- Open Access
Population genetic variation in gene expression is associated with phenotypic variation in Saccharomyces cerevisiae
© Fay et al. 2004
- Received: 28 January 2004
- Accepted: 27 February 2004
- Published: 24 March 2004
The relationship between genetic variation in gene expression and phenotypic variation observable in nature is not well understood. Identifying how many phenotypes are associated with differences in gene expression and how many gene-expression differences are associated with a phenotype is important to understanding the molecular basis and evolution of complex traits.
We compared levels of gene expression among nine natural isolates of Saccharomyces cerevisiae grown either in the presence or absence of copper sulfate. Of the nine strains, two show a reduced growth rate and two others are rust colored in the presence of copper sulfate. We identified 633 genes that show significant differences in expression among strains. Of these genes, 20 were correlated with resistance to copper sulfate and 24 were correlated with rust coloration. The function of these genes in combination with their expression pattern suggests the presence of both correlative and causative expression differences. But the majority of differentially expressed genes were not correlated with either phenotype and showed the same expression pattern both in the presence and absence of copper sulfate. To determine whether these expression differences may contribute to phenotypic variation under other environmental conditions, we examined one phenotype, freeze tolerance, predicted by the differential expression of the aquaporin gene AQY2. We found freeze tolerance is associated with the expression of AQY2.
Gene expression differences provide substantial insight into the molecular basis of naturally occurring traits and can be used to predict environment dependent phenotypic variation.
- Additional Data File
- Hydrogen Sulfide
- Expression Difference
- Freeze Tolerance
- Synonymous Substitution
An important question concerning the genetic basis and evolution of complex traits is the relative contribution of gene regulation versus protein structure. If gene-expression differences make a substantial contribution to phenotypic variation found in nature, the genetic basis of complex traits may be more readily understood through the analysis of gene expression . Furthermore, it would imply that most evolutionary changes occur through changes in either patterns or levels of gene expression [2, 3].
Genome expression studies have shown numerous differences in transcript abundance both within and between closely related species [4–12]. In some instances, genetic variation in gene expression has been associated with phenotypic variation [1, 5, 10, 13–16]. However, gene expression differences correlated with a phenotype may or may not contribute to the phenotype. Distinguishing between these possibilities requires locating the genes responsible for the trait [1, 14–16].
To further investigate the relationship between genetic variation in gene expression and phenotypic variation, we measured genome-wide mRNA transcript levels in nine strains of Saccharomyces cerevisiae which vary in their sensitivity to copper sulfate (CuSO4), a strong oxidizing agent often used as an antimicrobial agent in vineyards [17, 18].
Natural isolates of Saccharomyces cerevisiae vary in their sensitivity to copper sulfate
Identification of gene expression differences in the presence and absence of copper sulfate
Expression levels were measured using DNA microarrays in the nine strains during exponential growth in rich medium and in rich medium supplemented with copper sulfate (see Materials and methods). The microarrays used in this study are composed of oligonucleotides of 70 base pairs (bp) that are perfect matches to the S288C sequence. Although cDNA prepared from the other eight strains will not always be a perfect match to the sequence on the microarray, we expect fewer than 0.2 differences per 70 bp on average (see Materials and methods), and therefore do not expect the sequence differences to affect our measurements. A reference design was used whereby the RNA of each strain grown in rich medium and rich medium supplemented with copper sulfate was compared to the pooled RNA from all nine strains grown in rich medium and copper sulfate medium, respectively. Using three replicate experiments, four statistical tests were used to identify differentially expressed genes. From an analysis of variance, 194 genes showed significant expression differences among strains grown in copper sulfate medium, 241 genes showed significant expression differences among strains grown in rich medium, and 516 genes showed significant expression differences across both conditions (p < 0.01). One hundred and thirty-one genes showed significant differences between the rich medium and copper sulfate medium reference pools (t-test, p < 0.01). Because an analysis of variance assumes errors are independent and identically distributed, we estimated the rate of false positives using a nonparametric permutation resampling method (see Materials and methods). The estimated number of false positives was 57, 64, 55 and 71, for the test of gene-expression differences among strains in copper sulfate medium, in rich medium, in both media, and between the two reference pools, respectively. We chose a p-value cutoff of 0.01, as empirically, many significant genes are missed using a p-value cutoff of 0.001 and numerous false positives are generated using a p-value cutoff of 0.05 (see Materials and methods).
Differentially expressed genes correlated with growth rate in the presence of copper sulfate function in response to oxidative stress
Genes expressed at higher levels in copper-sensitive (M34 and YPS163) compared to resistant strains are known to function in response to oxidative stress. At high concentrations, copper causes oxidative stress resulting in lipid peroxidation, aggregation and fragmentation of proteins and DNA damage . Thioredoxin peroxidase (TSA1) and thioredoxin (TRX2) function in redox homeostasis and are regulated by the transcription factors Yap1p and Skn7p [23, 24]. The heat-shock proteins encoded by SSA1 and HSP82 are also regulated by Yap1p and Skn7p and function in protein folding and translocation of misfolded proteins . Sti1p is a member of the Hsp82 protein complex . Kar2p interacts with Ire1p  to activate the unfolded protein response, including protein disulfide isomerase, PDI1 , which is required for oxidative protein folding in the endoplasmic reticulum . These genes, in addition to functioning in oxidative stress and protein folding, had higher levels of expression in the copper sulfate compared to rich medium reference pool (Figure 4a).
Genes expressed at lower levels in strains sensitive to copper sulfate were expressed at lower levels in the copper sulfate compared to the rich medium reference pool and function in RNA processing. RFX1 encodes a repressor of RNA polymerase II (Pol II) promoters . ENP1 encodes a small nucleolar RNA-binding protein involved in rRNA processing . In addition, both YJL010C and YLL034C show changes in gene expression similar to other RNA-processing genes , which together form a major component of the environmental stress response . The expression of RNA-processing genes may be related to a general stress response and/or the reduced growth rate of copper-sulfate-sensitive strains.
Of those genes found to change in response to copper sulfate (Figure 5), the genes expressed at lower levels in the presence of copper sulfate are not functionally related, and the genes expressed at higher levels in the presence of copper sulfate are significantly enriched in genes known to function in protein folding, stress response and metabolism (see Materials and methods). Of the 131 genes, 24 were expressed at twofold or higher levels in the presence of copper sulfate and one, ZRT1, encoding a high-affinity zinc transporter, was expressed at half the level in the presence of copper sulfate. Of these 24 genes, seven are known to function in the stress response (ALD3, DDR2, HSP12, HSP104, TSL1, YGP1, YRO2), four in protein folding (SSA1, SSA2, SSA4, SIS1), four in metabolism (ALD4, GLK1, HXK1, PGM2), five in copper homeostasis (CUP1-1, CUP1-2, FET3, FTR1, SOD1), two are uncharacterized (YHR087W, YMR315W), one encodes a lipid-binding protein (TFS1), and one gene is involved in meiotic sister-chromatid recombination (MSC1).
Of those genes expressed at higher levels in the presence of copper sulfate, many are also expressed at higher levels in YPS163 and M34 (Figure 5). However, the response differs among the copper-sulfate-resistant strains. The expression pattern in the copper-resistant strains delineates two major clusters enriched for genes known to function in protein folding (Figure 5, red bars) and stress response and metabolism (Figure 5, blue bars). The group enriched for genes functioning in protein folding tends to be expressed at higher levels in YPS163, M34 and, to some extent, M5. Whereas M5 is resistant to copper in rich medium, it is quite sensitive in SD or SC medium (see Additional data file 1). One of the genes expressed at higher levels in M5, YPS163 and M34 is SIS1, encoding an HSP40 family chaperone required for the initiation of translation , and known to regulate the protein-folding activity of the heat-shock protein Ssa1p . The group enriched for genes functioning in the stress response and carbohydrate metabolism tends to be expressed at higher levels in the two copper-sensitive strains, YPS163 and M34, but also tends to be expressed in S288C and M32, two of the three most resistant strains.
Differentially expressed genes correlated with rust coloration function in the sulfur assimilation/methionine pathway
A candidate phenotype, freeze tolerance, is associated with the differential expression of the aquaporin gene AQY2
Genes that respond to the presence of copper sulfate show no correlation with sequence divergence between strains
We have examined the association between gene-expression differences and two copper-sulfate-related phenotypes. Whereas the function of these genes implies that they are not casually associated with the trait, the gene-expression differences may be a response to the phenotype (correlative) or may cause the phenotype (causative). Distinguishing between these possibilities is important to understanding the molecular basis and evolution of complex traits and why transcriptional variation is present in natural populations.
Resistance to copper sulfate
Resistance to high levels of copper ions is mediate through the copper-binding transcription factor ACE1, which induces the metallothionein gene CUP1 , the metallothionein-like gene CRS5  and the copper, zinc superoxide dismutase gene, SOD1 . A global analysis of gene expression in response to copper sulfate using DNA microarrays identified FET3 and FTR1, encoding two high-affinity iron transporters and FIT2, encoding another iron transporter, as being induced in the presence of copper along with the previously characterized induction of CUP1, SOD1 and CRS5 . Consistent with these studies, we found that CUP1, SOD1, FET3 and FTR1 were expressed at higher levels in the presence of 1 mM copper sulfate medium compared to rich medium (Figures 4, 5). In addition to these four genes, we found another 127 genes expressed at significantly different levels in the presence of copper sulfate, 20 of which showed a twofold or greater level of expression in the presence of copper sulfate and one, ZRT1, encoding a high-affinity zinc transporter, which showed a 50% lower expression level in the presence of copper sulfate (Figure 5). Our study differed from previous studies because we measured expression 180 minutes subsequent to copper treatment in rich medium for three replicate experiments, whereas the other studies measured gene expression 30 minutes subsequent to copper treatment in synthetic complete medium.
Different levels of copper resistance among strains of S. cerevisiae have been attributed to variation in the number of tandem copies of the CUP1 locus [19, 20] and could be due to use of copper sulfate in vineyards as a fungicide against powdery mildew since the 1880s . We have found an incomplete association between CUP1 expression and resistance to copper sulfate. In the presence of copper sulfate, CUP1 was expressed at higher levels in strains M14, M22 and M8. These strains are resistant to 5 mM copper sulfate (Figure 1), but so are M5, M32 and S288C. CUP1 was expressed at the lowest levels in M13, S288C, YPS163 and M34, and while M13, YPS163 and M34 are the most copper-sensitive strains (Figure 1), S288C is one of the most resistant. Because previous studies examined resistance to copper sulfate on synthetic complete (SC) medium, we examined growth on SC medium with 0.1 mM copper sulfate. Only M8, M13, M32 and M34 grew on synthetic minimal (SD) medium or SC medium supplemented with 0.1 mM copper sulfate (see Additional data file 1). S288C did not grow on either SD or SC medium in the absence of copper sulfate, and M14 and M22 grew weakly in its absence. Thus, YPS163 and M5 are the most sensitive to copper sulfate in SD or SC medium, in contrast to rich medium. Genetic studies will be needed to determine whether resistance to copper sulfate is mediated by loci other than the CUP1 locus and whether the different transcriptional responses among strains contribute to resistance in the presence of copper sulfate in rich medium or in other growth or environmental conditions.
Genes tightly correlated with sensitivity to copper sulfate (Figure 4a) are likely to be correlated characters and do not contribute to levels of resistance. The oxidative stress response involves numerous genes, many of which were found differentially expressed between strains (Figure 4). However, if genes that respond to oxidative stress were protecting resistant but not sensitive strains, we would expect them to be expressed at higher levels in the resistant rather than the sensitive strains. The opposite is observed. Thus, it appears that many of the genes tightly associated with sensitivity to copper sulfate are likely to be differentially expressed as part of a coordinated response to a toxic cellular environment. Ultimately, the genetic basis of resistance to copper sulfate must be mapped to identify any expression differences that contribute to resistance.
Previous studies of other rust-colored strains using electron microscopy  and treatment with potassium cyanide  have suggested that the rust color produced in the presence of copper sulfate is due to the formation of copper sulfide (CuS) mineral lattices on cell surfaces. The two rust-colored strains, M14 and M22, often produced a distinct smell of hydrogen sulfide (H2S) during fermentation in both the presence and absence of copper sulfate. Hydrogen sulfide production in M14 and M22 may be attributed to the conversion of hydrogen sulfite to hydrogen sulfide by sulfite reductase, Met10p/Ecm17p , proteins that are expressed at higher levels in both M14 and M22. The rust coloration may be due to the formation of copper sulfide as a consequence of hydrogen sulfide production. Hydrogen sulfide is often produced during wine fermentation , and, because of the resulting undesirable flavors, may be a trait that has been selected against in yeast strains used for wine production. In addition, copper sulfate is often used to remove unwanted sulfides, including hydrogen sulfide, produced during wine production. Segregants from a heterozygous Italian strain were found to co-segregate differential expression of the sulfur-assimilation/methionine metabolism pathway with a filigreed colony morphology produced during starvation . However, neither M14 nor M22 showed the filigreed phenotype at any time during starvation.
The differential expression of the sulfur-assimilation pathway may be responsible for the rust coloration phenotype as the differential expression of the pathway is not due to the presence of copper sulfate. The production of hydrogen sulfide, the differential expression of sulfur-assimilation genes in the absence of copper sulfate and the absence of a response by the sulfur-assimilation genes to the presence of copper sulfate (Figure 6), suggest that the expression of the sulfur-assimilation pathway is not due to the presence of copper sulfate.
The lack of any obvious phenotype associated with the genes differentially expressed in rich medium suggests that many expression differences may only be associated with phenotypic variation under certain environmental conditions, or may not be associated with any phenotype at all. Because most expression differences persist in the presence and absence of copper sulfate, they may persist under different environmental conditions and may be associated with phenotypic variation under those conditions. This is the case for the sulfur-assimilation/methionine pathway, which is associated with rust coloration only in the presence of copper sulfate. This is also the case for the expression of the aquaporin gene, AQY2, which was used to predict phenotype variation among strains subsequent to a freeze-thaw cycle. Our ability to predict phenotype from expression data is not unique. The expression of arsenic-resistance genes was used to correctly predict sensitivity to arsenic among four natural isolates of S. cerevisiae . Gene-expression patterns from tumors have been found to predict clinical outcome, for example . Thus, the molecular phenotypes revealed by gene-expression patterns may provide valuable insights into the molecular genetic basis of complex traits, especially those that are environment dependent.
Rate of divergence in gene expression
Most expression differences were not associated with either resistance to copper sulfate or rust coloration in the presence of copper sulfate. The differential expression of these genes could be due to a lack of selective constraint on their expression levels or could be due to some form of natural selection. For instance, they may be the result of a balance between mutation and purifying selection or could be a result of diversifying selection mediated by environmental heterogeneity. We found a significant correlation between divergence in gene expression and DNA sequence divergence for overall patterns of gene expression but not for those that respond to the presence of copper sulfate. While this implies that different explanations are needed for the two groups of genes, it is difficult to ascribe neutral or selective explanations with high levels of confidence. First, gene-expression differences are also expected to accumulate with divergence time if selection is uniform in its pressure across all strains. Second, many factors can influence the variance in the number of expression differences between two strains, so the significance of the association between divergence in gene expression with DNA sequence divergence is difficult to interpret. Regardless, the relationship between rates of protein divergence and divergence in gene expression are useful to understanding biological diversity at the molecular level.
The average rate of change in gene expression was estimated to be 5,448 expression changes across the genome per synonymous substitution per site, or 0.887 (5,448/6,144) expression changes in each gene per synonymous substitution per site (see Materials and methods). The average number of synonymous substitutions per site, amino-acid-altering substitutions per site, and intergenic substitutions per site between strains in the three sequenced regions, was estimated as 6.87 × 10-3, 1.20 × 10-3, and 2.00 × 10-3, respectively. Therefore, the rate of change in gene expression per synonymous substitution is higher than the rate of amino-acid substitution per synonymous substitution (0.175) or the rate of intergenic substitution per synonymous substitution (0.291). If intergenic sites were neutral, the expected rate of intergenic substitution per synonymous substitution is 1. The ratio of rates of intergenic to synonymous substitution suggests that purifying selection constrains about 70% of intergenic sites found 5' of the HHT2, MBP1 and SUP35 genes. Because we do not know the effective number of sites in the genome which when mutated alter gene-expression levels in copper sulfate and rich medium, we cannot determine how many differentially expressed genes would be expected in the absence of any selective constraints on changes in gene expression. The mutation variance for gene expression is needed to estimate the amount of selective constraint on gene expression levels.
Yeast strains were selected from a larger collection of strains surveyed for variation in sensitivity to copper sulfate and those used are listed in Table 1. Of the nine strains, seven were isolated from vineyards in Italy between 1993 and 1994 by R. Mortimer . The diploid, sequenced lab strain, S288C, was obtained from the Botstein lab (DBY8268). The lab strain S288C is mostly derived from EM93, which was isolated from a rotting fig in California in 1938 . The woodland strain, YPS163, and the S. paradoxus strain, YPS125, were isolated from oak tree exudates in Lima, Pennsylvania in 1999 . The strains were chosen from a screen of around 100 natural isolates for variation in resistance to copper sulfate.
Resistance to copper sulfate
Strains were grown in 2 ml overnight rich medium cultures (YPD: 1% yeast extract, 2% peptone, 2% dextrose), diluted by a factor of 103 and 104 and plated onto the following media: rich medium (YPD + 2% agar) and rich medium plates supplemented with 1.0, 2.5, 5.0 and 7.5 mM copper sulfate; minimal medium (SD: 0.67% yeast nitrogen base with ammonium sulfate, 2% dextrose, 2% agar); SD supplemented with 0.1 mM copper sulfate; synthetic complete medium (CM: 0.67% yeast nitrogen base with amino acids and ammonium sulfate, 2% dextrose, 2% agar); and CM supplemented with 0.1 mM copper sulfate.
Three complete replicate experiments were done on different days. Each replicate started from a 2-ml overnight rich medium culture (YPD). Strains were grown at 30°C in either rich medium or copper sulfate medium (YPD supplemented with 1 mM CuSO4) to an OD600 of 1 (optical density of one at 600 nm is approximately 1 × 107 cells/ml), at which point they were diluted to an OD600 of 0.1 in 10 ml of either rich medium or copper sulfate medium. When the strains had again reached an OD600 of 0.8-1.0 (about 3 h later) they were spun for 3 min at 1,500g, lysed in 0.5 ml lysis buffer (10 mM Tris-Cl pH 7.4, 10 mM EDTA, 0.5% SDS) and frozen in liquid nitrogen. RNA was extracted using hot phenol and chloroform. At 3 h the strains were in exponential growth and any residual expression differences from the previous culture were not likely to be present. Total RNA was reverse transcribed using aminoallyl-dUTP then coupled to either a Cy3 or Cy5 fluorescent dye (Amersham Pharmacia) and hybridized overnight to microarrays on which 6,144, 70-bp oligonucleotides (Qiagen Operon) had been spotted as described at .
A reference design was used whereby the RNA from each strain grown in rich or copper sulfate medium was compared to a pool of the RNA from all strains grown in rich or copper sulfate medium, respectively. The reference pool was constructed using equal samples of RNA from each strain. While a loop design provides more statistical power from a given number of microarrays , in a loop design, a biased slide may bias estimates of all other treatment effects in the loop, while in a reference design, a biased slide only biases the estimate of a single treatment effect. We chose to use a separate rich medium and copper sulfate reference pool so as to maximize our ability to detect strain differences. For example, an expression difference between rich medium and copper sulfate of 1 to 1,000 units in strain A and 2 to 1,000 units in strain B may not be distinguishable unless strain A and B are compared in rich and copper sulfate medium separately. To identify genes expressed at different levels in rich medium compared to copper sulfate, the two reference pools were directly compared.
Arrays were scanned using a GenePix 4000A scanner and GenePix 4.0 software (Axon). An average of 762 spots per slide were manually flagged as unusable. The raw expression data are available in the GEO database under the ID GSE1073. Each array was print-tip normalized (mean normalized as a function of spot intensity) using the SMA package of the R statistics software with a span parameter of 0.7 . A span parameter of 1.0 is equal to no intensity-dependent normalization and a span parameter of 0.7 normalizes by intensity as a function of 70% of the data. Three replicate experiments were carried out, resulting in 54 arrays (9 strains, 3 replicates, 2 conditions) to measure differences among strains and six arrays to measure differences between the two reference pools. For one of the replicates a dye-swap was performed, where Cy3 instead of Cy5 was used to label the reference sample. Of the six comparisons between reference pools, two were dye-swaps. Significant differences in gene expression among strains were obtained by applying an analysis of variance (ANOVA) to each gene individually using the model: y i = u + V i + e i where y i is the ratio of transcipts in strain i compared to the reference pool, u is the average ratio across all strains, V i is the effect of strain i on the transcript ratio, and e i is the error. An analysis of variance on transcript levels rather than on ratios of transcripts was also done and produced similar results. A t-test was used to identify genes differentially expressed between the rich medium and copper sulfate medium reference pools.
Permutation resampling was used to estimate the number of false positives generated for different p-value cutoffs. For each gene, the expression data was randomized with respect to strain 100 times. Each resampling produced very similar rates of false positives. Using a p-value cutoff of p < 0.05, 922 genes showed significant expression differences across both conditions and the number of false positives was estimated to be 255 from permutation resampling. Using a cutoff of p < 0.01, 516 genes showed expression differences across both conditions with only 57 estimated false positives. Using a cutoff of p < 0.001, 277 genes showed expression differences across both conditions with only two estimated false positives. While the less stringent cutoff produces 667 (922 - 255) compared to 459 (516 - 57) significant expression differences, 28% compared to 11% of significant genes are false positives. While the most stringent cutoff produces only two false positives, only 275 compared to 459 (516 - 57) expression differences are detected. We chose a p-value cutoff of 0.01 to maximize the number of significant genes and hold the rate of false positives to a minimum.
To identify genes with expression patterns that specifically differ between rich medium and copper sulfate treatments, we performed an analysis of variance using the model y i = u + V i + V i M j + e i where y i is the ratio of transcipts in strain i compared to the reference pool, u is the average ratio across all strains, V i is the effect of strain i on the transcript ratio, V i M j is the interaction between the ratio of transcripts in strain i and medium treatment j (either rich medium or copper sulfate), and e i is the error. Using this model, 56 genes were found to differ in their rich medium compared to copper sulfate medium among strain expression patterns.
Significant genes were hierarchically clustered using Cluster and visualized using Treeview . Groups of functionally related genes were annotated by hand and are presented in Figure 2. The microarray images, GenePix gpr files and tab-delimited Cluster files are available on the Faylab homepage .
Growth rate was measured as the slope of the regression of log10 of cell density, as measured by OD600, and log10 of time, measured in minutes. Although the cell populations followed a logistic growth curve, copper sulfate treatment affected both the growth rate and carrying capacity parameters of the logistic growth model. Thus, a simple linear rather than logistic regression was used.
DNA sequence data
Three genes, HHT2, MBP1 and SUP35, were sequenced using Big Dye (PerkinElmer) termination sequencing of purified PCR products, GenBank accession number AY553984-AY554008. No polymerase chain reaction (PCR) product could be obtained from M14 and M32 for the SUP35 gene. HHT2 on chromosome 14 encodes a histone, SUP35 on chromosome 4 encodes a translation termination factor, and MBP1 on chromosome 4 encodes a transcription factor functioning in the cell cycle and DNA replication, 455 kb away from SUP35. The forward and reverse primers for HHT2 were 5'ACCACCTTTACCTCTACCGG and 5'AAATTCCCGCTTTATATTCATG, respectively; for MBP1, 5'TTACCGATAAGGAGGGGTAGAG and 5'CGGGAAATCGCTCTTCAAA, respectively; and for SUP35, 5'AAAATCCCAACCCTACGGTA and 5'CCACTGTAGCCGGATACTGGCA, respectively. For each strain both DNA strands were sequenced and analyzed using Phred, Phrap and Consed  and polymorphic sites were identified manually. The first polymorphic site found at MBP1 was heterozygous in both the M5 and M13 strains, and only the site different from the consensus was used in the analysis. Replacement, synonymous and intergenic polymorphic sites were identified using DNASP . A total of 31 segregating sites was found in 3,747 bp surveyed in the nine strains. These include seven intergenic sites, 14 synonymous sites, and 10 replacement sites.
Comparison of expression and phenotype data
Gene-expression differences in the presence of copper sulfate were correlated with sensitivity to copper sulfate and rust coloration. We used a binary vector to represent differences in growth rate and difference in color in the presence of 1 mM copper sulfate. From Figure 1, both M34 and YPS163 have a reduced rate of growth compared to the other seven strains. Thus, growth rate was a vector of 0s for unaffected strains and 1s for affected strains. Rust coloration was represented by a vector of 0s for white strains and 1s for M14 and M22, the two rust-colored strains.
Comparison of expression and DNA sequence data
Divergence in gene expression was measured as the number of pairwise differences in gene expression among strains. Because duplicate genes can cross-hybridize on the microarrays, each 70-bp probe was tested for its cross-hybridization potential. Probes susceptible to cross-hybridization were identified as those probes with 70% or greater nucleotide identity to coding sequences other than to the gene the probe was designed to detect. This cutoff was chosen because many genes with 70% sequence identity showed little or no correlation in their expression pattern. Of the 731 genes, 66 families of potentially cross-hybridizing probes were found. Of the 66 families, 44 families only contained one probe among the significant genes and the remaining 26 families contained 158 probes among the significant genes. The largest family was of 71 gag or pol genes present in Ty transposable elements. All but one member of each potentially cross-hybridizing gene family was removed. The remaining 599 genes were tested for pairwise differences in gene expression using a t-test (p < 0.05). Of these, 436 showed at least one or more differences in gene expression among strains in rich medium, copper sulfate medium or both. A Mantel test showed that these expression differences are significantly associated with DNA sequence differences (P = 0.043). The slope of the regression of expression differences on synonymous DNA sequence differences was 5,448. Synonymous DNA sequence differences were used to estimate the rate of change in gene expression as amino-acid altering and intergenic rates of divergence are heavily influenced by purifying selection.
DNA sequence differences between strains were unlikely to affect hybridization. We expect about 0.2 mismatches per 70-bp oligonucleotide, given the sequence divergence between strains at synonymous and amino-acid-altering sites and given that about 70% of coding sites are amino-acid altering. Thus, 82% of hybridizations should contain no mismatches. The remaining probes are not likely to affect the results. After the removal of potentially cross-hyridizing probes, we found many expression patterns that were nearly identical, even though low levels of sequence divergence existed. For example many Ty elements contain one or two mismatches out of 70. Thus, low levels of sequence divergence are unlikely to affect the results. In addition, S288C expression data could be removed and we would expect the results to be the same since the reference pool contains only a small portion of S288C cDNA.
Pairwise gene-expression differences were obtained from the 131 genes found to differ between the two media treatments (Figure 6). Of these genes, two clusters were enriched for genes functioning in protein folding, stress response and carbohydrate metabolism (p < 10-5 ). Five genes were removed because of potentially cross-hybridizing probes, and of the remainder, 48 genes showed at least one or more pairwise gene-expression difference between strains in either rich medium, copper sulfate medium, or both (t-test, p < 0.05). A Mantel test found no significant association between DNA sequence divergence and the expression differences of these 48 genes between strains (p > 0.05).
Overnight cultures were resuspended in 4 ml of YPD at an OD600 of approximately 1 and grown at 30°C for 2 h. Cultures were then split and treated for 1 h at 4°C or at -30°C in an ethanol bath. The frozen cultures were then returned to 4°C by shaking in a 20°C water bath. Both 4°C and -30°C treated cultures were then grown in a 30°C shaker. Relative growth rate was measured by the increase in OD600 from the time of treatment to 4 h later for three replicate experiments.
A figure (Additional data file 1) showing strains grown on minimal media and synthetic complete media in the presence and absence of copper sulfate is available with the online version of this article.
We thank A. Moses for stimulating discussions, A. Gasch for the suggestion that differential expression of AQY2 may confer freeze tolerance, and members of the Eisen lab, J. Townsend and D. Crawford for comments on the manuscript. This research was supported by a Sloan Postdoctoral Fellowship to J.C.F. M.B.E. is a Pew Scholar in the Biomedical Sciences. This work was conducted under the US Department of Energy contract number ED-AC03-76SF00098.
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