Adaptive, or Stationary-Phase, Mutagenesis, a Component of Bacterial Differentiation in Bacillus subtilis
Adaptive (stationary-phase) mutagenesis occurs in the gram-positive bacterium Bacillus subtilis. Furthermore, taking advantage of B. subtilis as a paradigm for the study of prokaryotic differentiation and development, we have shown that this type of mutagenesis is subject to regulation involving at least two of the genes that are involved in the regulation of post-exponential phase prokaryotic differentiation, i.e., comA and comK. On the other hand, a functional RecA protein was not required for this type of mutagenesis. The results seem to suggest that a small subpopulation(s) of the culture is involved in adaptive mutagenesis and that this subpopulation(s) is hypermutable. The existence of such a hypermutable subpopulation(s) raises important considerations with respect to evolution, the development of specific mutations, the nature of bacterial populations, and the level of communication among bacteria in an ecological niche.For over a decade, there has been considerable interest in a phenomenon that has been called adaptive, or stationaryphase, mutagenesis. The result of the mechanism(s) responsible for this phenomenon is the production of mutations that arise in nondividing or stationary-phase bacteria when the cells are subjected to nonlethal selective pressure, such as nutrientlimited environments (6,11,15,32,61). While most of the research has involved Escherichia coli model systems, similar observations have been made in other prokaryotes (43) as well as in eukaryotic organisms (69).In the FЈ lac frameshift reversion assay system in E. coli, stationary-phase mutations that lead to the generation of Lac ϩ cells can be distinguished from normal growth-dependent spontaneous Lac ϩ mutations (21, 59, 63). Specifically, Lac ϩ mutations are generated in stationary-phase cells via a molecular mechanism that requires a functional homologous recombination system (11,21,36,37), FЈ transfer functions (20, 23), and a component(s) of the SOS system (50). Genetic evidence suggests that DNA polymerase III (18, 35) and DNA polymerase IV (51, 52) are responsible for the synthesis of errors that lead to these mutations. Furthermore, for the Lac ϩ mutations, different sequence spectra are generated for the stationaryphase mutations than for the types of mutations generated during growth.For instance, a majority of the Lac ϩ mutations that arise during stationary phase have a Ϫ1 deletion at mononucleotide repeats within the target gene. On the other hand, for the spontaneous mutations that arise during growth, various types of mutations occur in seemingly random locations (19, 62). These characteristics suggested that stationary-phase Lac ϩ reversions occur via a different molecular mechanism(s) than for those reversions of the same lac allele that are generated during growth. However, there is also evidence that demonstrates that the mutations generated by this lac system during stationary phase are the result of gene amplification followed by SOS-induced mutagenesis and selection (39).Although the very observations of ada...
Gene expression is regulated both by cis elements, which are DNA segments closely linked to the genes they regulate, and by trans factors, which are usually proteins capable of diffusing to unlinked genes. Understanding the patterns and sources of regulatory variation is crucial for understanding phenotypic and genome evolution. Here, we measure genome-wide allele-specific expression by deep sequencing to investigate the patterns of cis and trans expression variation between two strains of Saccharomyces cerevisiae. We propose a statistical modeling framework based on the binomial distribution that simultaneously addresses normalization of read counts derived from different parents and estimating the cis and trans expression variation parameters. We find that expression polymorphism in yeast is common for both cis and trans, though trans variation is more common. Constraint in expression evolution is correlated with other hallmarks of constraint, including gene essentiality, number of protein interaction partners, and constraint in amino acid substitution, indicating that both cis and trans polymorphism are clearly under purifying selection, though trans variation appears to be more sensitive to selective constraint. Comparing interspecific expression divergence between S. cerevisiae and S. paradoxus to our intraspecific variation suggests a significant departure from a neutral model of molecular evolution. A further examination of correlation between polymorphism and divergence within each category suggests that cis divergence is more frequently mediated by positive Darwinian selection than is trans divergence.
Molecular phylogeny of extant gymnosperms and seed plant evolution: analysis of nuclear 18S rRNA sequences
To study the evolutionary relationships among the four living gymnosperm orders and the interfamilial relationships in each order, a set of 65 nuclear 18S rRNA sequences from ferns, gymnosperms, and angiosperms was analyzed using the neighbor-joining and maximum-parsimony methods. With Selaginella as the outgroup, the analysis strongly indicates that the seed plants form a monophyletic group with the ferns as a sister group. Within the seed plants the angiosperms are clearly a monophyletic group. Although the bootstrap support for the monophyly of the gymnosperm clade is moderate, the monophyly is further supported by its lack of angiosperm-specific indels. Within the gymnosperms there appear to be three monophyletic clades: Cycadales-Ginkgoales, Gnetales, and Coniferales. The cycad-ginkgo clade is the earliest gymnosperm lineage. Given the strong support for the sister group relationship between Gnetales and Coniferales, it is unlikely that Gnetales is a sister group of the angiosperms, contrary to the view of many plant taxonomists. Within Coniferales, Pinaceae is monophyletic and basal to the remaining conifer families, among which there are three monophyletic clades: Phyllocladaceae-Podocarpaceae, Araucariaceae, and Sciadopityaceae-Taxaceae-Cephalotaxaceae-Taxodiacea e-Cupressaceae. Within the latter clade, Sciadopityaceae may be an outgroup to the other four families. Among the angiosperms, no significant cluster at the level of subclass was found, but there was evidence that Nymphaeaceae branched off first. Within the remaining angiosperms, the monocots included in this study are nested and form a monophyletic group. This study attests to the utility of nuclear 18S rRNA sequences in addressing relationships among living gymnosperms. Considerable variation in substitution rates was observed among the ferns and seed plants.
YqjH and YqjW are Bacillus subtilis homologs of the UmuC/DinB or Y superfamily of DNA polymerases that are involved in SOS-induced mutagenesis in Escherichia coli. While the functions of YqjH and YqjW in B. subtilis are still unclear, the comparisons of protein structures demonstrate that YqjH has 36% identity to E. coli DNA polymerase IV (DinB protein), and YqjW has 26% identity to E. coli DNA polymerase V (UmuC protein). In this report, we demonstrate that both YqjH and the products of the yqjW operon are involved in UV-induced mutagenesis in this bacterium. Furthermore, resistance to UV-induced damage is significantly reduced in cells lacking a functional YqjH protein. Analysis of stationary-phase mutagenesis indicates that absences of YqjH, but not that of YqjW, decreases the ability of B. subtilis to generate revertants at the hisC952 allele via this system. These data suggest a role for YqjH in the generation of at least some types of stationary-phase-induced mutagenesis.In Escherichia coli, the dinB gene is required for bacteriophage untargeted mutagenesis (UTM), an error-prone pathway observed when undamaged DNA infects SOS-induced E. coli cells (4, 55). Overexpression of the dinB gene confers a mutator phenotype on the cells (22). However, mutations in the dinB gene only caused a modest UV sensitivity phenotype, indicating that this gene product might not play a major role in the tolerance of DNA lesions introduced by UV irradiation into E. coli (22). The genetic requirements for UTM include the recA, uvrA, uvrB, uvrC, and polA genes, as well as DNA polymerase III (DNA Pol III), in addition to dinB (22,26). However, when the dinB gene is overexpressed on a multicopy plasmid, these requirements for genes besides dinB for UTM are bypassed (22). In 1999, it was discovered that the purified DinB protein has a template-directed, DNA-dependent DNA polymerase activity and it was designated the fourth DNA polymerase in E. coli (DNA Pol IV) (51).The DNA damage-inducible UmuDЈ and UmuC proteins are required for another type of SOS mutagenesis in E. coli (40). UmuCD-dependent translesion DNA synthesis allows cells to replicate past DNA damage-induced lesions that would normally block the continuing polymerization by the major replication DNA polymerase (DNA Pol III) in E. coli. This translesion synthesis results in an increased mutation rate (21, 42). The translesion DNA synthesis process requires the products of the SOS-regulated recA gene and the umuDC operon, which was originally identified by screening for E. coli mutants that were not mutable by UV light and other agents (21, 42). The umuDC gene products are also known to be essential components of chromosomal UTM (9, 27), a transient increase in the mutation frequency of chromosomal genes following induction of the SOS response (9, 27, 30). In 1999, UmuC or UmuDЈ 2 C was discovered to be a template-directed, DNAdependent DNA polymerase that was designated the fifth DNA polymerase in E. coli (DNA Pol V) (34, 49).It has very recently become apparent that UmuC ...
Previously, using a chromosomal reversion assay system, we established that an adaptive mutagenic process occurs in nongrowing Bacillus subtilis cells under stress, and we demonstrated that multiple mechanisms are involved in generating these mutations (41, 43). In an attempt to delineate how these mutations are generated, we began an investigation into whether or not transcription and transcription-associated proteins influence adaptive mutagenesis. In B. subtilis, the Mfd protein (transcription repair coupling factor) facilitates removal of RNA polymerase stalled at transcriptional blockages and recruitment of repair proteins to DNA lesions on the transcribed strand. Here we demonstrate that the loss of Mfd has a depressive effect on stationary-phase mutagenesis. An association between Mfd mutagenesis and aspects of transcription is discussed.Since the mid-1950s, microbiologists have been aware of mutations occurring in nondividing populations of cells (22,29). The formation of these mutants was alternatively termed "starvation-associated mutagenesis" (29), "adaptive mutation" (8), or "stationary-phase mutagenesis" (13). Recently, variations of this phenomenon have been investigated with Escherichia coli (8,29,38), Pseudomonas (33), Bacillus subtilis (41), and the eukaryotic yeast Saccharomyces cerevisiae (15,40). These phenomena reveal that starving populations of cells can acquire mutations favoring growth after the application of selection.While the phenomenon of stationary-phase mutation is widespread, it is clear that the mechanism(s) by which it arises varies from organism to organism. To date, the most favored system for studying adaptive or stationary-phase mutagenesis is the RecA-dependent E. coli FC40 system investigated by, among others, the laboratories of Cairns, Foster, Rosenberg, and Roth (7,8,11,18). Recent results strongly suggest that this mutagenesis is the result of gene amplification followed by mutation in a transiently growing population of cells (18). In light of this, we chose to investigate the possibility that transiently growing cells may play a role in a B. subtilis system containing three chromosomal point mutations. The phenomenon of transcriptional mutagenesis, or retromutagenesis, whereby RNA polymerase bypasses an unrepaired DNA lesion or otherwise produces an altered mRNA, which is then translated into a protein of altered function, could provide a transient growth advantage for the cell. This mechanism has been proposed for other model systems, including eukaryotes (6, 9).We have previously shown the existence of one such mutagenic phenomenon occurring during stationary phase in B. subtilis cells starved for amino acids (41). This mutagenic process appears to enhance the survivability of cell populations undergoing nutritional stress. In brief, isogenic strains of B. subtilis carrying three amino acid auxotrophies conferred by hisC952 (amber), metB5 (ochre), and leuC427 (missense) are incubated on medium lacking one of the required amino acids. After several days of incubati...
BackgroundNeocallimastix patriciarum is one of the common anaerobic fungi in the digestive tracts of ruminants that can actively digest cellulosic materials, and its cellulases have great potential for hydrolyzing cellulosic feedstocks. Due to the difficulty in culture and lack of a genome database, it is not easy to gain a global understanding of the glycosyl hydrolases (GHs) produced by this anaerobic fungus.ResultsWe have developed an efficient platform that uses a combination of transcriptomic and proteomic approaches to N. patriciarum to accelerate gene identification, enzyme classification and application in rice straw degradation. By conducting complementary studies of transcriptome (Roche 454 GS and Illumina GA IIx) and secretome (ESI-Trap LC-MS/MS), we identified 219 putative GH contigs and classified them into 25 GH families. The secretome analysis identified four major enzymes involved in rice straw degradation: β-glucosidase, endo-1,4-β-xylanase, xylanase B and Cel48A exoglucanase. From the sequences of assembled contigs, we cloned 19 putative cellulase genes, including the GH1, GH3, GH5, GH6, GH9, GH18, GH43 and GH48 gene families, which were highly expressed in N. patriciarum cultures grown on different feedstocks.ConclusionsThese GH genes were expressed in Pichia pastoris and/or Saccharomyces cerevisiae for functional characterization. At least five novel cellulases displayed cellulytic activity for glucose production. One β-glucosidase (W5-16143) and one exocellulase (W5-CAT26) showed strong activities and could potentially be developed into commercial enzymes.
Expression evolution in yeast genes of single-input modules is mainly due to changes in trans-acting factors
Both cis-and trans-regulatory mutations contribute to gene expression divergence within and between species. To estimate their relative contributions, we examined two yeast strains, BY (a laboratory strain) and RM (a wild strain), for their gene-expression divergence by microarray. Using these data and published ChIP-chip data, we obtained a set of single-regulator-regulated genes that showed expression divergence between BY and RM. We randomly selected 50 of these genes for further study. We developed a step-by-step approach to assess the relative contributions of cisand trans-variations to expression divergence by using pyrosequencing to quantify the mRNA levels of the BY and RM alleles in the same culture (co-culture) and in hybrid diploids. Forty genes showed expression divergence between the two strains in co-culture, and pyrosequencing of the BY/RM hybrid diploids showed that 45% (18/40) can be attributed to differences in trans-acting factors alone, 17.5% (7/40) mainly to trans-variations, 20% (8/40) to both cis-and trans-acting factors, 7.5% (3/40) mainly to cis-variations, and 10% (4/40) to cis-acting factors alone. In addition, we replaced the BY promoter by the RM promoter in each of 10 BY genes that were found from our microarray data to have expression divergence between BY and RM, and in each case our quantitative PCR analysis revealed a cis effect of the promoter replacement on gene expression. In summary, our study suggests that trans-acting factors play the major role in expression evolution between yeast strains, but the role of cis variation is also important.
Both cis and trans mutations contribute to gene expression divergence within and between species. We used Saccharomyces cerevisiae as a model organism to estimate the relative contributions of cis and trans variations to the expression divergence between a laboratory (BY) and a wild (RM) strain of yeast. We examined whether genes regulated by a single transcription factor (TF; single input module, SIM genes) or genes regulated by multiple TFs (multiple input module, MIM genes) are more susceptible to trans variation. Because a SIM gene is regulated by a single immediate upstream TF, the chance for a change to occur in its trans-acting factors would, on average, be smaller than that for a MIM gene. We chose 232 genes that exhibited expression divergence between BY and RM to test this hypothesis. We examined the expression patterns of these genes in a BY-RM coculture system and in a BY-RM diploid hybrid. We found that trans variation is far more important than cis variation for expression divergence between the two strains. However, because in 75% of the genes studied, cis variation has significantly contributed to expression divergence, cis change also plays a significant role in intraspecific expression evolution. Interestingly, we found that the proportion of genes with diverged expression between BY and RM is larger for MIM genes than for SIM genes; in fact, the proportion tends to increase with the number of transcription factors that regulate the gene. Moreover, MIM genes are, on average, subject to stronger trans effects than SIM genes, though the difference between the two types of genes is not conspicuous.
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