.96 nM (n = 31) (Fig. 5L), which was lower than that of noninjected control embryos at 148.75±9.20 nM (n = 25). We then microinjected plasmids pHsp-miR-3906 and pHsp-wob-homer-1b into one-cell embryos of Tg(α-actin:RFP), followed by heat shock at 37°C four hours prior to Fura2-AM staining. The [Ca2+]i value of the noninjected, but heat shock-treated, control cells carrying no exogenous plasmids was 155.21±18.82 nM (n = 20) (Fig. 5L). However, the [Ca2+]i values were 106.77±23.33 nM (n = 64) and 293.58±58.06 nM (n = 45) for cells carrying exogenous pHsp-miR-3906 and pHsp-wob-homer-1b, respectively (Fig. 5L). Taken together, this evidence further confirmed that the change of expression level of either miR-3906 or homer-1b mRNA resulted in a corresponding change of [Ca2+]i in the fast muscle cells of zebrafish embryos.

miR-3906 and Homer-1b Affect Gene Expression in Fast Muscle Cells of Zebrafish Embryos by Changing [Ca2+]i

To understand whether miR-3906 and Homer-1b affected the gene expression in muscle cells of embryos by changing [Ca2+]i, we altered the expression levels of miR-3906 and homer-1b and detected the expressions of the fast muscle-specific gene fmhc4, slow muscle-specific gene smhc1, and calcium-sensitive gene atp2a1 in embryos at 24 hpf. Compared to the expression level of fmhc4 in WT embryos (Fig. 6A), embryos injected with either miR-3906-MO or homer-1b mRNA showed increased fmhc4 expression (Figs. 6G and 6J), as did embryos soaked in caffeine, which served as a control of increasing [Ca2+]i (Fig. 6P) [43], [44]. However, fmhc4 expression was decreased in embryos injected with either miR-3906 dsR or homer-1b-MO (Figs. 6D and 6M), similar to embryos soaked in 2-APB, which served as a control of decreasing [Ca2+]i (Fig. 6S) [45]. This evidence suggested that the gene expression in fast-twitch muscles is affected by [Ca2+]i. In contrast, the expression level of the slow muscle-specific gene smhc1 exhibited little change in the embryos injected with either miR-3906 or homer-1b (Figs. 6E, 6H, 6K and 6N), compared to that of wild-type embryos (Fig. 6B). We noticed that smhc1 expression increased in the embryos soaked in caffeine (Fig. 6Q), whereas smhc1 expression decreased in embryos soaked in 2-APB (Fig. 6T). These lines of evidence suggested that slow muscle gene expression is still affected by [Ca2+]i, but that miR-3906 and homer-1b are not involved in gene expression of slow-twitch muscles. We noticed that the expression of the calcium-sensitive gene atp2a1 was increased in caffeine-soaked embryos (Fig. 6R), while atp2a1 expression was decreased in 2-APB-soaked embryos (Fig. 6U). In a parallel experiment, we found that atp2a1 expression increased in the embryos injected with either miR-3906-MO or homer-1b-mRNA (Figs. 6I and 6L) because miR-3906-MO and homer-1b-mRNA enabled [Ca2+]i to increase in embryos. However, atp2a1 expression decreased in the embryos injected with either miR-3906 dsR or homer-1b-MO (Figs. 6F and 6O) because miR-3906 dsR and homer-1b-MO caused [Ca2+]i to decrease in these embryos. In addition to analyzing the location and signal intensities of expressed genes using WISH, we also quantified the mRNA levels of expressed genes using q-PCR. As shown in Figure 6V, the mRNA levels of examined genes presented by q-PCR fundamentally agreed with those of data observed in WISH.

thumbnail
Figure 6. Injection of either miR-3906-MO or homer-1b mRNA affects fast muscle differentiation by regulating the calcium concentration in muscle cells.

(A–C) Wild-type (WT) zebrafish embryos at 24 hpf and embryos injected with (D–F) miR-3906 dsR (1.5 ng), (G–I) miR-3906-MO (8 ng), (J–L) homer-1b mRNA (400 pg), and (M–O) homer-1b-MO (3 ng) were collected, and the expressions of fast muscle type fmhc4, slow muscle type smhc1, and calcium-sensitive gene atp2a1 were detected by WISH. (P–R) Embryos soaked with caffeine served as a positive control, indicating that [Ca2+]i was increased. (S–U) Embryos soaked with 2-APB served as a negative control, indicating that [Ca2+]i was reduced. Compared to WT (A), the expression of fmhc4 in the embryos injected with miR-3906-MO (G), homer-1b-mRNA (J) and soaked in caffeine (P) was increased. The expression of fmhc4 in the embryos injected with miR-3906 dsR (D), homer-1b-MO (M) and soaked in 2-APB (S) was decreased. The expressions of smhc1 in the embryos injected with miR-3906 and homer-1b showed no difference (B, E, H and K), while smhc1 expression was increased in embryos soaked in caffeine (Q) and reduced in embryos soaked in 2-APB (T). The expression patterns of atp2a1 (F, I, L, O, R and U) in the examined embryos displayed a result similar to that of fmhc4. (V) The expression levels of the examined genes were quantified by q-PCR analysis after embryos were treated as indicated. Three rescue experiments were included: co-injection of pHsp-wob-homer-1b (lanes 9 and 10), soaking with caffeine (lanes 12 and 13) and incubating with 2-APB (lanes 15 and 16). SigmaPlot software was used to perform the Student’s t-test. *: indicates the difference at P<0.05 level; **: indicates the difference at P<0.01 level. The numbers shown in the lower-right corner of panels A–U indicate the number of phenotypes out of the total number of embryos examined.

https://doi.org/10.1371/journal.pone.0070187.g006

Furthermore, we wanted to clarify whether the downregulated expression of muscle genes in the presence of excessive miR-3906 or absence of homer-1b could be rescued by conditionally adding exogenous wobble homer-1b at 20 hpf. To accomplish this, we exposed the Photo-homer-1b-MO-injected embryos under UV for 30 min at 20 hpf, and the expression of muscle genes, such as fmhc4,smhc1 and atp2a1, was analyzed by qPCR at 24 hpf. Results showed that the expression of smhc1 remained unchanged in the Photo-homer-1b-MO-injected embryos, whereas the expressions of fmhc4 and atp2a1 were relatively lower in the Photo-homer-1b-MO-injected embryos than those of the wild-type embryos (Fig. 6V): fmhc4 was decreased by 27% (lanes 1 vs. 6 = 1∶0.73); atp2a1 was decreased by 34% (lanes 1 vs. 6 = 1∶0.66). This evidence indicated that Photo-homer-1b-MO inhibits the translation of endogenous homer-1b mRNA, resulting in the reduction of Homer-1b, which, in turn, decreases the [Ca2+]i within muscle cells.

Next, we injected Photo-homer-1b-MO together with plasmid pHsp-wob-homer -1b. It will be recalled that wobble homer-1b mRNA is a mutated form derived from homer-1b mRNA, in which the target sequences of homer-1b-MO are mutated, and the 3′UTR of homer-1b mRNA is not included, effectively eliminating targets for miR-3906 and homer-1b-MO. We exposed these embryos under UV for 30 min and then performed heat shock treatment at 20 hpf. The gene expressions of fmhc4 and atp2a1 were analyzed by qPCR at 24 hpf. Compared to the 27% decrease of fmhc4 expression in the Photo-homer-1b-MO-injected embryos, the decrease of fmhc4 expression in the Photo-homer-1b-MO- plus plasmid pHsp-wob-homer-1b-injected embryos was only 2% (lanes 1 vs. 10 = 1∶0.98). Moreover, compared to the 34% decrease of atp2a1 expression in the Photo-homer-1b-MO-injected embryos, the atp2a1 expression in the Photo-homer-1b-MO- plus plasmid pHsp-wob-homer-1b- injected embryos was even increased up to 31% (lanes 1 vs. 10 = 1∶1.31). This line of evidence indicated that the overexpression of exogenous wobble-homer-1b mRNA induced at late stage, such as 20 hpf, rescues the decreases of fmhc4 and atp2a1 caused by Photo-homer-1b-MO (Fig. 6V).

Subsequently, we microinjected embryos with pHsp-miR-3906 at the one-cell stage and carried out heat shock treatment for 30 min to overexpress miR-3906 at 20 hpf. Similarly, the expression levels of muscle genes, such as fmhc4,smhc1 and atp2a1, were then analyzed by qPCR at 24 hpf. Results showed that the expression of smhc1 remained unchanged in the pHsp-miR-3906-injected embryos, whereas the expressions of fmhc4 and atp2a1 were relatively lower in the pHsp-miR-3906-injected embryos than those of the wild-type embryos (Fig. 6V): fmhc4 was decreased by 32% (lanes 1 vs. 7 = 1∶0.68); atp2a1 was decreased by 19% (lanes 1 vs. 7 = 1∶0.81). These results indicate that overexpression of miR-3906 RNA after induction inhibits the translation of homer-1b mRNA, resulting in the decrease of [Ca2+]i.

We further microinjected plasmid pHsp-miR-3906 together with plasmid pHsp-wob-homer-1b into zebrafish embryos at the one-cell stage, performed heat shock for 30 min at 20 hpf, and analyzed the gene expressions of fmhc4 and atp2a1 at 24 hpf. Compared to the 32% and 19% decreases of fmhc4 and atp2a1 expressions in the pHsp-miR-3906-injected embryos, respectively, the fmhc4 and atp2a1 expressions in the embryos injected with plasmids pHsp-miR-3906 plus pHsp-wob-homer-1b were increased by 9% and 6%, respectively (Fig. 6V; fmhc4: lanes 1 vs. 9 = 1∶1.09; atp2a1, lanes 1 vs. 9 = 1∶1.06). This line of evidence indicated that the overexpression of exogenous wobble homer-1b after heat shock induction at late stage, such as 20 hpf, rescues the decreases of fmhc4 and atp2a1 expressions caused by miR-3906.

The Phenotypes Caused by Manipulating either miR-3906 or homer-1b Expression can be Rescued by Changing Calcium Concentration

We examined whether the abnormal expressions of muscle genes caused by manipulating the expression levels of miR-3906 or homer-1b could be rescued by incubating embryos in medium containing a chemical which changes [Ca2+]i. First, at 20 hpf, the Photo-homer-1b-MO-injected embryos were exposed to UV, and the pHsp-miR-3906-injected embryos were treated with heat shock. The expressions of fmhc4 and atp2a1 were reduced in theses embryos (lanes 6 and 7, Fig. 6V). However, this defect could be rescued by co-injection of pHsp-wob-homer-1b and heat shock treatment at 20 hpf because the expressions of fmhc4 and atp2a1 reverted to normal levels (lane 6 vs. 10 and lanes 7 vs. 9, Fig. 6V).

Second, the expression levels of fmhc4 and atp2a1 in the miR-3906 dsR (lane 2, Fig. 6V) or homer-1b-MO (lane 5, Fig. 6V) were lower than those of control WT embryos (lane 1, Fig. 6V) embryos. We examined whether the expression levels of muscle genes caused by excessive miR-3906 or by knockdown of homer-1b could be rescued by soaking embryos in caffeine during 20–24 hpf. Results showed that the expression levels of fmhc4 (lane 2 vs. 12, Fig. 6V) and atp2a1 (lane 5 vs. 13, Fig. 6V) were greatly increased in the embryos injected with either miR-3906 dsR or homer-1b-MO after soaking in caffeine, suggesting that caffeine increased [Ca2+]i of fast muscles and restored the defective gene expressions induced by overexpression of miR-3906 or by knockdown of homer-1b.

Third, we found that the expression levels of fmhc4 and atp2a1 in the embryos injected with miR-3906-MO and incubated with 2-APB (miR-3906-MO+2-APB) were both similar to their respective untreated control WT embryos (Fig. 6V, fmhc4 section, lane 1 vs. 15 = 1∶0.94; atp2a1 section, lane 1 vs. 15 = 1∶0.95). In contrast, when the miR-3906-MO-injected embryos were compared to the miR-3906-MO+2-APB-treated embryos, the mRNA expression levels of fmhc4 and atp2a1 were significantly decreased for the miR-3906-MO+2-APB-treated embryos (Fig. 6V, fmhc4 section, lane 3 vs. 15 = 1.53∶0.94; atp2a1 section, lane 3 vs. 15 = 1.54∶0.95). These results indicated that blocking calcium rise caused by miR-3906-MO could prevent changes of gene expression in fast muscle fibrils. Furthermore, we found that the expression levels of pHsp-wob-homer-1b+2-APB-treated embryos were slightly lower than those of untreated control WT (Fig. 6V, fmhc4 section, lane 1 vs. 16 = 1∶0.72; atp2a1 section, lane 1 vs. 16 = 1∶0.80). However, when the pHsp-wob-homer-1b-injected embryos were compared to the pHsp-wob-homer-1b+2-APB-treated embryos, the mRNA expression levels of fmhc4 and atp2a1 were significantly decreased for the pHsp-wob-homer-1b+2-APB-treated embryos (Fig. 6V, fmhc4 section, lane 8 vs. 16 = 1.79∶0.72; atp2a1 section, lane 8 vs. 16 = 1.46∶0.80). These results also indicated that blocking calcium rise caused by homer-1b could prevent changes of gene expression in fast muscle fibrils.

miR-3906 Inhibits Homer-1b Expression to Avoid Excessive Calcium Concentration in Muscle Cells

Although no significant deficiency was observed in external muscle morphology between wild-type embryos and embryos injected with miR-3906-MO and homer-1b-mRNA (Figs. 4B and 4C), the swimming behavior of larvae derived from either miR-3906-MO-injected embryos or homer-1b-mRNA-injected embryos was abnormal (Movie S1 in File S2). This fact prompted us to study whether the high concentration of calcium impacts muscle structure. We used phalloidin staining and confocal microscopy to examine fast muscle sarcomeric actin arrangement in fast muscle fibrils of embryos at 32 hpf. Sarcomeric actin arrangement showed fast muscle fibers in WT embryos as oriented in the same direction with clear dye-sarcomere boundaries (Fig. 7A). In comparison, the sarcomeric actin arrangement was bent with indistinct dye-sarcomere boundaries in the miR-3906-MO-injected embryos (Fig. 7B), homer-1b-mRNA-injected embryos (Fig. 7C), pHsp-homer-1b-injected (Fig. S6 in File S1) and caffeine-soaked embryos (from 20 to 32 hpf) (Fig. 7D). We further applied transmission electron microscopy to observe the sarcomeric ultrastructure in muscle cells. No defect of the sarcomeric ultrastructure could be seen in WT embryos (Fig. 7E), whereas the sarcomeric ultrastructure was disordered in the embryos injected with miR-3906-MO (Fig. 7F), injected with homer-1b-mRNA (Fig. 7G), or soaked in caffeine (Fig. 7H), because of the bent muscle fibers. In addition, the boundary structure between sarcomeres, such as actin filament bound by Z disk, could not be clearly defined. In WT embryos, a regular hexagonal arrangement of thick filament intercalating with thin filament could be seen in cross sections at a ratio of thick: thin = 6∶6 (Fig. 7I). In comparison, the relative location between the myosin heavy chain and actin filament was seriously disordered in miR-3906-MO-injected embryos (thick: thin = 6∶4.13±0.30) (Fig. 7J), homer-1b-mRNA-injected embryos (thick: thin = 6∶4.20±0.53) (Fig. 7K), and caffeine-soaked embryos (thick: thin = 6∶3.33±0.83) (Fig. 7L), indicating that the proportional arrangement between myosin heavy chain and actin filament was chaotic in the homer-1b-overexpressed embryos. This evidence suggested that higher calcium concentration in muscle cells causes loss of organization in sarcomeric actin arrangement, which, in turn, causes defective muscle development.

thumbnail
Figure 7. Either inhibition of miR-3906 or overexpression of homer-1b disrupts sarcomeric actin organization.

Using phalloidin stain, compared to (A) WT embryos, (B) miR-3906-MO-injected embryos, (C) homer-1b-mRNA-injected embryos and (D) caffeine-soaked embryos exhibited a bending and disruption of sarcomeric actin organization in muscle cells. In longitudinal section, compared to (E) WT control embryos, (F) the Z-disc structure displaying in miR-3906-MO-injected embryos, (G) homer-1b-mRNA-injected embryos and (H) caffeine-soaked embryos was chaotic (indicated by arrows), and the full-length sarcomeres in muscle fibers were interrupted (indicated by asterisks) and could not be seen completely in a full sarcomere line. In cross section, compared to (I) WT control embryos, the relative position and proportion between myosin heavy chain and actin filament among the (J) miR-3906-MO-injected embryos, (K) homer-1b-mRNA-injected embryos and (L) caffeine-soaked embryos were chaotic and extremely irregular. For each sample, we randomly selected five positions to identify their hexagonal arrangements and calculated the ratio between the thick and thin filaments (n = 3). Results were presented at the bottom right of each picture (I–L). M:M line;Z:Z-disc;scale bar:0.1 µm.

https://doi.org/10.1371/journal.pone.0070187.g007

The Upstream cis-element is Capable of Driving the Transcription of miR-3906 When the Host Gene myf5 Transcription is Absent

To prove whether the upstream cis-element is capable of driving the transcription of miR-3906, we constructed plasmids in which luc reporter was driven by various lengths of upstream segment located from +1 to +479 (+1/+479) (Fig. 8A). After injection, we found that the luciferase activities of embryos injected with those plasmids missing the +203/+302 segment (phRL-exon1-3) and the +303/+402 segment (phRL-exon1-4) increased and decreased greatly, compared to those of embryos injected with plasmids containing phRL-exon1-3 and phRL-exon1-4, respectively (Fig. 8B). In addition, the proximal upstream sequence of miR-3906 was capable of driving reporter gene activity, but with a greater driving strength at later developmental stages, such as 32 hpf, when the expression of host gene myf5 becomes weaker in trunk muscle than that observed at early developmental stages, such as 16 hpf, when myf5 expression is strong in trunk (Fig. 8C). This evidence suggested that the upstream elements of miR-3906 are capable of controlling the transcription of miR-3906, including segments such as +203/+302 and +303/+402, which are responsible for inhibition and activation of miR-3906 transcription, respectively. Therefore, we hypothesize that miR-3906 might be transcribed from the activation of segment +303/+402, when host gene myf5 apparently disappears from trunk muscle cells at later developmental stages, thereby reducing Homer-1b protein level in zebrafish embryos.

thumbnail
Figure 8. The proximal upstream cis-elements of miR-3906 are capable of controlling the transcription of miR-3906.

(A) The schematic diagrams of plasmid constructs having a 1.1 kb fragment upstream of myf5 gene and having various deletions of exon 1 of myf5 which are proximal upstream regulatory segments of miR-3906. (B) Luciferase activity assay in zebrafish embryos at 24 hpf. Plasmids phRL-exon1-1, phRL-exon1-2, phRL-exon1-3, phRL-exon1-4 and phRL-exon1-5 were co-injected individually with pGL3-TK, an internal control, into one-cell embryos. The luc expression of embryos injected with plasmid phRL-exon1-1 served as 1. The relative luc expression level of each combination was examined. (C) Luciferase activity assay in zebrafish embryos at 16, 24 and 32 hpf. Plasmids phRL-myf5-promoter and phRL-exon1-1 were co-injected individually with pGL3-TK, an internal control, into one-cell embryos. The luc expression of each plasmid at 16 hpf served as 1. The relative luc expression levels of phRL-myf5-promoter and phRL-exon1-1 at 24 and 32 hpf were examined. Data were presented as means±SD from three independent experiments (n = 3). Student's t-test was used to calculate the differences among data. *: indicates significant difference at P<0.05. **: indicates significant difference at P<0.01.

https://doi.org/10.1371/journal.pone.0070187.g008

Discussion

Regulation of Intracellular Calcium Concentration by Homer-1b Affects Muscle Development

Ca2+ channels, such as IP3R, RyR and TRPC, are expressed in skeletal muscle cells, and Homer proteins can bind them individually [46][48]. IP3R and RyR channels are located at SR membrane and are responsible for releasing Ca2+ from SR into cytoplasm. After differentiation of muscle cells, Stiber et al. [49] found that Homer proteins increase their expression levels greatly. For example, Homer-1 and Homer-2b are expressed to the degree required to release Ca2+ through the RyR channel to increase intracellular [Ca2+]. When the RyR channel is activated, nuclear factor of activated T cells (NFAT) enters the nucleus to turn on the expression of downstream muscle genes. Thus, Homer-1 protein not only has the ability to regulate the activation of the RyR channel, but also affects Ca2+-dependent signaling transduction during muscle cell differentiation.

In this in vivo study of zebrafish embryos, we demonstrated that Homer-1b regulates intracellular [Ca2+]. Specifically, we found that overexpression of homer-1b mRNA increases intracellular [Ca2+], while injection of homer-1b-MO decreases [Ca2+]i in muscle cells (Fig. 5). Meanwhile, since a) homer-1b mRNA was expressed at higher level and b) [Ca2+]i was increased in muscle cells of the miR-3906-MO-injected embryos, we concluded that miR-3906 affects [Ca2+]i in muscle cells by decreasing the translation of homer-1b mRNA (Fig. 5). We also observed that the release of [Ca2+]i was enhanced in the embryos soaked in caffeine, resulting in the increased expression of such fast muscle-specific genes as fmhc1 and atp2a1. In contrast, the release of [Ca2+]i was reduced in the embryos soaked in 2-ABP, resulting in the decreased expressions of fmhc1 and atp2a1 (Fig. 6), suggesting that the fast muscle gene expression of zebrafish is controlled by [Ca2+]i. Additionally, we demonstrated that the phenotypes caused by manipulating either miR-3906 or homer-1b expression can be rescued by changing calcium concentration. Therefore, we concluded that the miR-3906 or homer-1b system affects gene expression in the fast muscle fibrils, such as fmhc4and atp2a1, as a result of change in calcium influx and not through direct influence on the promoter activity of genes or the stability of mRNA. Thus, miR-3906 is capable of fine tuning [Ca2+]i in muscle cells through targeting homer-1b mRNA to decrease the protein level of Homer-1b, leading to decreased expression of fast muscle-specific genes (Fig. 6). On the other hand, irrespective of which method was employed to increase [Ca2+]i, i.e., by injection of miR-3906-MO or homer-1b mRNA or by soaking in caffeine, the expressions of fmhc1 and atp2a1 did not exhibit a significant difference in terms of somite number, compared to the wild-type embryos. Therefore, we believe that the control of muscle cell differentiation still requires the involvement of MRFs, such as myod and myogenin, while the increase of [Ca2+]i serves to provide an intracellular condition that favors the phosphorylation of MEF2 and NFAT in muscle cells to activate the expression of downstream genes.

Homeostasis of Intracellular Calcium Concentration is Required in Order to Maintain Normal Muscle Cell Development and Function

Morphological defects in muscle development were not found in either miR-3906-MO-injected embryos or homer-1b-mRNA-injected embryos, as demonstrated in this study. We did, however, observe a defect in swimming ability, including short-distance escape swimming and abnormal rotation, in the embryos injected with either miR-3906-MO or homer-1b mRNA. When we examined muscle structure under confocal microscopy, we found that both miR-3906-MO-injected embryos and homer-1b-mRNA-injected embryos exhibited a bent arrangement of muscle fibers, indistinct sarcomere boundaries, and lost organization of sarcomeric actin. These structural defects of muscle cells were also observed in the caffeine-soaked embryos. Furthermore, when we used electron microscopy to observe the ultrastructure of muscle cells, we found irregular arrangements in three kinds of embryonic sarcomere, vague Z line, and chaotic position between myosin heavy chain and actin filament (Fig. 7). This line of evidence suggested that excessive [Ca2+]i induced by injection of either miR-3906-MO or homer-1b mRNA causes ultrastructural defects in muscle cells. Interestingly, the defects found in zebrafish are similar to those found in mice, as reported by Stiber et al. [50], who demonstrated that homer-1-knockout mice displayed smaller myofibers and weaker muscle contraction. This myopathic phenomenon is conclusive for increased intracellular calcium concentration. Additionally, Millay et al. [51] reported that overexpression of transient receptor potential canonical 3 (TRPC3) causes an influx of intracellular calcium, leading to muscular dystrophy, which is similar to the dystrophin-glycoprotein complex (DGC)-deficient model phenotype. They also found that muscle gene expression was similar to that of the DGC-deficient dystrophic disease model. In this study, we also found a similarity between muscle atrophy in the trunk and tail of embryos injected with homer-1b-MO (Fig. 4) and the abnormal pattern of shortened somites in camk2b-MO-injected embryos [52]. This evidence suggested that loss of Ca2+-dependent signaling leads to more serious defects in muscle development. Therefore, either higher [Ca2+]i or lower [Ca2+]i causes muscle development defects, indicating homeostasis of [Ca2+]i in muscle cells is critical for normal muscle development and function at the differentiation stage. These findings lead to the conclusion that miR-3906 functions to fine tune the protein level of Homer-1b, which, in turn, affects [Ca2+]i homeostasis in muscle cells to control fast muscle differentiation rate and normal muscle structure and function.

Similar to miR-206, Different Target Genes of miR-3906 Play Unique Roles at each Stage of Embryonic Development

In responding to different developmental stages, miRNA plays a unique role in the dynamic process of embryo development. Since, for example, it has been shown that miR-206 has different target genes at different stages of mouse embryonic development [4], we hypothesized that miR-3906 might also target specific genes affecting muscle development during embryonic development.

To illustrate this phenomenon, miR-206 has been shown to impact the function of transcription factor Pax3 in muscle cells. Specifically, in early muscle development, the dermomyotome cells migrate to the limb bud and serve as precursor cells to form the limb muscles. Pax3 in dermomyotome cells modulates specialization and proliferation in muscle cells through its control of Myf5 and Myod [53], [54]. Goljanek-Whysall et al. [55] found that Pax3 is highly expressed in mice in the muscle cells of forelimbs and hindlimbs at HH24, whereas Pax3 is greatly decreased at HH28. In contrast, while miR-206 expression increases in limbs at HH24, it decreases at HH28. Thus, it appears that the expression of both pax3 and miR-206 in mouse limbs is dynamic and stage-dependent. Additionally, knockdown of miR-206 increases both the mRNA level and protein level of Pax3, suggesting that the expression of pax3 is negatively correlated with that of miR-206 and that miR-206 can control pax3 gene expression at the posttranscriptional level. Therefore, silencing of pax3 by miR-206 at the early somatic muscle developmental stage causes decreased specification and proliferation of muscle cells which, in turn, favors further differentiation of muscle cells. It has also been shown that miR206 is involved in TGF-β signaling which inhibits muscle cells from further differentiation. In this case, histone deacetylase 4 (HDAC4) is one of the downstream effectors of TGF-β. When muscle cells begin to differentiate, miR-206 silences HDAC4, allowing cells to differentiate and produce muscle regulatory protein MEF2 and muscle structure protein MHC [56]. At the same time, however, miR-206 can also silence the expression of tissue inhibitor of metalloproteinase 3 (TIMP3), which inhibits TNFαfrom downregulating the process of differentiation. Since TIMP3 is decreased by miR-206, the release of TNFαis increased, which results in enhancing the phosphorylation of p38 and expression of the muscle structural proteins Myogenin and MHCs. Under these conditions, the muscle cells finally proceed to differentiation [57].

Interestingly, in this zebrafish study, we found some of these same characteristics in miR-3906. First, we observed that miR-3906 is detectable from 16 hpf [17]. We could also detect the presence of miR-3906 in the trunk muscles, even as late as 8 dpf. At 16 hpf, miR-3906 is significantly increased in mature somites. As a result, the expression of dkk3a, a target gene of miR-3906, is inhibited in mature somites. Since dkk3a is decreased, the promoter activity of myf5 is immobilized. This then results in the significant reduction of myf5 expression in mature somites such that the expression of myf5 is almost undetectable in somites after 24 hpf. Taken together, this evidence suggested that miR-3906 reduces the specification of muscle cells, but facilitates the process of differentiation. Interestingly, during muscle cell differentiation after 24 hpf, homer-1b, another target gene of miR-3906, functions to increase the [Ca2+]i of muscle cells to facilitate fast muscle gene expression. At this stage, miR-3906 reduces the level of Homer-1b protein to maintain [Ca2+]i homeostasis. Therefore, similar to miR-206, which plays different functional roles in embryogenesis through its target genes, we concluded that miR-3906 inhibits the expression of either dkk3a or homer-1b at different developmental stages to ensure normal muscle development during myogenesis in embryos by facilitating specification or differentiation, respectively.

miR-3906 Fine Tunes homer-1b Expression and Affects Trunk Muscle, even in the Absence of Host Gene myf5 Transcription

Some intronic miRNAs are reported to be expressed at developmental stages absent transcription of host genes [58][60]. This phenomenon supports observations presented in this study. That is, although miR-3906 is derived from the myf5 transcripts in somites, the expression of myf5 is gradually reduced to an undetectable level in mature trunk somites after 20 hpf. Nonetheless, miR-3906 is continuously detectable in the front of mature trunk somites at 20 hpf, even persisting up to 8 dpf. Additionally, Mi et al. [61] demonstrated that has-miR-128b is overexpressed in blood cells of acute lymphoblastic leukemia patients when the promoter of its host gene ARPP21 is modified by hypomethylation and the promoter activity is decreased, indicating that the expression of has-miR-128b is controlled by its own promoter. In this study, we supported the hypothesis raised by the above reports because we proved that intronic miR-3906 is controlled by its own promoter at later developmental stages, thus providing an alternative explanation for the transcriptional decoupling between miR-3906 and its host gene myf5.

Conclusion

Based on the above evidence, as depicted in Figure 9, we concluded that normal muscle cell development during differentiation is characterized by [Ca2+]i homeostasis controlled by the negative regulation of Homer-1b concentration through miR-3906 in fast muscle fibrils, allowing Ca2+-dependent signaling transduction to induce the expression of fast muscle genes. However, when either miR-3906 or homer-1b mRNA expression is downregulated or overexpressed, a state of [Ca2+]i imbalance occurs, resulting in abnormal zebrafish embryonic development. Briefly, when excessive miR-3906 RNA is introduced or homer-1b-specific MO is injected to knock down homer-1b, the decrease in [Ca2+]i, e.g., below 120 nM, in muscle cells results in such severe consequences as body bending and tail shortening defects. On the other hand, when miR3906-specific MO is injected to knock down miR-3906 or excessive homer-1b mRNA is introduced, the increase in [Ca2+]i, e.g., over 200 nM, in muscle cells results in such developmental defects as sarcomeric actin disorganization and abnormal swimming behavior. Thus, miR-3906, by its fine tuning of homer-1b expression, functions delicately in muscle differentiation at the later developmental stage.

thumbnail
Figure 9. Schematic model illustrating how miR-3906 controls [Ca2+]i homeostasis in fast muscle cells during differentiation.

Overexpression or knockdown of either miR-3096 or homer-1b causes an imbalance between miR-3096 and homer-1b, resulting in disturbing [Ca2+]i homeostasis in the fast muscle cells during differentiation. At this developmental stage, miR-3906, which is transcribed from its own promoter, decreases [Ca2+]i through inhibiting the translation of homer-1b mRNA and causing the reduction of Homer-1b protein. This fine-tuning of the protein amount of Homer-1b by miR-3096 allows homer-1b to be present at a normal level in order to maintain [Ca2+]i homeostasis, thus ensuring normal fast muscle differentiation.

https://doi.org/10.1371/journal.pone.0070187.g009

Supporting Information

File S1.

File containing Figures S1–S6. Figure S1. miR-3906 persisted in the trunk muscle of zebrafish embryos at later developmental stages. (A, D) Using WISH to detect the expression of miR-3906, (B, E) miR-206 and (C, F) myf5 intron1 control-22nt of zebrafish embryos at 48 hpf and 8 dpf. (A) miR-3906 was detected both at 48 hpf and (D) 8 dpf in the trunk muscles of zebrafish embryos. (B, E) Detecting miR-206 expression served as a positive control, (C, F) while detecting the expression of myf5 intron1 control-22nt served as negative control. Figure S2. The putative target genes of miR-3906 using LAMP assay and microarray analysis. LAMP assay was performed for the cell extracts from zebrafish embryos at 32 hpf, and the possible target-RNAs of miR-3906 were analyzed by Zebrafish Whole Genome Microarray (Aligent). After standardization, 632 possible target genes of miR-3906 were predicted. Among them, 150 genes with higher binding capacity were selected and the NCBI’s ZFIN database used to define these plausible genes. Only 50 out of 150 genes had a complete gene sequence and were defined, including, for example, 4 genes of brain, 3 of the central nervous system (CNS), 1 of lens, 12 of muscles and 30 others from nonspecific regions. NA: not available. Figure S3. The mutated sequences of miR-3906 binding sites at the 3′UTR of homer-1b mRNA. (A) Three miR-3906 binding sequences at the 3′UTR of homer-1b mRNA were predicted at positions 1, 2 and 3. (B) Three mutated sequences of miR-3906 binding sites at the 3′UTR of homer-1b mRNA were shown at positions M1, M2 and M3. Figure S4. The expression patterns of homer-1b mRNA at various developmental stages. (A) Using reverse transcription-PCR to detect homer-1b transcripts in embryos at various stages as indicated. The homer1b cDNA was detected from 20 hpf until at least 72 hpf. No homer-1b primers were added to serve as negative control. Detection of β-actin cDNA served a positive control. Using whole mount in situ hybridization to detect the expression patterns of homer-1b mRNA in the muscle region of zebrafish embryos at indicated stages. (BF) were lateral view and (B’, G) were dorsal view. The homer-1b was starting to express at the dorsal somite (ds) in the front of mature somites at 20 hpf (B, B', arrow). At 22 hpf, homer-1b was detected at dorsal region (dorsal somite, ds) and ventral region (ventral somite, vs) in the front of mature somites (C, arrow). At 26 hpf, homer-1b expression was increased in the newly formed somites in tail (D). At 36 hpf, homer-1b transcripts were detected in trunk muscles (E, F). (G) At 60 hpf, homer-1b was also expressed in the trunk migratory muscles of fin bud (fb), posterior hypoaxial muscle (phm) and sternohyoideus (sh), as well as craniofacial muscles of adductor hyoideus (ah), adductor operculi (ao), dilator operculi (do) and levator arcus palatini (lap). Figure S5. Specific inhibition of homer-1b-morpholino (MO). (A) Diagrams depict the target sequences of homer-1b-MO against homer-1b mRNA fused with egfp mRNA (homer-1b-MO-target-egfp mRNA) and the mutated homer-1b mRNA at wobble sequences fused with egfp mRNA (wobble homer-1b-egfp mRNA). (B) The GFP signal was observed in the embryos at 32 hpf when injected with egfp mRNA only (100 pg), (C) homer-1b-MO (2 ng) injected with egfp mRNA (100 pg), (D) homer-1b-MO injected with homer-1b-MO-target-egfp mRNA, (E) homer-1b-MO injected with wobble homer-1b-egfp mRNA, (F) Photo-homer-1b-MO injected with homer-1b-MO-target-egfp mRNA without UV treatment and (G) Photo-homer-1b-MO injected with homer-1b-MO-target-egfp mRNA under UV exposure. GFP was not observed in embryos injected with homer-1b-MO and homer-1b-MO-target-egfp mRNA (D) and Photo-homer-1b-MO injected with homer-1b-MO-target-egfp mRNA under UV exposure (E). Figure S6. Induction to produce excessive homer-1b at late stage caused the disarrangement of actin filaments. We microinjected plasmid pHsp-wob-homer-1b into one-cell wild-type embryos and heat-shocked at 20 hpf for 30 min to overexpress wobble homer-1b mRNA. After heat shock, we employed phalloidin staining for embryos at 32 hpf to examine the alignment of sarcomeric actin of fast muscle cells. Compared with WT (A), the morphological trait of embryos injected pHsp-wob-homer-1b (B) was similar to that of WT. In WT embryo (C, C’), the actin filaments were bent and disordered, and the boundaries of sarcomeres were vague in pHsp-wob-homer-1b-injected embryos (D, D’). This evidence demonstrated that overexpression of homer-1b both at the one-celled stage and at 20 hpf caused the same effects on the arrangement of actin filaments in embryos.

https://doi.org/10.1371/journal.pone.0070187.s001

(DOC)

File S2.

File containing Movie S1. Movie S1. Swimming defect of miR-3906-MO and homer-1b mRNA injected embryos.

https://doi.org/10.1371/journal.pone.0070187.s002

(AVI)

Acknowledgments

We are grateful to Ms. Yi-Chun Chuang and Ms. Ya-Chan Yang, College of Life Science, NTU, for helping with the confocal laser scanning microscopy and transmission electron microscopy.

Author Contributions

Conceived and designed the experiments: HJT CYL. Performed the experiments: CYL JSC MRL CCH WYC. Analyzed the data: CYL JSC MRL CCH WYC. Wrote the paper: HJT CYL.

References

  1. 1. Filipowicz W, Bhattacharyya SN, Sonenberg N (2008) Mechanisms of post-transcriptional regulation by microRNAs: are the answers in sight? Nat Rev Genet 9: 102–114.
  2. 2. Stefani G, Slack FJ (2008) Small non-coding RNAs in animal development. Nat Rev Mol Cell Biol 9: 219–230.
  3. 3. Fabian MR, Sonenberg N, Filipowicz W (2010) Regulation of mRNA translation and stability by microRNAs. Annu Rev Biochem 79: 351–379.
  4. 4. Braun T, Gautel M (2011) Transcriptional mechanisms regulating skeletal muscle differentiation, growth and homeostasis. Nat Rev Mol Cell Biol 12: 349–361.
  5. 5. Buckingham M, Vincent SD (2009) Distinct and dynamic myogenic populations in the vertebrate embryo. Curr Opin Genet Dev 19: 444–453.
  6. 6. Ge Y, Chen J (2011) MicroRNAs in skeletal myogenesis. Cell Cycle 10: 441–448.
  7. 7. Chen JF, Mandel EM, Thomson JM, Wu Q, Callis TE, et al. (2006) The role of microRNA-1 and microRNA-133 in skeletal muscle proliferation and differentiation. Nat Genet 38: 228–233.
  8. 8. Chen JF, Tao Y, Li J, Deng Z, Yan Z, et al. (2010) microRNA-1 and microRNA-206 regulate skeletal muscle satellite cell proliferation and differentiation by repressing Pax7. J Cell Biol 190: 867–879.
  9. 9. Dey BK, Gagan J, Dutta A (2011) miR-206 and -486 induce myoblast differentiation by downregulating Pax7. Mol Cell Biol 31: 203–214.
  10. 10. van Rooij E, Quiat D, Johnson BA, Sutherland LB, Qi X, et al. (2009) A family of microRNAs encoded by myosin genes governs myosin expression and muscle performance. Dev Cell 17: 662–673.
  11. 11. Mishima Y, Abreu-Goodger C, Staton AA, Stahlhut C, Shou C, et al. (2009) Zebrafish miR-1 and miR-133 shape muscle gene expression and regulate sarcomeric actin organization. Genes Dev 23: 619–632.
  12. 12. Zhao Y, Samal E, Srivastava D (2005) Serum response factor regulates a muscle-specific microRNA that targets Hand2 during cardiogenesis. Nature 436: 214–220.
  13. 13. Rao PK, Kumar RM, Farkhondeh M, Baskerville S, Lodish HF (2006) Myogenic factors that regulate expression of muscle-specific microRNAs. Proc Natl Acad Sci U S A 103: 8721–8726.
  14. 14. Liu N, Williams AH, Kim Y, McAnally J, Bezprozvannaya S, et al. (2007) An intragenic MEF2-dependent enhancer directs muscle-specific expression of microRNAs 1 and 133. Proc Natl Acad Sci U S A 104: 20844–20849.
  15. 15. Sweetman D, Goljanek K, Rathjen T, Oustanina S, Braun T, et al. (2008) Specific requirements of MRFs for the expression of muscle specific microRNAs, miR-1, miR-206 and miR-133. Dev Biol 321: 491–499.
  16. 16. Lin CY, Chen YH, Lee HC, Tsai HJ (2004) Novel cis-element in intron 1 represses somite expression of zebrafish myf-5. Gene 334: 63–72.
  17. 17. Hsu RJ, Lin CY, Hoi HS, Zheng SK, Lin CC, et al. (2010) Novel intronic microRNA represses zebrafish myf5 promoter activity through silencing dickkopf-3 gene. Nucleic Acids Res 38: 4384–4393.
  18. 18. Hsu RJ, Yang HJ, Tsai HJ (2009) Labeled microRNA pull-down assay system: an experimental approach for high-throughput identification of microRNA-target mRNAs. Nucleic Acids Res 37: e77.
  19. 19. Chen YH, Lee WC, Liu CF, Tsai HJ (2001) Molecular structure, dynamic expression, and promoter analysis of zebrafish (Danio rerio) myf-5 gene. Genesis 29: 22–35.
  20. 20. Hsu RJ, Lin CC, Su YF, Tsai HJ (2011) dickkopf-3-related gene regulates the expression of zebrafish myf5 gene through phosphorylated p38a-dependent Smad4 activity. J Biol Chem 286: 6855–6864.
  21. 21. Feng W, Tu J, Yang T, Vernon PS, Allen PD, et al. (2002) Homer regulates gain of ryanodine receptor type 1 channel complex. J Biol Chem 277: 44722–44730.
  22. 22. Lin CY, Yung RF, Lee HC, Chen WT, Chen YH, et al. (2006) Myogenic regulatory factors Myf5 and Myod function distinctly during craniofacial myogenesis of zebrafish. Dev Biol 299: 594–608.
  23. 23. Westerfield M (1995) The Zebrafish Book, 3rd edn. University of Oregon Press, Eugene, OR.
  24. 24. Kimmel CB, Ballard WW, Kimmel SR, Ullmann B, Schilling TF (1995) Stages of embryonic development of the zebrafish. Dev Dyn 203: 253–310.
  25. 25. Lee HC, Huang HY, Lin CY, Chen YH, Tsai HJ (2006) Foxd3 mediates zebrafish myf5 expression during early somitogenesis. Dev Biol 290: 359–372.
  26. 26. Lee HC, Huang HY, Lin CY, Chen YH, Tsai HJ (2006) Foxd3 mediates zebrafish myf5 expression during early somitogenesis. Dev Biol 290: 359–372.
  27. 27. Maves L, Waskiewicz AJ, Paul B, CaoY, Tyler A, et al. (2007) Pbx homeodomain proteins direct Myod activity to promote fast-muscle differentiation. Development 134: 3371–3382.
  28. 28. Lin CY, Chen WT, Lee HC, Yang PH, Yang HJ, et al. (2009) The transcription factor Six1a plays an essential role in the craniofacial myogenesis of zebrafish. Dev Biol 331: 152–166.
  29. 29. Tallafuss A, Gibson D, Morcos P, Li Y, Seredick S, et al. (2012) Turning gene function ON and OFF using sense and antisense photo-morpholinos in zebrafish. Development 139: 1691–1699.
  30. 30. Eisenhoffer GT, Loftus PD, Yoshigi M, Otsuna H, Chien CB, et al. (2012) Crowding induces live cell extrusion to maintain homeostatic cell numbers in epithelia. Nature 484: 546–549.
  31. 31. Myhre JL, Pilgrim DB (2010) Cellular differentiation in primary cell cultures from single zebrafish embryos as a model for the study of myogenesis. Zebrafish 7: 255–266.
  32. 32. Grynkiewicz G, Poenie M, Tsien RY (1985) A new generation of Ca2+ indicators with greatly improved fluorescence properties. J Biol Chem 260: 3440–3450.
  33. 33. Ferrante MI, Kiff RM, Goulding DA, Stemple DL (2011) Troponin T is essential for sarcomere assembly in zebrafish skeletal muscle. J Cell Sci 124: 565–577.
  34. 34. Wang YX, Qian LX, Yu Z, Jiang Q, Dong YX, et al. (2005) Requirements of myocyte-specific enhancer factor 2A in zebrafish cardiac contractility. FEBS Lett 579: 4843–4850.
  35. 35. Te W, Lv Q, Wong CK, Hu S, Fu C, et al. (2008) The effect of central loops in miRNA:MRE duplexes on the efficiency of miRNA-mediated gene regulation. PLoS One 3: e1719.
  36. 36. Miranda KC, Huynh T, Tay Y, Ang YS, Tam WL, et al. (2006) A pattern-based method for the identification of MicroRNA binding sites and their corresponding heteroduplexes. Cell 126: 1203–1217.
  37. 37. Rehmsmeier M, Steffen P, Hochsmann M, Giegerich R (2004) Fast and effective prediction of microRNA/target duplexes. RNA 10: 1507–1517.
  38. 38. Fagni L, Worley PF, Ango F (2002) Homer as both a scaffold and transduction molecule. Sci STKE 2002: re8.
  39. 39. Stiber JA, Rosenberg PB (2011) The role of store-operated calcium influx in skeletal muscle signaling. Cell Calcium 49: 341–349.
  40. 40. Hahn K, DeBiasio R, Taylor DL (1992) Patterns of elevated free calcium and calmodulin activation in living cells. Nature 359: 736–738.
  41. 41. Webb SE, Miller AL (2003) Imaging intercellular calcium waves during late epiboly in intact zebrafish embryos. Zygote 11: 175–182.
  42. 42. Ashworth R (2004) Approaches to measuring calcium in zebrafish: focus on neuronal development. Cell Calcium 35: 393–402.
  43. 43. Koulen P, Janowitz T, Johenning FW, Ehrlich BE (2001) Characterization of the calcium-release channel/ryanodine receptor from zebrafish skeletal muscle. J Membr Biol 183: 155–163.
  44. 44. Chen YH, Huang YH, Wen CC, Wang YH, Chen WL, et al. (2008) Movement disorder and neuromuscular change in zebrafish embryos after exposure to caffeine. Neurotoxicol Teratol 30: 440–447.
  45. 45. Leung CF, Miller AL, Korzh V, Chong SW, Sleptsova-Freidrich I, et al. (2009) Visualization of stochastic Ca2+ signals in the formed somites during the early segmentation period in intact, normally developing zebrafish embryos. Dev. Growth Differ 51: 617–637.
  46. 46. Salanova M, Priori G, Barone V, Intravaia E, Flucher B, et al. (2002) Homer proteins and InsP(3) receptors co-localise in the longitudinal sarcoplasmic reticulum of skeletal muscle fibres. Cell Calcium 32: 193–200.
  47. 47. Ward CW, Feng W, Tu J, Pessah IN, Worley PK, et al. (2004) Homer protein increases activation of Ca2+ sparks in permeabilized skeletal muscle. J Biol Chem 279: 5781–5787.
  48. 48. Woo JS, Kim doH, Allen PD, Lee EH (2008) TRPC3-interacting triadic proteins in skeletal muscle. Biochem J 411: 399–405.
  49. 49. Stiber JA, Tabatabaei N, Hawkins AF, Hawke T, Worley PF, et al. (2005) Homer modulates NFAT-dependent signaling during muscle differentiation. Dev Biol 287: 213–224.
  50. 50. Stiber JA, Zhang ZS, Burch J, Eu JP, Zhang S, et al. (2008) Mice lacking Homer 1 exhibit a skeletal myopathy characterized by abnormal transient receptor potential channel activity. Mol Cell Biol 28: 2637–2647.
  51. 51. Millay DP, Goonasekera SA, Sargent MA, Maillet M, Aronow BJ, et al. (2009) Calcium influx is sufficient to induce muscular dystrophy through a TRPC-dependent mechanism. Proc Natl Acad Sci U S A 106: 19023–19028.
  52. 52. Rothschild SC, Easley CA, Francescatto L, Lister JA, Garrity DM, et al. (2009) Tbx5-mediated expression of Ca2+/calmodulin-dependent protein kinase II is necessary for zebrafish cardiac and pectoral fin morphogenesis. Dev Biol 330: 175–184.
  53. 53. Bajard L, Relaix F, Lagha M, Rocancourt D, Daubas P, et al. (2006) A novel genetic hierarchy functions during hypaxial myogenesis: Pax3 directly activates Myf5 in muscle progenitor cells in the limb. Genes Dev 20: 2450–2464.
  54. 54. Hu P, Geles KG, Paik JH, DePinho RA, Tjian R (2008) Codependent activators direct myoblast-specific MyoD transcription. Dev Cell 15: 534–546.
  55. 55. Goljanek-Whysall K, Sweetman D, Abu-Elmagd M, Chapnik E, Dalmay T, et al. (2011) MicroRNA regulation of the paired-box transcription factor Pax3 confers robustness to developmental timing of myogenesis. Proc Natl Acad Sci U S A. 108: 11936–11941.
  56. 56. Winbanks CE, Wang B, Beyer C, Koh P, White L, et al. (2011) TGF-beta regulates miR-206 and miR-29 to control myogenic differentiation through regulation of HDAC4. J Biol Chem 286: 13805–13814.
  57. 57. Liu H, Chen SE, Jin B, Carson JA, Niu A, et al. (2010) TIMP3: a physiological regulator of adult myogenesis. J Cell Sci 123: 2914–2921.
  58. 58. Wang D, Lu M, Miao J, Li T, Wang E, et al. (2009) Cepred: predicting the co-expression patterns of the human intronic microRNAs with their host genes. PLoS One 4: e4421.
  59. 59. Corcoran DL, Pandit KV, Gordon B, Bhattacharjee A, Kaminski N, et al. (2009) Features of mammalian microRNA promoters emerge from polymerase II chromatin immunoprecipitation data. PLoS One 4: e5279.
  60. 60. Monteys AM, Spengler RM, Wan J, Tecedor L, Lennox KA, et al. (2010) Structure and activity of putative intronic miRNA promoters. RNA 16: 495–505.
  61. 61. Mi S, Lu J, Sun M, Li Z, Zhang H, et al. (2007) MicroRNA expression signatures accurately discriminate acute lymphoblastic leukemia from acute myeloid leukemia. Proc Natl Acad Sci U S A 104: 19971–19976.