Plant Material and Growth Conditions

The maize inbred lines UH002, UH005, UH250 and UH301 as well as their 12 hybrid combinations were generated in the nursery of the University of Hohenheim in the summer season of 2003. Seeds were surface sterilized, thoroughly rinsed in twice distilled water, transferred on moistened filter paper (193×290 mm Grade 603 N, Munktell&Filtrak, Bärenstein, Germany) which was rolled up with 10 seeds of a genotype per filter paper and germinated in a phytochamber (Versatile Environmental Test Chamber, MLR-350, Sanyo, Japan) at 26°C, with a 16 h light and 8 h dark cycle [20]. For further analyses, the 3.5-day-old roots were excised with a razor blade, the roots growing on the same filter paper were pooled, weighted, snap frozen in liquid nitrogen and stored at −70°C. This procedure was repeated six times per genotype leading to six biological replicates. Altogether six times ten kernels of 12 hybrid and 4 inbred genotypes were in randomized order independently germinated and harvested. For each sample the average biomass (fresh weight of 10 pooled primary roots) was calculated, these values represent the primary root biomass in the very early stage of maize seedling development. Frozen samples were randomly grinded in 2.0 ml round bottom micro-vials (Eppendorf, Germany) with prewashed 0.25 inch steel balls in a mixer mill (Retsch, Haan, Germany). Per sample 100 mg of frozen homogenized pooled root material was subjected to subsequent sample extraction.

Root material was preferred over analyzing kernels to account for heterosis effects during seed formation (accumulation of storage compounds) as well as seedling establishment (storage compound utilization and environmental influences).

Metabolomics Analyses and Data Normalization

A targeted analysis [27] evaluating the levels of 112 distinct metabolites was conducted for six biological replicates of each individual genotype following the procedure outlined in [28] and modified as described in [29] with respect to the extraction mixture (MeOH:MTBE:H₂O instead of MeOH:CHCl₃:H₂O). The 112 metabolites are a subset of the extractable polar fraction of metabolites which are accessible by gas-chromatography-mass spectrometry (GC-MS) and where selected after manual inspection of several chromatograms. Sixty nine metabolites were identified by comparison with the Golm Metabolome Database [30] as a reference based on Retention Index and spectra similarity. For 19 of the remaining 43 unidentified metabolites we could assign a putative chemical class (aa: amino acid, acid: organic acid, cho: sugar, chop: sugar phosphate) according to selective masses from the spectra. All samples were measured in completely randomized order in three consecutive batches (measurement days).

Metabolite intensities were log₁₀-transformed to better resemble a normal distribution. A two-way analysis of variance (ANOVA) was applied using genotype and sample batch as factors. Systematic differences due to the latter factor were thus removed. Values with studentized residues larger than four were eliminated. In a further normalization step, we corrected for differences in metabolite levels due to variation in initial sample amount. Here, we calculated a correction factor for each sample as the ratio of its median peak height (i.e. metabolite level) and the median peak height for all replicates of the similar genotype. By dividing each sample with its correction factor, we scaled biological replicates to a similar median peak size.

Notation

Let be the set of parental genotypes with , and denote a member of , i.e., . A hybrid genotype is denoted by , where In total, there are 12 different hybrid and 4 different parental genotypes.

Let denote the cardinality of a given set .

Let denote the number of available replicates for each measurement. The matrix gathers the profiles of metabolites from parents and replicates, thus, . The matrix will be referred to as the data matrix of parental metabolic profiles. Analogously, the data matrix gathers the hybrid metabolic profiles, where . Columns of and , corresponding to metabolites, are mean-centered and scaled to unit variance.

Let denote the row of a matrix , and its column.

We next construct an matrix where each row represents a hybrid as a concatenation of two parental profiles also mean-centered and scaled to unit variance.

Notation regarding replicates is suppressed and it is always implied that a group of replicates is meant when a genotype is discussed, unless otherwise stated.

Problem Setting

Every can be represented on 4 levels:

• A: the labels g₁ and g₂ of its parents
• B: the combined metabolic profiles of both of its parents
• C: its own metabolic profiles
• D: its biomass.

In practical terms (e.g., a breeding program), it is desirable to predict macroscopic quantities such as D given an easily obtainable quantity describing its parents. Efforts have been made for decades to predict D given A by using linear models, culminating in the Bayesian formulation found in [7].

A black-box approach would be to predict D given B, however, level C is skipped which potentially has predictive information. Levels B and C could also stand for other types of molecular data, such as transcript or protein levels. Additionally, there would be the need to select features of B to gain biological insight or develop a small number of predictive biomarkers for use.

Here, we aim to predict C given B. In general, it is hard to predict one profile given another, hence we apply the following simplification: if is the matrix of profiles corresponding to C, and corresponds to B, we predict given for each . The trade-off of this simplification is that the individual metabolites in the hybrid profiles are treated as if they are independent of each other, which is clearly not true for each metabolite.

The output of the parallel prediction problems ( given ) is aggregated and some parental metabolites (labelled as either maternal or paternal) show an overall higher predictive power of than others. Therefore, we use this as a biologically-motivated feature-selection method and find that these parental metabolites are also predictive of biomass, i.e., allow to predict D given B.

Problem Formulation

A new matrix is first constructed, quantitatively capturing the concept of additivity and dominance, by comparing the levels of each metabolite in to those in the respective parents. As a result, hybrid metabolite levels are expressed relative to the corresponding parental levels and not to a common reference (zero). This captures the genetic constraints imposed by the parents, and is achieved by using moderated t-statistic [31], as detailed below.

For every metabolite and every hybrid , we consider the following two null hypotheses for i = 1 (maternal) and i = 2 (paternal):

Because for each , there is a multiple testing situation, moderated t-statistics are calculated over for each .

Using this approach, each metabolite within each hybrid is given a label specified by:

where, for succinctness, the notation for expectation is neglected for all and ±2 corresponds to positive/negative overdominance, ±1 corresponds to positive/negative dominance and 0 corresponds to additivity, respectively. Therefore, in the alternative formulation, the problem is that of classifying the parental matrix according to:where is a classifier to estimate given the parental matrix as input.

Let denote the number of genotypes with the corresponding class label in metabolite . Hybrid metabolites are then filtered so that only those with reasonably balanced classes are predicted by assigning each hybrid metabolite a weight where:

such that

such that and , otherwise. For two of the remaining metabolites where , such that , we removed only the rows of the corresponding genotype.

In a classification problem, given a data set of points, belonging to one of at least two classes, it is required to determine a function of the features, specifying the points, to infer the class labels. Depending on the properties and constraints the function should satisfy, there are several approaches available, and a thorough overview can be found in [32]. Here, the class labels are given by the CLR, and the features are the parental metabolites. To infer the class labels, we employ five classification methods: support vector machines (SVM) VAPNIK, linear discriminant analysis (LDA) [32], random forests (RF) [33], RF preceded by a partial-least-squares dimension reduction step (PLS-RF) [34] and LDA preceded by a partial-least-squares dimension reduction step (PLS-LDA) [34]. Selecting a classification method (: SVM, LDA, PLS-LDA, PLS-RF, RF) for a problem based on lowest class error rate of an individual method can give an 'optimistic bias' [35]. Therefore, we used the following strategy to obtain those metabolites which are well classified regardless of the classification method employed (available from the Bioconductor package CMA [36]):

For each with :

1. Construct a new , after permuting the rows and , corresponding to each .
2. Split into 3 groups of samples for 3-fold cross validation (sampling balanced across classes)
3. Construct the classifier 3 times using each group once as the test set, and apply different classification methods to estimate either the observed labels or a permuted version thereof.
4. Report the median misclassification rate for method and for and respectively.
5. Repeat steps one to four 25 times.
6. For each method, report the median misclassification rate over the 25 replicates. Select the two methods with in both .
7. Define , where and denote the first and third quartiles, respectively, of 25 median errors . First and 3rd quartiles are used to be stricter than comparing medians.

If , then is considered to be predictable using . For these metabolites, it is now desired to select the features of which are most predictive of . To do so, ranked feature weights of SVM is used (regardless of performance compared to other methods, as this remains unknown), i.e., for each , there is a -vector of parental metabolite feature weight ranks , where and indexes the parental metabolites. Ranks are used to avoid the problem of feature weights being on different scales for each , and to avoid the problem of threshold selection.

To summarize the combined performance of all hybrid metabolite classifiers, the parental metabolites are ranked based on the median of , i.e., their importance in predicting each . Parental metabolites with a low are often important in predicting and conversely metabolites with a high median, are not very often important in predicting .

Validation of Selected Parental Metabolites Using Hybrid Fresh Weight

To test if the informative parental metabolites, which are low ranked in hybrid metabolite prediction, are also predictive of biomass (), we form a final ranking for parental metabolites .

We form a biomass predictor using support vector regression on 60% of the samples as a training set and measuring performance calculating the Pearson correlation between the predicted () and actual biomass values.

To determine the subset of columns (metabolites) of selected we define as being 5 randomly selected metabolites out of those with , and , and with and . This is compared to for with the values block permuted, i.e. biological replicates for each remain together. For each , is constructed 500 times, each time with rows randomly assigned in and , as well as replicates also being randomly assigned.

A schematic representation of our analysis pipeline can be found in Figure S6.

Description of the Experimental Setup and Conceptual Framework

We used four European parents, two of each from the flint (UH002 and UH005) and the dent (UH250 and UH301) pool, and all their reciprocal hybrids. The full experimental design is displayed in Figure S1 B and was also previously described [24].

Based on our earlier observation that biomass was correlated to the deviation from a set of optimal metabolic levels, we concluded that in order to complete a targeted breeding approach, it is crucial to establish the link between parental and hybrid profiles. While it is easy to select promising parental lines () and measure their metabolic profiles (), we set out to devise a method to infer from the hybrid profile (), or a derived version () thereof, retaining sufficient information to predict hybrid biomass () ultimately based on parental traits alone (Figure S1 A, Materials and Methods).

As metabolism is sensitive to changing environmental conditions [37], our experiment was designed to keep environmental influences at minimum. Therefore, we performed our study on the germinating root system in maize, where heterosis was previously shown to occur in a highly controlled setup [20]. Six biological replicate samples, each containing 10 pooled roots, were analyzed by gas-chromatography time-of-flight mass-spectrometry (GC-TOF-MS) to obtain the metabolic profiles comprising the levels of 112 metabolites [24].

We initially tested if biomass can be predicted based solely on knowledge of the parental genotype and biomass, utilizing a Bayesian framework [7] to estimate the posterior densities of the inherent effects. However, hybrid outcome is essentially arbitrary in the absence of further information, and there is no power for further generalization (e.g., parent X improves hybrid biomass independent of the other parental genotype). Therefore, to gain a deeper insight, we next investigated the connections between parental and hybrid metabolite profiles and average root´s biomass.

Re-encoding the Hybrid Metabolite Profiles According to Individual Heterosis Mode of Action

Hybrid metabolic levels depend on parental levels, albeit in an unknown way. To investigate the connection, we do not work with absolute hybrid metabolic levels but rather we transformed them to relative values with respect to the corresponding parents. However, here each hybrid metabolite is compared to two separate quantities, namely the corresponding maternal and paternal metabolite levels, and a decision must be made on how to combine the parental levels. Representing the parental levels by the mean may not suffice, because the separation between the parental levels is lost and this is essential information about the diallel structure. Instead, we define the Combined Relative Level (CRL) by applying the concept of additivity/dominance/over-dominance to each metabolite. If the hybrid level is significantly greater/smaller than both respective parental levels, then CRL is +/−2. If it is significantly greater/small than just one parent, CRL is +/−1. When it is indistinguishable from both parents or greater than one and smaller than the other, CRL is 0 (cf. Methods). While information about the diallel is retained through the consideration of the separation of each parental combination in the calculation of the CRL, it is evident that the magnitude of the hybrid shift is lost.

Our aim was to examine whether certain regions of parental metabolite space favor certain shift directions, as a consequence of common genetic and biochemical constraints. However, while we did the classification individually per metabolite, hybrid metabolite levels are likely to be the outcome of complex combinatorial patterns of multiple parental metabolites levels [38]. The corresponding parental metabolite levels of metabolite may even be less influential for the hybrid outcome of than the parental levels of metabolites and , which potentially allows the prediction of hybrid outcome based on a reduced set of parental metabolite levels.

Predicting the Hybrid Class Label Profile

We asked for every hybrid metabolite which of the parental metabolites is predictive of the hybrid class labels based on their levels. The parental input matrix is constructed as a concatenation of maternal (m) and paternal (p) profiles (cf. Methods) and, therefore, contains every metabolite twice (e.g. alanine_m and alanine_p).

Before classification, hybrid metabolites which show the same class label at least nine times (out of 12 combinations) were removed. This is necessary to avoid an overly unbalanced set of class labels, narrowing down the profiles to 69 metabolites (Figure 1). The threshold of nine was chosen based on a visual inspection of class label balance distribution. We then tested several classification methods (support vector machines (SVM), linear discriminant analysis (LDA), random forests (RF) and combinations of partial least squares (PLS) with the previous: PLS-LDA and PLS-RF, cf. Methods for details) which are ideally evaluated against an independent test data set to avoid choosing the ‘best’ method. Because such a test data set is currently not available, we compared our results to classification with permuted class labels using 3-fold cross-validation on both permuted and original datasets, each time with 25 replicates. For the 54 metabolites where the minimum original median error from one of the classification methods was lower than the minimum permuted median error we considered parental profiles to have predictive power for the hybrid class label. The median miss-classification frequency for the SVM method, which often has a low CV error, is shown in Figure S2.

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Figure 1. Hybrid class label matrix.

The hybrid class label matrix is established using moderated t-statistics (cf. Methods). It shows the observed metabolite heterosis mode of action in all hybrids. Metabolites with unbalanced class labels (e.g. predominantly showing similar class, upper 53 rows) were excluded before conducting classification methods. Various classification methods were used on parental metabolite data to investigate which parental metabolites allow to predict the observed classes within hybrids.

https://doi.org/10.1371/journal.pone.0085435.g001

Identifying the most Influential Parental Metabolites

The next question to address was which parent metabolites are influential in the prediction of hybrid class labels which requires a feature selection procedure. As SVM performs well overall, we decided to use the embedded feature selection method, i.e., recursive feature selection. However, the feature weights appeared to be on different scales for each hybrid metabolite, and, furthermore, there was the additional problem of choosing an appropriate feature weight threshold. To circumvent these challenges, the feature weight rankings were used, where a low rank corresponds to high feature weight or variable importance. The median ranks over all 54 hybrid metabolite class label predictions were scaled between 0 and 1, allowing the identification of parental metabolites with global importance, rather than individually choosing and interpreting a set of features for each metabolite. The rank distribution within each feature (parental metabolite) over all predicted hybrid metabolites is shown in Figure 2, where metabolites are sorted by their median rank.

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Figure 2. Ranking of the parental features.

Parental metabolite levels (224 features in total) are used to predict the observed class labels of 54 hybrid metabolites. In each prediction model all features can be ranked according to their weights. The ranks are scaled between 0 and 1 by dividing by the total feature number. The scaled median rank distribution of a feature, i.e. the individual boxes in the plot, then gives an estimate regarding the importance of the absolute parental level of the respective metabolite on the heterosis pattern of all hybrid metabolites.

https://doi.org/10.1371/journal.pone.0085435.g002

It can be seen that features with low median rank are also highly skewed to the left, meaning they are low ranked more often than high ranked. At the other end, there are features which are never of low rank. This implies that there is a set of parental metabolites which may be implicated in the outcome of the discretized hybrid metabolite profiles (CLR), i.e. they are informative not only for the hybrid heterosis mode of action for the respective metabolite itself but for several up to many metabolites.

To assess how robust our feature ranking would be if not all genotypes are included in the modeling step we performed a leave-one-out (LOO) approach excluding all replicates of a specific hybrid. This is important for a later application in breeding where we would like to make predictions on hybrid traits based on their parental properties without measuring the hybrid itself. While it is obvious that a LOO strategy is less strict compared to an independent test set, we found the feature ranking to be very stable (Figure S3).

Predicting Hybrid Root’s Biomass from Parental Metabolite Profiles

We have been able to predict the CRL class labels of each hybrid metabolite individually given the parental profiles, and some parental metabolites are overall more influential than others. Furthermore, this ranking does not appear to be dominated by any genotype in particular, given that the feature ranking is stable using a LOO approach.

It would be of practical use to predict the biomass of primary roots in the progeny given parental profiles, and thus we now investigate whether the feature ranking can also be used for feature selection. We predict the biomass given the parental profiles using support vector regression (SVR), and as a baseline, we use all metabolites, with prediction quality measured by correlation between actual and predicted biomass values (Figure 3, Box L). Comparing the prediction quality to that of permuted biomass values, the parental profiles are indeed predictive of average fresh weight (Figure 3, Box M).

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Figure 3. Prediction evaluation.

The correlation between observed and predicted HP in models incorporating 5 metabolites. The metabolites have been selected based on a previous ranking (cf. Figure 2). It can be seen that good prediction accuracies are only obtained for high ranked metabolites and not for low ranked metabolites, which perform comparable to permuted data sets. Metabolite input matrices X_pp were established as described in Methods.

https://doi.org/10.1371/journal.pone.0085435.g003

We would like to know whether all features are necessary for prediction, or whether a small number of features may achieve comparable predictive power. We find that using only the top 5 ranked features in the SVR gives comparable results to using all features (Figure 3, Box A). We would like to know how many of the top ranked features are equally good predictors. To this end, we randomly select 5 out of the top 10, 20 and 50. The top 5, 10 and 20 features have comparable prediction quality (Figure 3, Box B and C), and there is a decrease in prediction quality by using the top 50 (Figure 3, Box D). Note that the number of features used in the SVR remains fixed at 5, as a higher number of features was found to improve prediction quality for the top 10 and top 20. Furthermore, prediction quality progressively decreases as more bottom ranked metabolites are included in the SVR (Figure 3, Boxes E, F and G).

The results of the top 5 and random 5 can be compared to predictions of permuted biomass (Figure 3, Boxes H and I), and the top 5 features are also predictive of biomass, while it is not true in general that randomly selected features are predictive. Note that even predictions on permuted biomass gives results which are better than random (median correlation is greater than 0). As expected, prediction is truly random when the correlation structure of the parental profiles is destroyed by permuting the cells of the parental profile matrix (Figure 3, Boxes J and K). Thus, the feature ranking found by predicting hybrid CRL class labels is of direct relevance to the prediction of average fresh weight.