Contribution of horizontal gene transfer to the evolution of Saccharomyces cerevisiae

The genomes of the hemiascomycetes Saccharomyces cerevisiae and Ashbya gossypii have been completely sequenced, allowing a comparative analysis of these two genomes, which reveals that a small number of genes appear to have entered these genomes as a result of horizontal gene transfer from bacterial sources. One potential case of horizontal gene transfer in A. gossypii and 10 potential cases in S. cerevisiae were identified, of which two were investigated further. One gene, encoding the enzyme dihydroorotate dehydrogenase (DHOD), is potentially a case of horizontal gene transfer, as shown by sequencing of this gene from additional bacterial and fungal species to generate sufficient data to construct a well-supported phylogeny. The DHOD-encoding gene found in S. cerevisiae, URA1 (YKL216W), appears to have entered the Saccharomycetaceae after the divergence of the S. cerevisiae lineage from the Candida albicans lineage and possibly since the divergence from the A. gossypii lineage. This gene appears to have come from the Lactobacillales, and following its acquisition the endogenous eukaryotic DHOD gene was lost. It was also shown that the bacterially derived horizontally transferred DHOD is required for anaerobic synthesis of uracil in S. cerevisiae. The other gene discussed in detail is BDS1, an aryl- and alkyl-sulfatase gene of bacterial origin that we have shown allows utilization of sulfate from several organic sources. Among the eukaryotes, this gene is found in S. cerevisiae and Saccharomyces bayanus and appears to derive from the alpha-proteobacteria.     

Trends and barriers to lateral gene transfer in prokaryotes

Gene acquisition by lateral gene transfer (LGT) is an important mechanism for natural variation among prokaryotes. Laboratory experiments show that protein-coding genes can be laterally transferred extremely fast among microbial cells, inherited to most of their descendants, and adapt to a new regulatory regime within a short time. Recent advance in the phylogenetic analysis of microbial genomes using networks approach reveals a substantial impact of LGT during microbial genome evolution. Phylogenomic networks of LGT among prokaryotes reconstructed from completely sequenced genomes uncover barriers to LGT in multiple levels. Here we discuss the kinds of barriers to gene acquisition in nature including physical barriers for gene transfer between cells, genomic barriers for the integration of acquired DNA, and functional barriers for the acquisition of new genes.     

Phylogenetic reconstruction and lateral gene transfer

Lateral gene transfer (LGT) is often seen as a form of noise, obscuring the phylogenetic signal with which we might hope to reconstruct the evolution of a group of organisms, or indeed the history of all life (the Tree of Life). Such reconstruction might still be possible if the subset of genes conserved among all genomes in a group (or common to all genomes) comprise a core that is relatively refractory to LGT. Several papers designed to test this notion have recently appeared, and here we re-analyze one, which claims that the core of single-copy orthologs shared by all sequenced genomes of the gammaproteobacteria is essentially free of LGT. This conclusion is unfortunately premature, and it is very hard to determine what fraction of this core has been affected by LGT. We discuss other difficulties with the core concept and suggest that, although the core idea must remain part of our understanding of phylogenetic relationships, it should not be the sole basis for defining such relationships, because these are not exclusively tree-like. We suggest instead a more complex but more natural framework for classification, which we call the Synthesis of Life.     

The chemostat with lateral gene transfer

We investigate the standard chemostat model when lateral gene transfer is taken into account. We will show that when the different genotypes have growth rate functions that are sufficiently close to a common growth rate function, and when the yields of the genotypes are sufficiently close to a common value, then the population evolves to a globally stable steady state, at which all genotypes coexist. These results can explain why the antibiotic-resistant strains persist in the pathogen population.     

The chemostat with lateral gene transfer

We investigate the standard chemostat model when lateral gene transfer is taken into account. We will show that when the different genotypes have growth rate functions that are sufficiently close to a common growth rate function, and when the yields of the genotypes are sufficiently close to a common value, then the population evolves to a globally stable steady state, at which all genotypes coexist. These results can explain why the antibiotic-resistant strains persist in the pathogen population.     

Phylogenetic analyses suggest lateral gene transfer from the mitochondrion to the apicoplast

The genomes of the three temperate bacteriophages contained in the chromosome of Staphylococcus aureus 8325 have been extracted from the sequence database and analyzed. phi 11, phi 12 and phi 13 are members of the same lytic group but different serogroups and consequently co-habitate the same host cell. Their genomes are approximately 42 kb to 45 kb and contain about 90 ORFs of at least 50 codons. Of these, about 50 have similarities to known genes or to genes of other staphylococcal phages. Each of the phages clusters within a homology group that share large regions of sequence identity while intergroup homology is comparatively low. The arrangement of genes on the chromosomes of the three phages is similar and consistent with current modular theory of phage gene organization. The replicated genomes appear to be packaged by different mechanisms. Phage phi 11 and phi 12 have been found to contain sequences consistent with pac-site phages while phi 13 has sequences consistent with cos-site phages. The attBsite for phi 11 is located in an intergenic region of the S. aureus chromosome while phi 12 and phi 13 integrate into specific genes. The phi 12 att-site is within an unknown gene, but the phi 13 att-site is within the beta-toxin gene. In contrast to the other two phages, phi 13 also introduces the staphylokinase gene (sak) and a second gene related to expression of fib.     

Much ado about bacteria-to-vertebrate lateral gene transfer

When the International Human Genome Sequencing Consortium (IHGSC) published its draft of the human genome in February 2001, several genes were identified as possible bacteria-to-vertebrate transfers (BVTs). These genes were identified by their highly significant sequence similarity to bacterial genes in BLAST searches, and by their lack of matches among non-vertebrate eukaryote genes. Many were later rejected as BVTs by several methods, including recovery of probable orthologs from the genomes of incompletely sequenced eukaryotes. Whereas the BVT issue has received considerable attention, there has been no compilation of all potential BVTs considered to date, nor any proposal of a single comprehensive method for rigorously establishing the veracity of a putative BVT. In reviewing the work to date, we list all of the proteins examined and propose systematic tests to investigate whether a vertebrate gene proposed as a BVT is indeed of bacterial origin. We use the proposed strategy to test--and reject--one of the BVTs from the original IHGSC list.     

Thermotoga heats up lateral gene transfer.

The complete sequence of the bacterium Thermotoga maritima genome has revealed a large fraction of genes most closely related to those of archaeal species. This adds to the accumulating evidence that lateral gene transfer is a potent evolutionary force in prokaryotes, though questions of its magnitude remain.     

High rates of lateral gene transfer are not due to false diagnosis of gene absence

Methods for assessing gene presence and absence have been widely used to study bacterial genome evolution. A recent report by Zhaxybayeva et al. [Zhaxybayeva, O., Nesbo, C. L., and Doolittle, W. F., 2007. Systematic overestimation of gene gain through false diagnosis of gene absence. Genome. Biol. 8, 402] suggests that false diagnosis of gene absence or the presence of undetected truncated genes leads to a systematic overestimation of gene gain. Here (1) we argue that these annotation errors can cause more complicated effects and are not necessarily systematic, (2) we argue that current annotations (supplemented with BLAST searches) are the best way to consistently score gene presence/absence and (3) that genome wide estimates of gene gain/loss are not strongly affected by small differences in gene annotations but that the number of related gene families is strongly affected. We have estimated the rates of gene insertions/deletions using a variety of cutoff thresholds and match lengths as a way in which to alter the recognition of genes and gene fragments. The results reveal that different cutoffs for match length only cause a small variation of the estimated insertion/deletion rates. The rates of gene insertions/deletions on recent branches remain relatively high regardless of the thresholds for match length. Lastly (4), the dynamic process of gene truncation needs to be further considered in genome comparison studies. The data presented suggest that gene truncation tends to take place preferentially in recently transferred genes, which supports a fast turnover of recent laterally transferred genes. The presence of truncated genes or false diagnosis of gene absence therefore does not significantly affect the estimation of gene insertions/deletions rates, but there are several other factors that bias the results toward an under-estimation of the rate of gene insertion/deletion. All of these factors need to be considered.     

A singular bacteriophytochrome acquired by lateral gene transfer

Bacteriophytochromes are phytochrome-like proteins that mediate photosensory responses in various bacteria according to their light environment. The genome of the photosynthetic and plant-symbiotic Bradyrhizobium sp. strain ORS278 revealed the presence of a genomic island acquired by lateral transfer harboring a bacteriophytochrome gene, BrBphP3.ORS278, and genes involved in the synthesis of phycocyanobilin and gas vesicles. The corresponding protein BrBphP3.ORS278 is phylogenetically distant from the other (bacterio)phytochromes described thus far and displays a series of unusual properties. It binds phycocyanobilin as a chromophore, a unique feature for a bacteriophytochrome. Moreover, its C-terminal region is short and displays no homology with any known functional domain. Its dark-adapted state absorbs maximally around 610 nm, an unusually short wavelength for (bacterio)phytochromes. This form is designated as Po for orange-absorbing form. Upon illumination, a photo-reversible switch occurs between the Po form and a red (670 nm)-absorbing form (Pr), which rapidly backreacts in the dark. Because of this instability, illumination results in a mixture of the Po and Pr states in proportions that depend on the intensity. These uncommon features suggest that BrBphP3.ORS278 could be fitted to measure light intensity rather than color.     

Unconventional lateral gene transfer in extreme thermophilic bacteria

Conjugation and natural competence are two major mechanisms that explain the acquisition of foreign genes throughout bacterial evolution. In recent decades, several studies in model organisms have revealed in great detail the steps involved in such processes. The findings support the idea that the major basis of these mechanisms is essentially similar in all bacteria. However, recent work has pinpointed the existence of new, evolutionarily different processes underlying lateral gene transfer. In Thermus thermophilus HB27, at least 16 proteins are required for the activity of one of the most efficient natural competence systems known so far. Many of those proteins have no similarities to proteins involved in natural competence in other well-known models. This unusual competence system is conserved, in association with the chromosome, in all other Thermus spp. genomes so far available, it being functional even in strains from isolated environments, such as deep mines. Conjugation is also possible among Thermus spp. Homologues to proteins implicated in conjugation in model bacteria are encoded in the genome of a recently sequenced strain of Thermus thermophilus and shared by other members of the genus. Nevertheless, processive DNA transfer in the absence of a functional natural competence system in strains in which no conjugation homologous genes can be found hints at the existence of an additional and unconventional conjugation mechanism in these bacteria.     

Complexity, connectivity, and duplicability as barriers to lateral gene transfer

Background

Lateral gene transfer is a major force in microbial evolution and a great source of genetic innovation in prokaryotes. Protein complexity has been claimed to be a barrier for gene transfer, due to either the inability of a new gene's encoded protein to become a subunit of an existing complex (lack of positive selection), or from a harmful effect exerted by the newcomer on native protein assemblages (negative selection).

Results

We tested these scenarios using data from the model prokaryote Escherichia coli. Surprisingly, the data did not support an inverse link between membership in protein complexes and gene transfer. As the complexity hypothesis, in its strictest sense, seemed valid only to essential complexes, we broadened its scope to include connectivity in general. Transferred genes are found to be less involved in protein-protein interactions, outside stable complexes, and this is especially true for genes recently transferred to the E. coli genome. Thus, subsequent to transfer, new genes probably integrate slowly into existing protein-interaction networks. We show that a low duplicability of a gene is linked to a lower chance of being horizontally transferred. Notably, many essential genes in E. coli are conserved as singletons across multiple related genomes, have high connectivity and a highly vertical phylogenetic signal.

Conclusion

High complexity and connectivity generally do not impede gene transfer. However, essential genes that exhibit low duplicability and high connectivity do exhibit mostly vertical descent.     

Evolution of the cutinase gene family: evidence for lateral gene transfer of a candidate Phytophthora virulence factor

Lateral gene transfer (LGT) can facilitate the acquisition of new functions in recipient lineages, which may enable them to colonize new environments. Several recent publications have shown that gene transfer between prokaryotes and eukaryotes occurs with appreciable frequency. Here we present a study of interdomain gene transfer of cutinases -- well documented virulence factors in fungi -- between eukaryotic plant pathogens Phytophthora species and prokaryotic bacterial lineages. Two putative cutinase genes were cloned from Phytophthora brassicae and Northern blotting experiments showed that these genes are expressed early during the infection of the host Arabidopsis thaliana and induced during cyst germination of the pathogen. Analysis of the gene organisation of this gene family in Phytophthora ramorum and P. sojae showed three and ten copies in tight succession within a region of 5 and 25 kb, respectively, probably indicating a recent expansion in Phytophthora lineages by gene duplications. Bioinformatic analyses identified orthologues only in three genera of Actinobacteria, and in two distantly related eukaryotic groups: oomycetes and fungi. Together with phylogenetic analyses this limited distribution of the gene in the tree of life strongly support a scenario where cutinase genes originated after the origin of land plants in a microbial lineage living in proximity of plants and subsequently were transferred between distantly related plant-degrading microbes. More precisely, a cutinase gene was likely acquired by an ancestor of P. brassicae, P. sojae, P. infestans and P. ramorum, possibly from an actinobacterial source, suggesting that gene transfer might be an important mechanism in the evolution of their virulence. These findings could indeed provide an interesting model system to study acquisition of virulence factors in these important plant pathogens.     

Contribution of TCR-beta locus and HLA to the shape of the mature human Vbeta repertoire

T cells that survive thymic selection express a diverse array of unique heterodimeric alphabeta TCRs that mediate peptide-MHC Ag recognition. The proportion of the total T cell repertoire that expresses a particular Vbeta protein may be determined by a variety of factors: 1) germline preference for use of particular Vbeta genes; 2) allelic effects on the expression of different Vbeta genes; and 3) HLA effects on the expression of different Vbeta genes (acting via thymic selection and/or peripheral mechanisms). In this study, we show that Vbeta usage by human CD4(+) and CD8(+) T cells in neonatal and adult donors is highly correlated between unrelated individuals, suggesting that a large proportion of the observed pattern of Vbeta expression is determined by factors intrinsic to the TCR-beta locus. The presence of identical TCR alleles (within an individual) leads to a significantly better correlation between CD4(+) and CD8(+) T cells with respect to Vbeta expression; these effects are, however, relatively minor. The sharing of HLA alleles between individuals also leads to an increased correlation between their Vbeta expression patterns, although this did not reach statistical significance. We therefore conclude that the correlation in Vbeta expression patterns between CD4(+) and CD8(+) T cells can be explained predominantly by germline TCR-beta locus factors and not TCR-beta allelic or HLA effects.     

Evidences of lateral gene transfer between archaea and pathogenic bacteria

Acquisition of new genetic material through horizontal gene transfer has been shown to be an important feature in the evolution of many pathogenic bacteria. Changes in the genetic repertoire, occurring through gene acquisition and deletion, are the major events underlying the emergence and evolution of bacterial pathogens. However, horizontal gene transfer across the domains i.e. archaea and bacteria is not so common. In this context, we explore events of horizontal gene transfer between archaea and bacteria. In order to determine whether the acquisition of archaeal genes by lateral gene transfer is an important feature in the evolutionary history of the pathogenic bacteria, we have developed a scheme of stepwise eliminations that identifies archaeal-like genes in various bacterial genomes. We report the presence of 9 genes of archaeal origin in the genomes of various bacteria, a subset of which is also unique to the pathogenic members and are not found in respective non-pathogenic counterparts. We believe that these genes, having been retained in the respective genomes through selective advantage, have key functions in the organism’s biology and may play a role in pathogenesis.     

Intranuclear verrucomicrobial symbionts and evidence of lateral gene transfer to the host protist in the termite gut

In 1944, Harold Kirby described microorganisms living within nuclei of the protists Trichonympha in guts of termites; however, their taxonomic assignment remains to be accomplished. Here, we identified intranuclear symbionts of Trichonympha agilis in the gut of the termite Reticulitermes speratus. We isolated single nuclei of T. agilis, performed whole-genome amplification, and obtained bacterial 16S rRNA genes by PCR. Unexpectedly, however, all of the analyzed clones were from pseudogenes of 16S rRNA with large deletions and numerous sequence variations even within a single-nucleus sample. Authentic 16S rRNA gene sequences were finally recovered by digesting the nuclear DNA; these pseudogenes were present on the host Trichonympha genome. The authentic sequences represented two distinct bacterial species belonging to the phylum Verrucomicrobia, and the pseudogenes have originated from each of the two species. Fluorescence in situ hybridization confirmed that both species are specifically localized, and occasionally co-localized, within nuclei of T. agilis. Transmission electron microscopy revealed that they are distorted cocci with characteristic electron-dense and lucent regions, which resemble the intranuclear symbionts illustrated by Kirby. For these symbionts, we propose a novel genus and species, ‘Candidatus Nucleococcus trichonymphae'' and ‘Candidatus Nucleococcus kirbyi''. These formed a termite-specific cluster with database sequences, other members of which were also detected within nuclei of various gut protists, including both parabasalids and oxymonads. We suggest that this group is widely distributed as intranuclear symbionts of diverse protists in termite guts and that they might have affected the evolution of the host genome through lateral gene transfer.     

About the last common ancestor, the universal life-tree and lateral gene transfer: a reappraisal

An organismal tree rooted in the bacterial branch and derived from a hyperthermophilic last common ancestor (LCA) is still widely assumed to represent the path followed by evolution from the most primeval cells to the three domains recognized among contemporary organisms: Bacteria, Archaea and Eucarya. In the past few years, however, more and more discrepancies between this pattern and individual protein trees have been brought to light. There has been an overall tendency to attribute these incongruities to widespread lateral gene transfer. However, recent developments, a reappraisal of earlier evidence and considerations of our own lead us to a quite different view. It would appear (i) that the role of lateral gene transfer was overemphasized in recent discussions of molecular phylogenies; (ii) that the LCA was probably a non-thermophilic protoeukaryote from which both Archaea and Bacteria emerged by reductive evolution but not as sister groups, in keeping with a current evolutionary scheme for the biosynthesis of membrane lipids; and (iii) that thermophilic Archaea may have been the first branch to diverge from the ancestral line.