Evolution of bacterial genomes

This review examines evolution of bacterial genomes with an emphasis on RNA based life, the transition to functional DNA and small evolving genomes (possibly plasmids) that led to larger, functional bacterial genomes.     

Packaging capacity of adeno-associated virus serotypes: impact of larger genomes on infectivity and postentry steps

The limited packaging capacity of adeno-associated virus (AAV) precludes the design of vectors for the treatment of diseases associated with larger genes. Autonomous parvoviruses, such as minute virus of mice and B19, while identical in size (25 nm), are known to package larger genomes of 5.1 and 5.6 kb, respectively, compared to AAV genomes of 4.7 kb. One primary difference is the fact that wild-type (wt) AAV utilizes three capsid subunits instead of two to form the virion shell. In this study, we have characterized the packaging capacity of AAV serotypes 1 through 5 with and without the Vp2 subunit. Using reporter transgene cassettes that range in size from 4.4 to 6.0 kb, we determined that serotypes 1 through 5 with and without Vp2 could successfully package, replicate in, and transduce cells. Dot blot analysis established that packaging efficiency was similar for all vector cassettes and that the integrity of encapsidated genomes was intact regardless of size. Although physical characterization determined that virion structures were indistinguishable from wt, transduction experiments determined that all serotype vectors carrying larger genomes (5.3 kb and higher) transduced cells less efficiently (within a log) than AAV encapsidating wt size genomes. This result was not unique to reporter genes and was observed for CFTR vector cassettes ranging in size from 5.1 to 5.9 kb. No apparent advantage in packaging efficiency was observed when Vp2 was present or absent from the virion. Further analysis determined that a postentry step was responsible for the block in infection and specific treatment of cells upon infection with proteasome inhibitors increased transduction of AAV encapsidating larger DNA templates to wt levels, suggesting a preferential degradation of virions encapsidating larger-than-wt genomes. This study illustrates that AAV is capable of packaging and protecting recombinant genomes as large as 6.0 kb but the larger genome-containing virions are preferentially degraded by the proteasome and that this block can be overcome by the addition of proteasome inhibitors.     

Larger rearranged mitochondrial genomes in Dekkera/Brettanomyces yeasts are more closely related than smaller genomes with a conserved gene order

Summary Mitochondrial genomes from yeasts in the Dekkera/Brettanomyces/Eeniella group vary in size from 28 to 101 kb. Mapping of genes has shown that the three smallest genomes, of 28–42 kb, have the same gene order, whereas the three larger mitochondrial DNAs of 57–101 kb are rearranged relative to the smaller molecules and between themselves. To examine the relationships between these genomes, a phylogenetic tree has been constructed by sequence comparison of the mitochondrialencoded cytochrome oxidase subunit gene (COX2) from the six species. Contrary to expectation, the tree shows that the larger rearranged genomes are more closely related than the smaller mtDNAs. This result indicates that the gene order of the smaller mtDNAs (28–42 kb) is ancestral and that larger mtDNA molecules (57–101 kb) are more prone to rearrangement than smaller forms.Offprint requests to: G.D. Clark-Walker     

Where are the pseudogenes in bacterial genomes?

Most bacterial genomes have very few pseudogenes; notable exceptions include the genomes of the intracellular parasites Rickettsia prowazekii and Mycobacterium leprae. As DNA can be introduced into microbial genomes in many ways, the compact nature of these genomes suggests that the rate of DNA influx is balanced by the rate of DNA deletion. We propose that the influx of dangerous genetic elements such as transposons and bacteriophages selects for the maintenance of relatively high deletion rates in most bacteria; the sheltered lifestyle of intracellular parasites removes this threat, leading to reduced deletion rates and larger pseudogene loads.     

Vertebrate genomes code excess proteins with charge periodicity of 28 residues

All amino acid sequences derived from 248 prokaryotic genomes, 10 invertebrate genomes (plants and fungi) and 10 vertebrate genomes were analysed by the autocorrelation function of charge sequences. The analysis of the total amino acid sequences derived from the 268 biological genomes showed that a significant periodicity of 28 residues is observable for the vertebrate genomes, but not for the other genomes. When proteins with a charge periodicity of 28 residues (PCP28) were selected from the total proteomes, we found that PCP28 in fact exists in all proteomes, but the number of PCP28 is much larger for the vertebrate proteomes than for the other proteomes. Although excess PCP28 in the vertebrate proteomes are only poorly characterized, a detailed inspection of the databases suggests that most excess PCP28 are nuclear proteins.     

Massive comparative genomic analysis reveals convergent evolution of specialized bacteria

Background  

Genome size and gene content in bacteria are associated with their lifestyles. Obligate intracellular bacteria (i.e., mutualists and parasites) have small genomes that derived from larger free-living bacterial ancestors; however, the different steps of bacterial specialization from free-living to intracellular lifestyle have not been studied comprehensively. The growing number of available sequenced genomes makes it possible to perform a statistical comparative analysis of 317 genomes from bacteria with different lifestyles.     

Construction of bacteriophage luminal diameterX174 mutants with maximum genome sizes.

The bacteriophage phi X174 strain ins6 constructed previously was used to investigate the maximum genome size that could be packaged into the icosahedral phage without concomitant loss of phage viability. The J-F intercistronic region of ins6, which already contains an insert of 117 base pairs with a unique PvuII site, was enlarged further by insertion of HaeIII restriction fragments of the plasmid pBR322 into that PvuII site. By using a biochemical approach for the site-specific mutagenesis as well as selection of mutant genomes, a series of mutants was isolated with genomes of up to 5,730 nucleotides, 6.4% larger than that of the wild-type DNA. Phages with genomes larger than 5,550 nucleotides were highly unstable and were rapidly outgrown by spontaneously occurring deletion mutants. The data predict that genomes of at least 6,090 nucleotides could be constructed and, most likely, packaged, but the resulting phages would not grow well. We speculate that the volume of the phage capsid is not the limiting factor of genome size or is not the only limiting factor.     

Of statistics and genomes

Higher organisms have more genes and larger genomes than simple organisms. This statement sounds almost too trivial to ask the question: why? But there are at least two different answers. Either there is an inherent necessity to increase genome size when more complexity is required or genome size increases because of other reasons that then enable complexity to "latch on". Recently, an article by Lynch and Conery, which used arguments of evolutionary population dynamics, proposed that low population size leads to larger genomes. This then provides the opportunity to generate more complex organisms.     

Single-cell enabled comparative genomics of a deep ocean SAR11 bathytype

Bacterioplankton of the SAR11 clade are the most abundant microorganisms in marine systems, usually representing 25% or more of the total bacterial cells in seawater worldwide. SAR11 is divided into subclades with distinct spatiotemporal distributions (ecotypes), some of which appear to be specific to deep water. Here we examine the genomic basis for deep ocean distribution of one SAR11 bathytype (depth-specific ecotype), subclade Ic. Four single-cell Ic genomes, with estimated completeness of 55%–86%, were isolated from 770 m at station ALOHA and compared with eight SAR11 surface genomes and metagenomic datasets. Subclade Ic genomes dominated metagenomic fragment recruitment below the euphotic zone. They had similar COG distributions, high local synteny and shared a large number (69%) of orthologous clusters with SAR11 surface genomes, yet were distinct at the 16S rRNA gene and amino-acid level, and formed a separate, monophyletic group in phylogenetic trees. Subclade Ic genomes were enriched in genes associated with membrane/cell wall/envelope biosynthesis and showed evidence of unique phage defenses. The majority of subclade Ic-specfic genes were hypothetical, and some were highly abundant in deep ocean metagenomic data, potentially masking mechanisms for niche differentiation. However, the evidence suggests these organisms have a similar metabolism to their surface counterparts, and that subclade Ic adaptations to the deep ocean do not involve large variations in gene content, but rather more subtle differences previously observed deep ocean genomic data, like preferential amino-acid substitutions, larger coding regions among SAR11 clade orthologs, larger intergenic regions and larger estimated average genome size.     

Tracing the evolution of gene loss in obligate bacterial symbionts

The gamma-proteobacterial symbionts of insects are a model group for comparative studies of genome reduction. The phylogenetic proximity of these reduced genomes to the larger genomes of well-studied free-living bacteria has enabled reconstructions of the process by which genes and DNA are lost. Three genome sequences are now available for Buchnera aphidicola. Analyses of Buchnera genomes in comparison with those of related enteric bacteria suggest that extensive changes including large deletions, repetitive element proliferation and chromosomal rearrangements occurred initially, followed by extreme stasis in gene order and slow decay of additional genes. This pattern appears to be characteristic of symbiont evolution.     

REVIEW—CONTRASTING MITOCHONDRIAL GENOME ORGANIZATIONS AND SEQUENCE AFFILIATIONS AMONG GREEN ALGAE: POTENTIAL FACTORS, MECHANISMS, AND EVOLUTIONARY SCENARIOS

The three green algal mitochondrial genomes completely sequenced to date — those of Chlamydomonas reinhardtii Dangeard, Chlamydomonas eugametos Gerloff, and Prototheca wickerhamii Soneda & Tubaki — revealed very different mitochondrial genome organizations and sequence affiliations. The Chlamydomonas genomes resemble the ciliate / fungal / animal counterparts, and the Prototheca genome resembles land plant homologues. This review points out that all the green algal mitochondrial genomes examined to date resemble either the Chlamydomonas or the Prototheca mitochondrial genome; the Chlamydomonas- like mitochondrial genomes are small and have a reduced gene content (no ribosomal protein or 5S rRNA genes and only a few protein-coding and tRNA genes) and fragmented and scrambled rRNA coding regions, whereas the Prototheca- like mitochondrial genomes are larger and have a larger set of protein-coding genes (including ribosomal protein genes), more tRNA genes, and 5S rRNA and conventional continuous small-subunit (SSU) and large-subunit (LSU) rRNA coding regions. It appears, therefore, that the differences previously observed between the mitochondrial genomes of C. reinhardtii and P. wickerhamii extend to the two green algal mitochondrial lineages to which they belong and are significant enough to raise questions about the causes and mechanisms responsible for such contrasting evolutionary strategies among green algae. This review suggests an integrative approach in explaining the occurrence of distinct evolutionary strategies and apparent phylogenetic affiliations among the known green algal mitochondrial lineages. The observed differences could be the result of distinct genetic potentials differentiated during the previous evolutionary history of the flagellate ancestors and / or of subsequent changes in habitat and life history of the more advanced green algal lineages.     

Viruses, masters at downsizing

Viruses are the smallest fruits on the tree of life. Dwarfed by their bacterial and cellular hosts, viruses and their close relatives have long been considered the smallest microbes. The genome of a virus may contain no more than three thousand nucleotides, compared to the three billion base pairs in human genomes. (Lest we feel superior, though, the genomes of some other organisms are much larger than our own.).     

Estimating the number of protein folds and families from complete genome data

Using the data on proteins encoded in complete genomes, combined with a rigorous theory of the sampling process, we estimate the total number of protein folds and families, as well as the number of folds and families in each genome. The total number of folds in globular, water- soluble proteins is estimated at about 1000, with structural information currently available for about one-third of the number. The sequenced genomes of unicellular organisms encode from approximately 25%, for the minimal genomes of the Mycoplasmas, to 70-80% for larger genomes, such as Escherichia coli and yeast, of the total number of folds. The number of protein families with significant sequence conservation was estimated to be between 4000 and 7000, with structures available for about 20% of these.     

Genome-wide profile of oxidoreductases in viruses, prokaryotes, and eukaryotes

Enzymes that utilize nicotinamide adenine dinucleotide (NAD) or its 2'-phosphate derivative (NADP) are found throughout the kingdoms of life. These enzymes are fundamental to many biochemical pathways, including central intermediary metabolism and mechanisms for cell survival and defense. The complete genomes of 25 organisms representing bacteria, protists, fungi, plants, and animals, and 811 viruses, were mined to identify and classify NAD(P)-dependent enzymes. An average of 3.4% of the proteins in these genomes was categorized as NAD(P)-utilizing proteins, with highest prevalence in the medium-chain oxidoreductase and short-chain oxidoreductase families. In general, the distribution of these enzymes by oxidoreductase family was correlated to the number of different catalytic mechanisms in each family. Organisms with smaller genomes encoded a larger proportion of NAD(P)-dependent enzymes in their proteome (approximately 6%) as compared to the larger genomes of eukaryotes (approximately 3%). Among viruses, those with large, double-strand DNA genomes were shown to encode oxidoreductases. Gram-positive and gram-negative bacteria showed some differences in the distribution of NAD(P)-dependent proteins. Several organisms such as M. tuberculosis, P. falciparum, and A. thaliana showed unique distributions of oxidoreductases corresponding to some phenotypic features.     

Insertion bias and purifying selection of retrotransposons in the <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>genome

Background  

Genome evolution and size variation in multicellular organisms are profoundly influenced by the activity of retrotransposons. In higher eukaryotes with compact genomes retrotransposons are found in lower copy numbers than in larger genomes, which could be due to either suppression of transposition or to elimination of insertions, and are non-randomly distributed along the chromosomes. The evolutionary mechanisms constraining retrotransposon copy number and chromosomal distribution are still poorly understood.     

Application of the RLGS Method to Large-Size Genomes Using a Restriction Trapper

We developed a method for producing restriction landmark genomicscanning (RLGS) profiles of large size genomes, such as thoseof higher plants or amphibians using a restriction trapper.Use of the conventional RLGS method is limited to genomes smallerthan 3 x 10⁹ bp, because the larger genomic DNAs, especiallythose of more than 1 x 10¹⁰ bp, produce high background dueto incorporation of radioactivity at non-specifically damagedsites. Our new method reduces the background levels by reducinggenome complexity to 1/200–1/300 using a purificationstep to enrich DNA fragments carrying specific restriction landmarksat their ends using a restriction trapper. This step makes itpossible to obtain RLGS patterns of larger genomes. Our paperdescribes the practical application for the RLGS method usinga restriction trapper with the pine tree genome (3 x 10¹⁰ bp/haploidgenome; Pinus koraiensis Sieb. et Zucc.) as an example.     

Coevolution between simple sequence repeats (SSRs) and virus genome size

ABSTRACT: BACKGROUND: Relationship between the level of repetitiveness in genomic sequence and genome size has been investigated by making use of complete prokaryotic and eukaryotic genomes, but relevant studies have been rarely made in virus genomes. RESULTS: In this study, a total of 257 viruses were examined, which cover 90% of genera. The results showed that simple sequence repeats (SSRs) is strongly, positively and significantly correlated with genome size. Certain repeat class is distributed in a certain range of genome sequence length. Mono-, di- and tri- repeats are widely distributed in all virus genomes, tetra- SSRs as a common component consist in genomes which more than 100 kb in size; in the range of genome < 100 kb, genomes containing penta- and hexa- SSRs are not more than 50%. Principal components analysis (PCA) indicated that dinucleotide repeat affects the differences of SSRs most strongly among virus genomes. Results showed that SSRs tend to accumulate in larger virus genomes; and the longer genome sequence, the longer repeat units. CONCLUSIONS: We conducted this research standing on the height of the whole virus. We concluded that genome size is an important factor in affecting the occurrence of SSRs; hosts are also responsible for the variances of SSRs content to a certain degree.     

The structure of the small mitochondrial DNA of Kluyveromyces thermotolerans is likely to reflect the ancestral gene order in fungi

Mapping the 23-kb circular mitochondrial DNA from the yeast Kluyveromyces thermotolerans has shown that only one change occurs in the gene order in comparison to the 19-kb mtDNA of Candida (Torulopsis) glabrata. Sequence analysis of the mitochondrially encoded cytochrome oxidase subunit 2 gene reveals that despite their conserved gene order, the two small genomes are more distantly related than larger mtDNA molecules with multiple rearrangements. This result supports a previous observation that larger mitochondrial genomes are more prone to rearrange than smaller forms and suggests that the architecture of the two small molecules is likely to represent the structure of an ancestor.Correspondence to: G.D. Clark-Walker 0592