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Research Article

Induction of Ovarian Leiomyosarcomas in Mice by Conditional Inactivation of Brca1 and p53

  • Bridget A. Quinn,

    Affiliation: Fox Chase Cancer Center, Philadelphia, Pennsylvania, United States of America

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  • Tiffany Brake,

    Affiliation: Fox Chase Cancer Center, Philadelphia, Pennsylvania, United States of America

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  • Xiang Hua,

    Affiliation: Fox Chase Cancer Center, Philadelphia, Pennsylvania, United States of America

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  • Kimberly Baxter-Jones,

    Affiliation: Fox Chase Cancer Center, Philadelphia, Pennsylvania, United States of America

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  • Samuel Litwin,

    Affiliation: Fox Chase Cancer Center, Philadelphia, Pennsylvania, United States of America

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  • Lora Hedrick Ellenson,

    Affiliation: NewYork-Presbyterian Hospital, Weil Medical College of Cornell University, New York, New York, United States of America

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  • Denise C. Connolly mail

    Denise.Connolly@fccc.edu

    Affiliation: Fox Chase Cancer Center, Philadelphia, Pennsylvania, United States of America

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  • Published: December 31, 2009
  • DOI: 10.1371/journal.pone.0008404

Abstract

Background

Approximately one out of every ten cases of epithelial ovarian cancer (EOC) is inherited. The majority of inherited cases of EOC result from mutations in the breast cancer associated gene 1 (BRCA1). In addition to mutation of BRCA1, mutation of the p53 gene is often found in patients with inherited breast and ovarian cancer syndrome.

Methodology/Principal Findings

We investigated the role of loss of function of BRCA1 and p53 in ovarian cancer development using mouse models with conditionally expressed alleles of Brca1 and/or p53. Our results show that ovary-specific Cre-recombinase-mediated conditional inactivation of both Brca1LoxP/LoxP and p53LoxP/LoxP resulted in ovarian or reproductive tract tumor formation in 54% of mice, whereas conditional inactivation of either allele alone infrequently resulted in tumors (≤5% of mice). In mice with conditionally inactivated Brca1LoxP/LoxP and p53LoxP/LoxP, ovarian tumors arose after long latency with the majority exhibiting histological features consistent with high grade leiomyosarcomas lacking expression of epithelial, follicular or lymphocyte markers. In addition, tumors with conditional inactivation of both Brca1LoxP/LoxP and p53LoxP/LoxP exhibited greater genomic instability compared to an ovarian tumor with inactivation of only p53LoxP/LoxP.

Conclusions/Significance

Although conditional inactivation of both Brca1 and p53 results in ovarian tumorigenesis, our results suggest that additional genetic alterations or alternative methods for targeting epithelial cells of the ovary or fallopian tube for conditional inactivation of Brca1 and p53 are required for the development of a mouse model of Brca1-associated inherited EOC.

Introduction

Approximately 10% of cases of epithelial ovarian cancer (EOC) are associated with a clear hereditary predisposition to disease; the vast majority of cases resulting from inherited alterations in the breast cancer-associated tumor suppressor genes 1 or 2 (BRCA1 or BRCA2) (reviewed in: [1], [2], [3]). BRCA1 and BRCA2 were originally identified based on genetic linkage to families with an increased risk of breast and ovarian cancer. The proteins encoded by these genes control normal cellular growth by their involvement in DNA damage repair, maintenance of genomic integrity, chromatin remodeling and transcription regulation [4], [5]. Linkage to the BRCA1 gene exists in ~80% of families with inherited risk of breast and ovarian cancer [1], [2], [3]. Although mutations of the BRCA1 gene are not frequently detected in sporadic cases of EOC, recent studies have suggested that other mechanisms of inactivation of this tumor suppressor gene, such as promoter methylation and mutations in non-coding regions that effect functional protein expression, may exist in sporadic tumors [6], [7], [8], [9], [10]. In addition to alterations in BRCA1 and BRCA2, mutation of the p53 gene is reported in 70–90% of patients with familial breast and ovarian cancer syndrome [11], [12], [13], [14]. Interestingly, p53 mutations are identified more frequently in BRCA1-associated and sporadic serous ovarian carcinomas than in sporadic ovarian cancers of other histologic subtypes [11], [12], [13], [14]. A role for p53 in BRCA1-associated inherited breast and ovarian cancer is further supported by the cooperation of p53 with BRCA1 in the development of mammary tumor development in genetically engineered mouse (GEM) models [15], [16].

Despite recent advances in the development of GEM models of EOC [17], [18], [19], [20], [21] and the existence of mouse models of Brca1-associated inherited breast cancer [15], [16], analogous mouse models that develop Brca1-associated inherited invasive EOC have been more difficult to develop. The delay in developing such a model owes largely to controversy over the identity of the cell type of origin of BRCA1-associated inherited invasive EOC and the resultant difficulty in targeting molecular alterations to the correct cell type. Because homozygous deletion of Brca1 leads to early embryonic lethality in mice, attempts to establish such a model have employed strains of mice with conditional inactivation of Brca1. Two previous studies [22], [23] investigated the effects of ovary-specific conditional inactivation of Brca1 using distinct genetically engineered strains of mice harboring LoxP-flanked alleles of Brca1 [16], [24]. In these studies, ovary-specific Cre-recombinase expression was achieved by genetic means [22] or by direct administration of adenovirus encoded Cre-recombinase [23]. In both cases, ovary-specific conditional inactivation of Brca1 led to the development of pre-neoplastic [23] or benign [22] epithelial lesions in the ovary, but in neither case were invasive ovarian cancers observed. A separate study, using an ex vivo retroviral transduction strategy for conditional inactivation of LoxP-flanked Brca1 and p53 alleles in ovarian explants, showed that inactivation of both Brca1 and p53 in conjunction with expression of Myc led to transformation of ovarian cells and that these cells were tumorigenic in recipient mice [25]. In the present study, we sought to extend these previous observations by testing whether conditional inactivation of Brca1 and p53 in the ovarian surface epithelium in situ is sufficient to establish an autochthonous mouse model of BRCA1-associated invasive EOC. To this end, we used previously established strains of genetically engineered mice harboring LoxP-flanked Brca1 [16] in conjunction with mice harboring LoxP-flanked p53 [26] or a missense gain-of-function mutant allele of p53 [27] that is analogous to the R175H hotspot mutation frequently identified in human cancers [28], [29], [30].

Results

Intrabursal Administration of Adenovirus Results in Efficient Infection of Ovarian Surface Epithelial Cells

Because Brca1−/− (knockout) mice are embryonic lethal and p53−/− mice develop and succumb from tumors (e.g., lymphoma, sarcoma, etc.) at young ages, the present study utilized genetically engineered mouse strains that express LoxP recombination sites within the Brca1 and p53 alleles, thus allowing conditional inactivation of each allele upon exposure to Cre-recombinase [31]. Since there are no existing mouse models that exhibit ovarian surface epithelium (OSE)-restricted expression of Cre-recombinase, we chose a viral approach for conditional Cre-mediated inactivation of LoxP-flanked alleles by intrabursal administration of Adenovirus-Cre. To demonstrate our capability to successfully perform intrabursal injections that result in OSE-restricted viral infection, we performed pilot experiments in which 8 week-old female C57Bl/6 mice received intrabursal injections of Ad5-CMV-ntLacZ as previously described [18], [19], [21], [23]. To test the extent and localization of viral infection, eight week-old female C57Bl/6 mice were given intrabursal injections of 5×107 p.f.u. of Ad5-CMV-ntLacZ and euthanized one week post-surgery. Ovaries were dissected, snap frozen, sectioned and stained for β-galactosidase expression. Single intrabursal injection of Ad5-CMV-ntLacZ resulted in high efficiency, tissue restricted infection of the OSE with little or no infection of the underlying ovarian stromal tissue as shown by the β-galactosidase staining of thin sections of ovary (Figure 1A, panels a and b). Although staining was predominantly confined to the OSE, occasional β-galactosidase positive cells were observed in the fallopian tube (1A, panel c). No evidence of β-galactosidase staining was detected in the uterus or other organs indicating that viral infection had not spread beyond the site of injection (data not shown).

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Figure 1. Intrabursal injection of Adenovirus results in ovarian surface epithelial cell-restricted infection.

A) Histochemical detection of β-galactosidase expression in tissue sections of ovaries of a wild type mouse that received intrabursal injection of Ad5-CMV-LacZ show staining of the ovarian surface epithelium and absence of staining of the underlying ovarian cortex (panels a and b). Occasional β-galactosidase positive cells were also observed in fallopian tube (panel c) while no staining was observed in a control mouse injected with PBS (panel d). Scale bars in each image represent 100 µm. B) PCR amplification of LoxP containing sites in introns 4 (top) and 13 (bottom) of Brca1 in Brca1LoxP/LoxP, Brca1wt/wt, Brca1wt/Δ5-13 and Brca1WT/LoxP mice. Genomic DNA was isolated after digestion with proteinase K from the following tissues: liv–liver, t–tail, ut–uterus, ov 30′–ovary after 30 minute digestion and ov 12 h–ovary after 12 hours of digestion. The sizes of the LoxP flanked and wild type (wt) intron 4 and 13 PCR products are indicated. C) PCR amplification of 594 nt excised Brca1Δ5-13 allele was detected only in the ovary exposed to digestion for 30 minutes and in the genomic DNA isolated from a Brca1wt/Δ5-13 mouse.

doi:10.1371/journal.pone.0008404.g001

Cre-LoxP-Mediated Conditional Inactivation of Brca1

To confirm infection with Ad5-CMV-Cre and tissue-restricted Cre-mediated excision of LoxP-flanked sequences, Brca1LoxP/LoxP mice received intrabursal injection of Ad5-CMV-Cre and were euthanized one week post-surgery and the ovaries, uterus and liver were excised. Because the OSE is a comparatively small component of the total ovary, detection of Cre-mediated excision of LoxP flanked sequences in the ovaries of Brca1LoxP/LoxP mice would likely be obscured if genomic DNA from the entire ovary was used for PCR amplification and detection of excision. To circumvent this issue, we prepared a tissue lysate enriched for digested OSE by limiting the initial digestion time of ovary specimens to 30 min. The remainder of the undigested ovary was then digested overnight. Genomic DNA was isolated from each tissue and PCR amplified using both the forward and reverse primers for Brca1 introns 4 and 13. Cre-mediated excision of LoxP-flanked sequences of Brca1LoxP/LoxP was detected by amplification with Brca1-int4-Fwd and Brca1-int13-Rev primers. As expected, PCR amplification resulted in detection of LoxP flanked sequences in all tissues of the Brca1LoxP/LoxP mice (Figure 1B). Importantly, the excised Brca1Δ5-13 product was detected only after short (30 min) digestion of the ovary and not in the liver, uterus or the remainder of the ovary specimens that were digested overnight (Figure 1C). These results confirm successful infection of the ovary by Ad5-CMV-Cre and Cre-mediated excision of LoxP-flanked Brca1 sequences. Moreover, the absence of the excised Brca1Δ5-13 product in the ovary specimens digested overnight (Figure 1C) suggests that the Ad5-CMV-Cre infection is limited to the outer part of the ovary (the OSE) without substantial penetration of the ovarian cortex or infection of uterus or other peritoneal organs.

Based on the successful demonstration of efficient, tissue-restricted infection with the Ad5-CMV-ntLacZ and Ad5-CMV-Cre viruses, we commenced with intrabursal Ad5-CMV-Cre injection of the following groups of mice: 1) Brca1LoxP/LoxP, 2) p53LoxP/LoxP, 3) Brca1LoxP/LoxP;p53LoxP/LoxP, 4) Brca1LoxP/LoxP;p53+/515A and 5) Brca1LoxP/LoxP;p53LoxP/515A. The total number of mice receiving bilateral or unilateral injection of Ad5-CMV-Cre or unilateral injection of PBS (control) for each group is summarized in Table 1.

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Table 1. Summary of tumor incidence following intrabursal injection of Ad5-CMV-Cre recombinase.

doi:10.1371/journal.pone.0008404.t001

Conditional Loss of Brca1 or p53 Alone Infrequently Results in Ovarian Tumor Formation

A total of 51 Brca1LoxP/LoxP mice were evaluated (see Table 1 and Figure 2A), including 40 mice that received bilateral and 5 mice that received unilateral injection of Ad5-CMV-Cre as well as 6 unilateral PBS injected controls. The reproductive tracts and pathologically altered organs were isolated from all of these mice and subjected to histopathological evaluation (by L.H.E.). Of these 51 mice, 9/40 mice (23%) that received bilateral Ad5-CMV-Cre injection and 1/6 (17%) mice that received unilateral PBS injection developed tumors (Table 1) after long latency (i.e., average = 491±26 days after Ad5-CMV-Cre injection). No ovarian or reproductive tract tumors were detected (Figure 2A), and 8/9 tumors arising in bilaterally injected mice and the single tumor arising in a PBS injected mouse were extra-peritoneal. Because the tumors were located at sites distant from the site of Ad5-CMV-Cre injection, we considered the possibility that intrabursal injection of virus was leaky resulting in local or systemic infection beyond the original site of injection. To test this experimentally, genomic DNA was isolated from each of these tumors and subjected to PCR amplification of LoxP-flanked Brca1 sequences in introns 4 and 13 and the excised Brca1Δ5-13 product. Importantly, the Brca1Δ5-13 excision product was not detected in any of the tumors identified in the Brca1LoxP/LoxP mice (Table 1 and data not shown). These results suggest that the tumors observed were sporadic and unrelated to the Cre-mediated excision of Brca1LoxP/LoxP resulting from local or systemic viral infection. The lack of ovarian tumors is consistent with previous studies [22], [23], [25] demonstrating that inactivation of Brca1 alone is insufficient for malignant transformation in the mouse ovary.

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Figure 2. Incidence and latency of reproductive tract tumors in female mice with conditional inactivation of LoxP flanked alleles of Brca1 and/or p53.

A) Fraction of tumor free mice after intrabursal injection of Adenovirus-Cre recombinase. B) Genotyping analysis of DNA isolated from Brca1Δ5-13;p53Δ2-10 and p53Δ2-10 ovarian tumors. Both the Lox P flanked and excised Brca1 and p53 alleles were amplified from Brca1Δ5-13;p53Δ2-10 tumors (cases 307, 350, 352 355, 397, 399, 411 and 412) and the Lox P flanked and excised p53 allele was amplified from the single p53Δ2-10 ovarian tumor (case 627). In each panel the left lane contains a DNA ladder and the sizes of the amplified products (nt) are indicated at the right.

doi:10.1371/journal.pone.0008404.g002

Among the p53LoxP/LoxP mice evaluated in this study (n = 53), 41 received bilateral and 6 received unilateral injections of Ad5-CMV-Cre and 6 received unilateral injection with PBS (Table 1). None of the control PBS injected mice developed tumors, but a low frequency of tumor formation (3/53 mice) was observed in Ad5-CMV-Cre injected mice (Table 1 and Figure 2A). Specifically, one mouse developed a large palpable ovarian mass 132 days after bilateral Ad5-CMV-Cre injection, one mouse developed a small mass at the end of one of the uterine horns 373 days after unilateral injection of Ad5-CMV-Cre, and one control mouse developed a palpable subcutaneous mass located near the scapulae 353 days after PBS injection. Analysis of the genomic DNA isolated from the ovarian and uterine tumors resulted in amplification of the excised p53Δ2-10 product (Figure 2B and data not shown), whereas no excision product was amplified from the DNA isolated from the subcutaneous scapular tumor. These results suggest that conditional inactivation of p53 alone rarely results in ovarian tumor development (1/47 cases, 2%). This finding is again consistent with a previous study [19] reporting low frequency of ovarian tumor development (2/31 cases, 6%) after intrabursal Adenovirus-cre mediated conditional inactivation of p53.

Conditional Loss of Both Brca1 and p53 Cooperates to Induce Ovarian Tumors

To determine whether inactivation of both Brca1 and p53 in the OSE can cooperate to induce ovarian tumorigenesis, we evaluated ovarian tumor formation in Brca1LoxP/LoxP;p53LoxP/LoxP, Brca1LoxP/LoxP;p53+/515A and Brca1LoxP/LoxP;p53LoxP/515A mice following intrabursal injection of Ad5-CMV-Cre. It is important to note that the p53515A mice used in the current study constitutively expressed the arginine to histidine substitution at amino acid 172 of p53. As previously reported [27], mice harboring the homozygous constitutively expressed mutant p53515A/515A allele developed tumors with an incidence, latency and spectrum (e.g., lymphomas and sarcomas) similar to that of homozygous p53 knockout mice [32], [33]. Ovarian tumors were not detected in any of the Brca1LoxP/LoxP;p53+/515A and Brca1LoxP/LoxP;p53LoxP/515A mice at the time of euthanasia; therefore, these two groups were not informative for this study.

A total of 47 Brca1LoxP/LoxP;p53LoxP/LoxP mice were evaluated. Among these, 35 received bilateral Ad5-CMV-Cre injection, 6 received unilateral Ad5-CMV-Cre injection and 6 control mice were injected with PBS (Table 1). Tumors were detected in 20/35 (57%) mice with bilateral and 4/6 (66%) mice with unilateral injection of Ad5-CMV-Cre (Table 1 and Figure 2A) after long latency (409±81 days after Ad5-CMV-Cre injection). Pair-wise log-rank tests showed that Brca1LoxP/LoxP;p53LoxP/LoxP mice had significantly shorter average survival after conditional inactivation of LoxP flanked alleles than Brca1LoxP/LoxP or p53LoxP/LoxP mice (p<0.000001 and p<0.05 respectively). Among the 24 total tumors, we were able to demonstrate Cre-mediated excision of LoxP flanked sequences of both Brca1LoxP/LoxP and p53LoxP/LoxP in 23 cases (Table 2, Figure 2B and data not shown). The majority (22/23) of the tumors detected in Brca1LoxP/LoxP;p53LoxP/LoxP mice were associated with the ovaries and reproductive tract, and all exhibited Cre-mediated excision of LoxP flanked sequences (Table 2). Among these, there were 7 leiomyosarcomas of the ovary, 4 leiomyosarcomas of the ovary and uterus, 8 ovarian sarcomas, one malignant teratoma, one sclerosing stromal tumor of the uterus and one uterine adenocarcinoma. The only case in which the Brca1Δ5-13 and p53Δ2-10 excision products were not detected was a peritoneal sarcoma that was not associated with the reproductive tract. Thus, conditional loss of both Brca1 and p53 in the ovary leads to a high frequency of ovarian and reproductive tract tumor formation.

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Table 2. Summary of tumors associated with Cre-mediated inactivation of Brca1 and/or p53.

doi:10.1371/journal.pone.0008404.t002

Histopathological Features of Tumors Arising in Mice with Conditionally Inactivated Brca1 and/or p53

With the exception of one unclassifiable necrotic peritoneal mass, all of the tumors identified in Brca1LoxP/LoxP mice were classified as carcinomas. Among these was one vaginal squamous carcinoma, two subcutaneous adenocarcinomas located near the scapulae and five lung adenocarcinomas (not shown). PCR amplification of the excised Brca1Δ5-13 product was not detected in any of these cases leading to the conclusion that these carcinomas were sporadic in nature. The relatively high frequency of sporadic tumor occurrence in this strain of mice remains unexplained.

In contrast to previous studies [22], [23], the ovaries of Ad5-CMV-Cre injected Brca1LoxP/LoxP mice were histologically unremarkable and did not exhibit noteworthy morphological or histological changes of the OSE indicative of pre-neoplastic or neoplastic growth. Brca1LoxP/LoxP mice that received bilateral intrabursal Ad5-CMV-Cre injections were observed for an average of 475 days (±102 days) prior to euthanasia suggesting that conditional inactivation of Brca1 alone is insufficient to cause ovarian tumors even after long latency.

Histopathological evaluation of the single ovarian mass detected in a p53LoxP/LoxP mouse that received bilateral Ad-CMV-Cre injection showed that the tumor was an ovarian leiomyosarcoma (Figure 3A). The tumor was composed of spindle cells with marked cytologic atypia and numerous mitotic figures, including abnormal mitotic figures. The only other tumor detected in this group was a small uterine mass classified as a uterine leiomyosarcoma. In Brca1LoxP/LoxP;p53LoxP/LoxP mice that received bilateral Ad5-CMV-Cre injection, 23/41 (56%) mice developed confirmed Brca1Δ5-13;p53Δ2-10–associated tumors, most of which were ovarian. Among the ovarian tumors, the majority were categorized as soft tissue tumors including ovarian leiomyosarcomas (n = 12) and high grade sarcomas that could not be further classified (n = 4). These leiomyosarcomas exhibited spindle cells with marked atypia and the high grade sarcomas demonstrated pleiomorphic atypia without other specific morphologic features (Figure 3A). The ovarian tumors identified were highly proliferative as evidenced by nearly uniform PCNA staining (Figure 3A, panels c, g, and k) and, consistent with Cre-mediated inactivation of p53LoxP/LoxP, lacked expression of p53 (Figure 3A, panels d, h, and l). The ovarian tumors also lacked histopathological features or immunohistochemical staining of granulosa cell (α-inhibin), epithelial (CK8 and CK 19), lymphoid (CD3 and CD45R) or α-smooth muscle actin (α-SMA) differentiation (Figure 3B and data not shown). Thus, while conditional inactivation of both Brca1 and p53 resulted in a high frequency of ovarian tumor development, no ovarian carcinomas were detected.

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Figure 3. Histopathological characterization of ovarian tumors arising in Brca1Δ5-13;p53Δ2-10 and p53Δ2-10 mice after intrabursal administration of Ad5-CMV-Cre.

A) Low (panels a, e, and i) and high (panels b, f, and j) magnification of H&E stained sections of tumors isolated from two Brca1Δ5-13;p53Δ2-10 mice (cases number 307, panels a–d, and 399, panels e–h) and one p53Δ2-10 mouse (case number 627, panels i-l). Immunohistochemical detection of proliferating cell nuclear antigen (PCNA) shows that all three tumors were highly proliferative (panels c, g, and k). Immunohistochemical staining for p53 (Panels d, h, and l) showing that none of the tumors express p53 protein, consistent with the conditional inactivation of the LoxP-flanked p53 allele. B) Immunohistochemical staining of Brca1Δ5-13;p53Δ2-10 case number 307, a representative tumor, shows that the tumor is highly proliferative (PCNA staining, panel a), but does not express other common differentiation markers. Immunostaining for α-inhibin (panel b) shows isolated positively staining follicular cells and little or no staining of the tumor cells. Similarly, immunohistochemical detection of markers of lymphoid (CD45, panel c) epithelial (cytokeratins 8 and 19, panels d and e respectively) and stromal (α-smooth muscle actin, panel f) differentiation are not detected in tumor cells. Scale bars in each image represent 100 µm.

doi:10.1371/journal.pone.0008404.g003

Brca1 and p53 Tumors Exhibit Genomic Instability

Genomic DNA isolated from the single p53Δ2-10 ovarian leiomyosarcoma and two cases of Brca1Δ5-13;p53Δ2-10 ovarian leiomyosarcomas was subjected to array based comparative genomic hybridization (aCGH) analysis. The p53Δ2-10 ovarian leiomyosarcoma (case number 627) exhibited gains and/or losses of entire chromosomes analogous with aneuploidy and occasional isolated regions of DNA copy number alterations (Figure 4A). By comparison, the Brca1Δ5-13;p53Δ2-10 ovarian leiomyosarcomas (case numbers 307 and 399) exhibited a much more complex array of genetic copy number alterations including entire chromosomal gains and losses as well as distinct regions of DNA gains and losses within the same chromosome (Figure 4A); results suggestive of a high degree of chromosomal damage. Karyotypic analysis of a tumor cell line established from Brca1Δ5-13;p53Δ2-10 ovarian leiomyosarcoma case number 399 supported this observation. A total of 26 metaphase spreads were analyzed, 22 of which were karyotyped (Figure 4B). The number of chromosomes per individual metaphase ranged from 65 to 143, with no clear modal number. However, 18 metaphases were near-tetraploid, with chromosome counts ranging from 65–87. Seven metaphases had counts ranging from 97–143. The remaining metaphases showed a high level of chromosomal damage with many fragments, double minutes and a tri-radial rearrangement. Four of the metaphases had 1–3 chromosome or chromatid breaks, and 18 metaphases had one or more small markers or fragments. Thus, the cytogenetic analysis of this tumor cell line revealed considerable genomic instability. Due to the absence of Brca1Δ5-13 tumors were unable to assess chromosomal stability in mice with conditional inactivation of Brca1 alone; however, these results support the hypothesis that loss of Brca1 function leads to a high degree of genetic instability thus contributing to ovarian tumorigenesis.

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Figure 4. Brca1Δ5-13;p53Δ2-10 tumors exhibit a high degree of genomic instability.

A) Array based comparative genomic hybridization was performed using genomic DNA isolated from p53Δ2-10 (case #627) and Brca1Δ5-13;p53Δ2-10 (cases #307 and #399) ovarian tumors and shows that while p53Δ2-10 tumors exhibit alterations consistent with aneuploidy, the Brca1Δ5-13;p53Δ2-10 ovarian tumors exhibit complex patterns of chromosomal copy number changes, with gains and losses apparent within the same chromosome. B) The high degree of genetic instability was verified by metaphase chromosome analysis of a cell line derived from Brca1Δ5-13;p53Δ2-10 tumor #399.

doi:10.1371/journal.pone.0008404.g004

Discussion

Although the lifetime risk of developing ovarian cancer is increased in women with germline mutations of BRCA1, previous studies in mice suggest that loss of Brca1 alone was insufficient to lead to the development of EOC [22], [23], [25]. A number of independent studies [11], [12], [13], [14] have shown that in cases of EOC with BRCA1 mutations, the frequency of mutations of p53 is high, ranging from 70–90%. Moreover, in mouse models of mammary cancer, tumor latency is decreased and incidence of tumor formation increased in mice with both conditional inactivation of Brca1 and a p53 null allele [15]. This apparent cooperation of Brca1 and p53 in inherited breast and ovarian cancer in humans and in mammary tumor development in mice led us to create a mouse model of ovarian cancer by conditional inactivation of Brca1 and p53 in the ovarian epithelium.

Mice that are null or heterozygous for p53 are highly prone to developing tumors, particularly lymphomas and sarcomas [33], [34]. For reasons that are not completely understood, the occurrence of epithelial tumors is relatively rare. More recent studies [27], [35] show that mice that have homozygous or heterozygous missense mutations of p53 develop tumors with similar latency and spectrum to that of mice that are p53 null or heterozygous, but that they also develop osteosarcomas and carcinomas with higher frequency. Missense mutations of p53 have been shown to confer gain-of-function phenotypes compared to p53 null mutations [27], [35]. Therefore, to develop a mouse model of Brca1- and p53-associated inherited EOC, we used two approaches for inactivation or mutation of p53. First, we predicted that using a strategy for tissue-restricted conditional inactivation of p53LoxP/LoxP in combination with Brca1LoxP/LoxP in the OSE would result in predisposition for the development of ovarian carcinomas. The second approach was based on the idea that missense mutations of p53 confer gain-of-function phenotypes and possibly alter tissue specificity, favoring the development of carcinomas [27], [35]. Therefore, we also employed a mouse model expressing a missense mutation of p53 (p53515A, analogous to the p53 R175H hotspot mutation in human cancers [27]) in conjunction with Brca1LoxP/LoxP. Our results were consistent with previous findings in that ovary-specific conditional inactivation of either Brca1 or p53 alone rarely resulted in the development of invasive tumors [19], [22], [23], [25]. However, Cre-mediated conditional inactivation of both Brca1 and p53 resulted in the development of tumors in 56% (23/41) of the mice evaluated. Although mice heterozygous for the p53+/515A mutant allele develop tumors (i.e., lymphomas or sarcomas) with similar latency to p53+/− mice [27], we hypothesized that in mice that had also undergone Cre-mediated conditional inactivation of Brca1, ovarian carcinoma development might either out-pace or occur coincidentally with tumors at other sites. However, in spite of additional ovary-specific conditional inactivation of Brca1, tumors necessitating euthanasia developed at sites other than the ovary in Brca1LoxP/LoxP;p53+/515A and Brca1LoxP/LoxP;p53LoxP/515A mice. Histopathological evaluation revealed no ovarian or reproductive tract tumors in these mice. The strain of mice used in our study had been previously crossed with mice expressing Cre-recombinase under transcriptional control of the CMV gene promoter resulting in constitutive expression of the p53515A allele. It is therefore unknown whether mice would develop ovarian tumors if expression of p53+/515A or p53LoxP/515A were confined only to the OSE. Our results do suggest that ovarian tumor development in Brca1LoxP/LoxP;p53+/515A and Brca1LoxP/LoxP;p53LoxP/515A mice would require long latency and/or additional genetic alterations.

BRCA1-associated ovarian carcinomas in women typically exhibit serous histology [1]. Histopathological evaluation of the 22 Brca1Δ5-13;p53Δ2-10 and two p53Δ2-10 reproductive tract tumors unexpectedly showed a complex spectrum of tumors; ovarian leiomyosarcomas and sarcomas were most prevalent. In women, primary ovarian sarcomas are exceptionally rare [36], with very little known regarding the molecular alterations that contribute to their development. The reason for the lack of ovarian adenocarcinoma development in Brca1LoxP/LoxP;p53LoxP/LoxP mice given intrabursal injections of Ad5-CMV-Cre is unclear. Given the demonstration of highly selective ovarian surface epithelium infection after intrabursal administration of adenovirus, it seems unlikely to be due to technical issues associated with the injection procedure. The long latency between Ad5-CMV-Cre administration and the detection of tumors (~400±100 days) and the high degree of genomic instability detected in tumors by aCGH and karyotyping analysis strongly suggests that additional events are required for ovarian tumorigenesis. This is consistent with previous findings [25] showing that ex vivo conditional inactivation of both Brca1 and p53 in ovarian explants was insufficient for transformation, whereas the addition of Myc cooperated to induce transformation in these cells. One possible explanation for the high incidence of ovarian leiomyosarcomas is that ovarian stromal cells may be coincidentally infected after intrabursal injection of Ad5-CMV-Cre and that the combined loss of both Brca1 and p53 renders this population of cells more susceptible to transformation than the ovarian surface epithelium. Consistent with this is the observation that p53 null mice frequently develop sarcomas [33], [34]. Cre-mediated recombination of p53LoxP/LoxP alleles results in deletion of p53 exons two through ten, thus rendering the cells and tissues undergoing recombination effectively p53 null. Although this may potentially explain the high frequency of ovarian leiomyosarcomas observed, a previous study employing intrabursal adenovirus-Cre-recombinase mediated inactivation of LoxP-flanked sequences in p53LoxP/LoxP;RbLoxP/LoxP mice reported a high prevalence of ovarian carcinomas rather than leiomyosarcomas [19], suggesting the explanation may be more complicated than just relative tissue susceptibility in mice with p53 mutations.

An alternative explanation for the lack of epithelial cancers in this model comes from several recent studies [37], [38], [39], [40] suggesting the precursor lesion of ovarian tumors arising in BRCA1 mutation carriers may reside in the fallopian tube rather than the ovarian surface epithelium. These studies have nominated regions of distal fallopian tube mucosa exhibiting stabilized p53 protein, termed “p53 signatures”, and occult non-invasive intraepithelial serous carcinomas identified in prophylactic salpingo-oophorectomy specimens of BRCA1 mutation carriers as candidate precursors of invasive ovarian and/or pelvic serous carcinomas. In fact, some suggest “p53 signatures” present in distal fallopian tube of non-BRCA1 carriers as a plausible site of tumor origin for many sporadic ovarian and peritoneal cancers [41]. This may suggest that in attempting to model inherited EOC, the relevant target tissue for recombination and excision of Brca1 and p53 may not be the OSE, but rather the epithelium of the distal fallopian tube. Based on the anatomy of murine distal fallopian tube and ovary, intrabursal injection of Ad5-CMV-Cre would be predicted to result in viral contact with at least a portion of the tubal fimbria. This prediction is supported by our observation of isolated β-galactosidase positive cells present in the fallopian tube after intrabursal injection of Ad5-CMV-LacZ. However, this strategy appears to result in less frequent recombination in the fallopian tube than the OSE. Interestingly, in a very recent study that used a genetic approach for reproductive tract restricted Cre-recombinase expression by crossing Amhr2-Cre transgenic mice with Brca1LoxP/LoxP and/or p53LoxP/LoxP mice showed that while Cre-mediated recombination of floxed Brca1 and p53 alleles could be demonstrated in the ovaries, fallopian tubes and uteri of compound transgenic mice, the tumors that developed in these mice were all uterine leiomyosarcomas rather than ovarian tumors of any type [42]. Further studies will likely elucidate whether secretory epithelial cells of the tubal fimbria are the primary cell of origin of BRCA1-associated and/or sporadic serous ovarian carcinomas. If this is the case, an alternate strategy for development of mouse models of inherited Brca1-associated, and possibly sporadic serous EOC, would be to develop a transgenic strain of mice that express the Cre-recombinase gene under transcriptional control of a gene expressed selectively in the fallopian tube epithelium, such as the oviduct-specific glycoprotein 1 gene [43], [44].

Unlike other tumor suppressor genes, loss or mutation of BRCA1 confers a selective risk for cancer development in organs such as breast, ovary and prostate. The mechanisms of enhanced tissue-specific risk are unclear, but suggest that production of or responsiveness to hormones may play an important role. Recent work suggests that BRCA1 inactivation contributes to ovarian tumor development by cell non-autonomous mechanisms [22]. In this study, investigators used a Cre/LoxP strategy to specifically inactivate Brca1 in the granulosa cells of the mouse ovary by crossing Brca1LoxP/LoxP mice to transgenic mice expressing Cre-recombinase under transcriptional control of the follicle stimulating hormone receptor (Fshr) gene promoter. Otherwise genetically normal female mice with Brca1 inactivated only in granulosa cells developed benign epithelial ovarian neoplasms [22]. Analysis of microdissected epithelial lesions confirmed that no excision of the LoxP-flanked Brca1 allele occurred in these cells, suggesting that restricted conditional inactivation of Brca1 in granulosa cells is sufficient to induce neoplastic alterations in the epithelial compartment in a cell non-autonomous manner. Recent evidence suggests an additional role for BRCA1 in the regulation of aromatase P450 (CYP19), the enzyme that catalyzes conversion of androgen to estrogen [45]. Results from this study suggest that BRCA1 mutation and loss of heterozygosity may predispose cancer formation in steroidogenic tissues by virtue of loss of DNA damage repair mechanisms in the epithelial cell compartments coupled with growth stimulatory paracrine effects on these cells mediated by enhanced estrogen production in local tissues (i.e., granulosa cells and/or preadipocytes). Other studies suggest that selective inactivation of BRCA1 or p53 in the stroma surrounding tumors plays a direct role in tumor progression in steroidogenic organs [46], [47], [48]. Interestingly, recent work showed that cells exhibiting a senescence associated secretory phenotype (SASP) contribute to epithelial to mesenchymal transitions and invasiveness in a cell non-autonomous manner, with inactivation of p53 being a major contributor to these pro-malignant paracrine activities [49]. It is well-established that genetic and/or epigenetic alterations within the underlying tumor stroma have a direct effect on tumor progression (reviewed in [50]). Hence, it is clear that stromal-epithelial interactions are critical to both normal ovarian tissue function and to epithelial tumor initiation and progression in this hormone responsive organ.

Taken together, previously published studies and our own data suggest that loss of function of BRCA1 and p53 cooperate in their contribution to ovarian tumorigenesis, but that additional molecular or epigenetic alterations within tumor cells and/or stroma as well as cell non-autonomous factors contribute to the development of EOC. Further analyses are required to elucidate the mechanisms of BRCA1-mediated transformation of the ovarian epithelium.

Materials and Methods

Mutant Mouse Strains

All procedures in this study involving mice were approved by the Fox Chase Cancer Center Institutional Animal Care and Use Committee (IACUC). Mice harboring LoxP flanked sequences in Brca1 (FVB;129-Brca1tm2Brn) [16] and p53 (FVB;129-Trp53tm1Brn) [26] were obtained from the Mouse Models of Human Cancer Consortium (MMHCC) Mouse Repository (http://mouse.ncifcrf.gov/, National Cancer Institute, Frederick, MD) and maintained as homozygous colonies expressing the conditional alleles (Brca1LoxP/LoxP and p53LoxP/LoxP). Mice harboring an arginine to histidine substitution at amino acid 172 of p53 (p53515A/515A) [27], a mutation corresponding to the p53 hot spot mutation at Arg 175 in humans [28], [29], [30], were generously provided by Dr. Guillermina Lozano, University of Texas MD Anderson Cancer Center, Houston, TX). Mice harboring conditional (LoxP flanked) alleles of Brca1 or p53 or mutant p53 (Brca1LoxP/LoxP, p53LoxP/LoxP and/or p53515A/515A) were intercrossed to generate colonies with the following compound genotypes: Brca1LoxP/LoxP;p53LoxP/LoxP, Brca1LoxP/LoxP;p53+/515A and Brca1LoxP/LoxP;p53LoxP/515A.

Preparation of Genomic DNA and Genotyping Analysis

Genomic DNA was isolated from tail biopsies by overnight digestion in sodium chloride (NaCl)/Tris EDTA/proteinase K solution at 55°C and ethanol precipitation as previously described [17]. Mice harboring the Brca1LoxP/LoxP allele were genotyped as described [16], [23] using primers flanking introns 4 (Brca1-int4-Fwd-5′-TATCACCACTGAATCTCTACCG -3′ and Brca1-int4-Rev-5′-GACCTCAAACTCTGAGATCCAC-3′) and 13 (Brca1-int13-Fwd-5′-TATTCTTACTTCGTGGCACATC-3′ and Brca1-int13-Rev-5′-TCCATAGCATCTCCTTCTAAAC-3′). The expected sizes of wild type and LoxP flanked Brca1 sequences were 390 nt and 545 nt for intron 4 and 494 nt and 620 nt for intron 13 respectively. Mice harboring the p53LoxP/LoxP allele were genotyped as previously described [26] using primers flanking introns 1 (p53-int1-Fwd-5′-CACAAAAACAGGTTAAACCAG-3′ and p53-int1-Rev-5′-AGCACATAGGAGGCAGAGAC-3′) and 10 (p53-int10-Fwd-5′-AAGGGGTATGAGGGACAAGG-3′ and p53-int10-Rev-5′-GAAGACAGAAAAGGGGAGGG-3′). The expected sizes of wild type and LoxP flanked p53 sequences were 288 nt and 370 nt for intron 1 and 431 nt and 584 nt for intron 10 respectively. Mice harboring mutant p53515A allele(s) were genotyped as previously described [51] using primers PL5-5′-ACCTGTAGCTCCAGCACTGG-3, PL6-5-ACAAGCCGAGTAACGATCAGG-3 and NeoR-5′-CCATTTGTCACGTCCTGCACG-3.

Genomic DNA was isolated from bulk tumor tissue using the same method as described above. Alternatively, microscopic tumors were manually microdissected. Briefly, adjacent H&E stained sections were aligned with unstained paraffin embedded tissue sections to identify the area containing the tumor lesion which was then scraped with needles or scalpel blades as described [52], [53]. The microdissected tissue was then deparaffinized in xylenes and genomic DNA isolated by standard methods for phenol/chloroform/ethanol extraction [52], [53]. Purified genomic DNA was used for PCR amplification and detection of LoxP-flanked and excised Brca1LoxP/LoxP, p53LoxP/LoxP alleles. Cre recombinase-mediated excision of LoxP flanked sequences in Brca1LoxP/LoxP mice results in deletion of exons 5–13 (Brca1Δ5-13) and was detected by PCR amplification of genomic DNA with the Brca1-int4-Fwd and Brca1-int13-Rev primers. Detection of the 594 nt Brca1Δ5-13 PCR product confirmed excision. Similarly, Cre-mediated excision of LoxP flanked sequences in p53LoxP/LoxP mice resulting in deletion of exons 2–10 (p53Δ2-10) was detected by amplification of a 612 nt PCR product from genomic DNA amplified with the p53-int1-Fwd and p53-int10-Rev primers.

Adenovirus Administration

Replication defective recombinant adenoviruses expressing LacZ (Ad5-CMV-ntLacZ) or Cre-recombinase (Ad5-CMV-Cre) were purchased from the Gene Transfer Vector Core, University of Iowa, Iowa City, IA. To demonstrate our capability to successfully perform intrabursal injections, we performed pilot experiments in which 8 week-old female C57Bl/6 mice received intrabursal injections of Ad5-CMV-ntLacZ as previously described [18], [19], [21], [23], [54]. To synchronize ovulation, female mice were injected intraperitoneally (i.p.) with 5 U of pregnant mare serum gonadotropin, followed 48 hours later by i.p. injection with 5 U of human chorionic gonadotropin (hormones purchased from Sigma, St. Louis, MO). In preparation for surgery, mice were anesthetized by intraperitoneal injection of 95 µL per 10 gram body weight of 10 mg/mL Ketamine hydrochloride solution and 1 mg/mL Xylazine hydrochloride 36 hours following the last hormone injection. The ovaries were accessed and exposed through a dorsal incision and each ovary received a single intrabursal injection of approximately 10 µL (5×107 plaque forming units, p.f.u.) of Ad5-CMV-ntLacZ virus by inserting a 32G needle coupled with a Hamilton syringe through the oviduct near the infundibulum into the ovarian bursa.

For Cre-mediated excision of LoxP-flanked Brca1LoxP/LoxP and/or p53LoxP/LoxP alleles, mice received intrabursal injections of Ad5-CMV-Cre-recombinase (5×107 p.f.u.) as described above for Ad5-CMV-ntLacZ. Mice were subjected to bilateral or unilateral intrabursal injection of Ad5-CMV-Cre or unilateral injection of PBS (controls) and monitored daily for wellness for the first ten days post-surgery. Thereafter, mice were monitored at least twice a week for wellness and the development of palpable tumors. Once tumors were detected, mice were monitored daily until euthanasia. Mice were euthanized by CO2 asphyxiation if estimated tumor palpable tumor volume reached 10% of the total body weight or if mice exhibited any signs of loss-of-wellness, as per IACUC guidelines.

Detection of Ad5-CMV-ntLacZ Infection and Ad5-CMV-Cre-Mediated Excision

Mice infected with Ad5-CMV-ntLacZ were euthanized 7 days after intrabursal injection. Ovaries were removed, embedded in OCT medium (Tissue-Tek), snap frozen in liquid N2 and 10 µm sections cut with a cryostat. Sections were fixed for 10 minutes in 0.5% glutaraldehyde, followed by two rinses with PBS+0.1% Tween-20, then stained with X-gal solution (1 mg/mL X-gal (Promega, Madison, WI), 5 mM K3Fe(CN)6, 5 mM K4Fe(CN)6, 1 mM MgCl2 in phosphate-buffered saline (PBS)) at 37°C overnight in a humidified chamber. Sections were rinsed twice in PBS+0.1% Tween-20, counterstained with Nuclear Fast Red, dehydrated with alcohols, cleared in xylenes, and coverslipped using Permount (Fisher).

Tissue restricted Ad5-CMV-Cre infection and Cre-mediated excision of LoxP flanked alleles was confirmed by isolation of genomic DNA from ovary, uterus and liver tissue excised from mice seven days after intrabursal injection of Ad5-CMV-Cre. Tissues were digested in NaCl/Tris EDTA/proteinase K solution at 55°C and genomic DNA isolated as described [17]. A tissue lysate enriched for digested OSE was prepared by limiting the initial digestion time of ovary specimens at 55°C to 30 min. After the first 30 min., the samples were centrifuged briefly at low speed (1000 rpm) to pellet the undigested ovary. The supernatant was collected and genomic DNA was immediately isolated. To continue digestion of the remainder of the ovary, a fresh aliquot of NaCl/Tris-EDTA/proteinase K digestion buffer was added and the sample digested overnight along with other tissue specimens. Genomic DNA was isolated the following day and subjected to PCR amplification with Brca1 intron 4 and intron 13 primers for detection of LoxP flanked and excised sequences as described above.

Preparation and Analysis of Tissues, Histology and Immunohistochemistry

All mice were euthanized by CO2 asphyxiation, necropsied and examined for gross abnormalities. Pathologically altered organs, entire reproductive tracts and representative specimens of multiple organs and tissues, including the brain, lung, liver, kidney, spleen, pancreas and intestine were removed at necropsy, fixed in 10% (v/v) neutral buffered formalin (NBF) overnight, transferred to 70% ethanol and paraffin-embedded. In mice with evident tumor, specimens of the tumor tissue were also excised, snap frozen in liquid N2 and stored at −80°C. For histological analysis, 5 µm formalin fixed paraffin embedded tissue sections were cut for either H&E staining or immunohistochemistry (IHC). Histopathological analysis was performed by a Board Certified Surgical Pathologist with expertise in human and murine gynecological malignancies (LHE).

Sections of tumor tissue for immunohistochemical (IHC) staining were cut on SuperFrost Plus charged slides (Fisher). Antigens (dilution and source of primary antibodies indicated in parenthesis) detected by IHC included: Proliferating nuclear antigen (PCNA, 1:1000; Biogenex), p53 (1:400; Vector Labs), cytokeratin 8 and 19 (CK8, 1:100 and CK19, 1:50; Developmental Studies Hybridoma Bank, The University of Iowa), CD3 (1:100; DAKO), CD45R/B220 (1:200; Pharmingen), α-smooth muscle actin (α-SMA, 1:100; Sigma) and α-inhibin (1:50; Serotec). Unstained sections were deparaffinized, subjected to antigen retrieval and stained as described [17].

Establishment of Ovarian Cancer Cell Lines and Cell Culture

To establish a cell line from an ovarian tumor, approximately 1 cm3 fragments of tumor were excised under aseptic conditions, transferred to a 10 cm2 cell culture dish and finely minced using sterile scalpel blades. Minced tumor tissue was further disaggregated by passing several times through a syringe coupled with a 21½ G needle. The suspension of minced tumor tissue was plated directly in DMEM supplemented with 4% FBS, 1X insulin/transferring/selenium (ITS), penicillin/streptomycin (100 units/mL and 2 mM l-glutamine, and incubated at 37°C in 5% CO2. The culture medium was changed twice weekly until the cells reach confluence at which time they were trypsinized and passaged at 4–5 day intervals.

Array CGH and Karyotype Analysis

For aCGH, high quality genomic DNA (0.5 to 3 µg) was isolated from frozen tumor specimens using standard methods and digested with restriction endonucleases AluI and RsaI according to the Agilent Oligonucleotide Array-based CGH for Genomic DNA Analysis Version 4.0 protocol. The digested genomic DNA was labeled using Agilent Genomic DNA Labeling Kit PLUS. Test and reference DNA samples were labeled with either cyanine 5- or cyanine 3-dUTP, according to the manufacturer's instructions. Cyanine 5- and cyanine 3-labeled DNA products were then purified using Microcon YM-30 (Millipore) filtration devices. The DNA yield and level of dye incorporation were measured using the ND-1000 Spectrophotometer. Appropriate cyanine 5- and cyanine 3-labeled DNA sample pairs were combined and then mixed with mouse Cot-1 DNA, Agilent 10X Blocking Agent, and Agilent 2X Hybridization Buffer. The labeled target solution was hybridized to Agilent 244K Mouse Genome CGH microarray (G4415A) using SureHyb chambers. After hybridization the microarrays were washed and dried according to the procedures described in the manufacturer's protocol. Microarray slides were scanned immediately using an Agilent microarray scanner. Data for individual features on the microarray were extracted from the scan image using Agilent Feature Extraction (FE) Software. Output files from FE were imported into Agilent CGH data analysis software, CGH Analytics for DNA copy number analysis.

A tumor cell line established from a Brca1Δ5-13;p53Δ2-10 ovarian leiomyosarcoma was subjected to karyotype analysis. Preparation of metaphase spreads and trypsin-Giemsa (G) banding were performed according to standard procedures. Chromosome identification and karyotypes designations were in accordance with the University of Washington guidelines (http://www.pathology.washington.edu/rese​arch/cytopages/idiograms/mouse/).

Statistical Analysis

The Kaplan-Meier method was used to construct survival plots for each data set. Comparisons of each of the data sets were made using the Log-Rank test.

Acknowledgments

We would like to thank Drs. Andrew Godwin and Margie Clapper for critical reading of this manuscript and helpful discussions. We thank Dr. Guillermina Lozano, University of Texas MD Anderson Cancer Center, Houston, TX for providing the p53515A/515A mice and gratefully acknowledge the technical support provided by the Laboratory Animal, Research Histopathology and Genomics Facilities at Fox Chase Cancer Center.

Author Contributions

Conceived and designed the experiments: DC. Performed the experiments: BAQ TB XH KBJ DC. Analyzed the data: BAQ TB SL LHE DC. Wrote the paper: DC.

References

  1. 1. Lynch HT, Casey MJ, Snyder CL, Bewtra C, Lynch JF, et al. (2009) Hereditary ovarian carcinoma: heterogeneity, molecular genetics, pathology, and management. Mol Oncol 3: 97–137.
  2. 2. Pal T, Permuth-Wey J, Betts JA, Krischer JP, Fiorica J, et al. (2005) BRCA1 and BRCA2 mutations account for a large proportion of ovarian carcinoma cases. Cancer 104: 2807–2816.
  3. 3. Risch HA, McLaughlin JR, Cole DE, Rosen B, Bradley L, et al. (2001) Prevalence and penetrance of germline BRCA1 and BRCA2 mutations in a population series of 649 women with ovarian cancer. Am J Hum Genet 68: 700–710.
  4. 4. Narod SA, Foulkes WD (2004) BRCA1 and BRCA2: 1994 and beyond. Nat Rev Cancer 4: 665–676.
  5. 5. Venkitaraman AR (2002) Cancer susceptibility and the functions of BRCA1 and BRCA2. Cell 108: 171–182.
  6. 6. Rathi A, Virmani AK, Schorge JO, Elias KJ, Maruyama R, et al. (2002) Methylation profiles of sporadic ovarian tumors and nonmalignant ovaries from high-risk women. Clin Cancer Res 8: 3324–3331.
  7. 7. Hilton JL, Geisler JP, Rathe JA, Hattermann-Zogg MA, DeYoung B, et al. (2002) Inactivation of BRCA1 and BRCA2 in ovarian cancer. J Natl Cancer Inst 94: 1396–1406.
  8. 8. Geisler JP, Hatterman-Zogg MA, Rathe JA, Buller RE (2002) Frequency of BRCA1 dysfunction in ovarian cancer. J Natl Cancer Inst 94: 61–67.
  9. 9. Chan KY, Ozcelik H, Cheung AN, Ngan HY, Khoo US (2002) Epigenetic factors controlling the BRCA1 and BRCA2 genes in sporadic ovarian cancer. Cancer Res 62: 4151–4156.
  10. 10. Signori E, Bagni C, Papa S, Primerano B, Rinaldi M, et al. (2001) A somatic mutation in the 5′UTR of BRCA1 gene in sporadic breast cancer causes down-modulation of translation efficiency. Oncogene 20: 4596–4600.
  11. 11. Buller RE, Lallas TA, Shahin MS, Sood AK, Hatterman-Zogg M, et al. (2001) The p53 mutational spectrum associated with BRCA1 mutant ovarian cancer. Clin Cancer Res 7: 831–838.
  12. 12. Ramus SJ, Bobrow LG, Pharoah PD, Finnigan DS, Fishman A, et al. (1999) Increased frequency of TP53 mutations in BRCA1 and BRCA2 ovarian tumours. Genes Chromosomes Cancer 25: 91–96.
  13. 13. Rhei E, Bogomolniy F, Federici MG, Maresco DL, Offit K, et al. (1998) Molecular genetic characterization of BRCA1- and BRCA2-linked hereditary ovarian cancers. Cancer Res 58: 3193–3196.
  14. 14. Schorge JO, Muto MG, Lee SJ, Huang LW, Welch WR, et al. (2000) BRCA1-related papillary serous carcinoma of the peritoneum has a unique molecular pathogenesis. Cancer Res 60: 1361–1364.
  15. 15. Brodie SG, Xu X, Qiao W, Li WM, Cao L, et al. (2001) Multiple genetic changes are associated with mammary tumorigenesis in Brca1 conditional knockout mice. Oncogene 20: 7514–7523.
  16. 16. Liu X, Holstege H, van der Gulden H, Treur-Mulder M, Zevenhoven J, et al. (2007) Somatic loss of BRCA1 and p53 in mice induces mammary tumors with features of human BRCA1-mutated basal-like breast cancer. Proc Natl Acad Sci U S A 104: 12111–12116.
  17. 17. Connolly DC, Bao R, Nikitin AY, Stephens KC, Poole TW, et al. (2003) Female mice chimeric for expression of the simian virus 40 TAg under control of the MISIIR promoter develop epithelial ovarian cancer. Cancer Res 63: 1389–1397.
  18. 18. Dinulescu DM, Ince TA, Quade BJ, Shafer SA, Crowley D, et al. (2005) Role of K-ras and Pten in the development of mouse models of endometriosis and endometrioid ovarian cancer. Nat Med 11: 63–70.
  19. 19. Flesken-Nikitin A, Choi KC, Eng JP, Shmidt EN, Nikitin AY (2003) Induction of carcinogenesis by concurrent inactivation of p53 and Rb1 in the mouse ovarian surface epithelium. Cancer Res 63: 3459–3463.
  20. 20. Orsulic S, Li Y, Soslow RA, Vitale-Cross LA, Gutkind JS, et al. (2002) Induction of ovarian cancer by defined multiple genetic changes in a mouse model system. Cancer Cell 1: 53–62.
  21. 21. Wu R, Hendrix-Lucas N, Kuick R, Zhai Y, Schwartz DR, et al. (2007) Mouse model of human ovarian endometrioid adenocarcinoma based on somatic defects in the Wnt/beta-catenin and PI3K/Pten signaling pathways. Cancer Cell 11: 321–333.
  22. 22. Chodankar R, Kwang S, Sangiorgi F, Hong H, Yen HY, et al. (2005) Cell-nonautonomous induction of ovarian and uterine serous cystadenomas in mice lacking a functional Brca1 in ovarian granulosa cells. Curr Biol 15: 561–565.
  23. 23. Clark-Knowles KV, Garson K, Jonkers J, Vanderhyden BC (2007) Conditional inactivation of Brca1 in the mouse ovarian surface epithelium results in an increase in preneoplastic changes. Exp Cell Res 313: 133–145.
  24. 24. Xu X, Wagner KU, Larson D, Weaver Z, Li C, et al. (1999) Conditional mutation of Brca1 in mammary epithelial cells results in blunted ductal morphogenesis and tumour formation. Nat Genet 22: 37–43.
  25. 25. Xing D, Orsulic S (2006) A mouse model for the molecular characterization of brca1-associated ovarian carcinoma. Cancer Res 66: 8949–8953.
  26. 26. Jonkers J, Meuwissen R, van der Gulden H, Peterse H, van der Valk M, et al. (2001) Synergistic tumor suppressor activity of BRCA2 and p53 in a conditional mouse model for breast cancer. Nat Genet 29: 418–425.
  27. 27. Lang GA, Iwakuma T, Suh YA, Liu G, Rao VA, et al. (2004) Gain of function of a p53 hot spot mutation in a mouse model of Li-Fraumeni syndrome. Cell 119: 861–872.
  28. 28. Dittmer D, Pati S, Zambetti G, Chu S, Teresky AK, et al. (1993) Gain of function mutations in p53. Nat Genet 4: 42–46.
  29. 29. Hollstein M, Shomer B, Greenblatt M, Soussi T, Hovig E, et al. (1996) Somatic point mutations in the p53 gene of human tumors and cell lines: updated compilation. Nucleic Acids Res 24: 141–146.
  30. 30. Olivier M, Eeles R, Hollstein M, Khan MA, Harris CC, et al. (2002) The IARC TP53 database: new online mutation analysis and recommendations to users. Hum Mutat 19: 607–614.
  31. 31. Sauer B (1998) Inducible gene targeting in mice using the Cre/lox system. Methods 14: 381–392.
  32. 32. Harvey M, McArthur MJ, Montgomery CA Jr, Butel JS, Bradley A, et al. (1993) Spontaneous and carcinogen-induced tumorigenesis in p53-deficient mice. Nat Genet 5: 225–229.
  33. 33. Jacks T, Remington L, Williams BO, Schmitt EM, Halachmi S, et al. (1994) Tumor spectrum analysis in p53-mutant mice. Curr Biol 4: 1–7.
  34. 34. Donehower LA, Harvey M, Slagle BL, McArthur MJ, Montgomery CA Jr (1992) Mice deficient for p53 are developmentally normal but susceptible to spontaneous tumours. Nature 356: 215–221.
  35. 35. Olive KP, Tuveson DA, Ruhe ZC, Yin B, Willis NA, et al. (2004) Mutant p53 gain of function in two mouse models of Li-Fraumeni syndrome. Cell 119: 847–860.
  36. 36. Sood AK, Sorosky JI, Gelder MS, Buller RE, Anderson B, et al. (1998) Primary ovarian sarcoma: analysis of prognostic variables and the role of surgical cytoreduction. Cancer 82: 1731–1737.
  37. 37. Folkins AK, Jarboe EA, Saleemuddin A, Lee Y, Callahan MJ, et al. (2008) A candidate precursor to pelvic serous cancer (p53 signature) and its prevalence in ovaries and fallopian tubes from women with BRCA mutations. Gynecol Oncol 109: 168–173.
  38. 38. Lee Y, Miron A, Drapkin R, Nucci MR, Medeiros F, et al. (2007) A candidate precursor to serous carcinoma that originates in the distal fallopian tube. J Pathol 211: 26–35.
  39. 39. Medeiros F, Muto MG, Lee Y, Elvin JA, Callahan MJ, et al. (2006) The tubal fimbria is a preferred site for early adenocarcinoma in women with familial ovarian cancer syndrome. Am J Surg Pathol 30: 230–236.
  40. 40. Shaw PA, Rouzbahman M, Pizer ES, Pintilie M, Begley H (2009) Candidate serous cancer precursors in fallopian tube epithelium of BRCA1/2 mutation carriers. Mod Pathol.
  41. 41. Semmel DR, Folkins AK, Hirsch MS, Nucci MR, Crum CP (2009) Intercepting early pelvic serous carcinoma by routine pathological examination of the fimbria. Mod Pathol 22: 985–988.
  42. 42. Xing D, Scangas G, Nitta M, He L, Xu X, et al. (2009) A role for BRCA1 in uterine leiomyosarcoma. Cancer Res 69: 8231–8235.
  43. 43. Arias EB, Verhage HG, Jaffe RC (1994) Complementary deoxyribonucleic acid cloning and molecular characterization of an estrogen-dependent human oviductal glycoprotein. Biol Reprod 51: 685–694.
  44. 44. Woo MM, Gilks CB, Verhage HG, Longacre TA, Leung PC, et al. (2004) Oviductal glycoprotein, a new differentiation-based indicator present in early ovarian epithelial neoplasia and cortical inclusion cysts. Gynecol Oncol 93: 315–319.
  45. 45. Hu Y, Ghosh S, Amleh A, Yue W, Lu Y, et al. (2005) Modulation of aromatase expression by BRCA1: a possible link to tissue-specific tumor suppression. Oncogene 24: 8343–8348.
  46. 46. Hill R, Song Y, Cardiff RD, Van Dyke T (2005) Selective evolution of stromal mesenchyme with p53 loss in response to epithelial tumorigenesis. Cell 123: 1001–1011.
  47. 47. Patocs A, Zhang L, Xu Y, Weber F, Caldes T, et al. (2007) Breast-cancer stromal cells with TP53 mutations and nodal metastases. N Engl J Med 357: 2543–2551.
  48. 48. Weber F, Shen L, Fukino K, Patocs A, Mutter GL, et al. (2006) Total-genome analysis of BRCA1/2-related invasive carcinomas of the breast identifies tumor stroma as potential landscaper for neoplastic initiation. Am J Hum Genet 78: 961–972.
  49. 49. Coppe JP, Patil CK, Rodier F, Sun Y, Munoz DP, et al. (2008) Senescence-associated secretory phenotypes reveal cell-nonautonomous functions of oncogenic RAS and the p53 tumor suppressor. PLoS Biol 6: 2853–2868.
  50. 50. Beacham DA, Cukierman E (2005) Stromagenesis: the changing face of fibroblastic microenvironments during tumor progression. Semin Cancer Biol 15: 329–341.
  51. 51. Liu G, Parant JM, Lang G, Chau P, Chavez-Reyes A, et al. (2004) Chromosome stability, in the absence of apoptosis, is critical for suppression of tumorigenesis in Trp53 mutant mice. Nat Genet 36: 63–68.
  52. 52. Connolly DC, Katabuchi H, Cliby WA, Cho KR (2000) Somatic mutations in the STK11/LKB1 gene are uncommon in rare gynecological tumor types associated with Peutz-Jegher's syndrome. Am J Pathol 156: 339–345.
  53. 53. Tashiro H, Isacson C, Levine R, Kurman RJ, Cho KR, et al. (1997) p53 gene mutations are common in uterine serous carcinoma and occur early in their pathogenesis. Am J Pathol 150: 177–185.
  54. 54. Connolly DC, Hensley HH (2009) Xenograft and Transgenic Mouse Models of Epithelial Ovarian Cancer and Non-Invasive Imaging Modalities to Monitor Ovarian Tumor Growth In Situ: Applications in Evaluating Novel Therapeutic Agents. pp. 14.12.11–14.12.36. Current Protoc Pharmacol John Wiley & Sons, Inc.