Linkage and the elimination of deleterious mutant genes from experimental populations

The behavior of a balanced lethal system and its two component loci was examined in laboratory populations of the flour beetle,Tribelium castaneum. The two lethal genes wereShort antenna (Sa), a dominant morphological mutant which is a recessive lethal when homozygous, and a lethal (l) located 1 to 2 map units fromSa in linkage group VII.Frequencies of both lethals declined rapidly when present individually in populations. The elimination curve forl closely paralleled the theoretical curve for a recessive lethal;Sa was eliminated more rapidly, indicating that heterozygotes also suffer a reduced fitness relative to wild-type homozygotes. These observations were corroborated by measurements of several components of fitness.When populations were initiated with the two lethals in repulsion phase, marked differences were observed in the rate of elimination ofSa in six replicate populations. Since the initial phase of elimination depends on the occurrence of an effective crossover between the two loci, it was possible to apply a correction factor so that the observed elimination curve closely approximated a theoretical curve generated using parameters obtained from the assays of fitness components.It is argued that many cases of apparently intermediate gene frequency equilibrium reported in studies withTribolium and also withDrosophila result from linkage disequilibrium rather than overdominance. The data presented provide a striking example of the effects of linkage on the elimination of mutant genes from experimental populations.     

Repeated sequences in the DNA of the eukaryotic genome

Long DNA molecules from a cucumber satellite, the cucumber main band, mung bean, and Chinese hamster ovary (CHO) were digested with mung bean nuclease I, which was used as a probe for high AT regions. The digests were viewed under the electron microscope, and the distribution of sizes for the fragments of nuclease-treated plant DNA showed that the main band cucumber and the mung bean have regions along their genomes spaced at approximately 0.3 to 0.4 μ that are sensitive to the nuclease. The satellite from the cucumber contains these sites at intervals generally of 0.1 μ or less, whereas CHO DNA has these regions at intervals of 0.05 to 1.40 μ in length. The long DNA from the main band of the cucumber and the CHO were also partially melted in formamide at 37°C to denature preferentially the regions along the DNA molecules that are rich in AT. Measurements of the distances from the center of each loop to the center of the adjacent loops showed that these distances for the main band cucumber DNA tended to occur at approximately every 0.4 μ, whereas the corresponding distances for the Chinese hamster DNA were less regular, occurring every 0.1 to 1.0 μ.     

Dynamics of genome rearrangement in bacterial populations

Genome structure variation has profound impacts on phenotype in organisms ranging from microbes to humans, yet little is known about how natural selection acts on genome arrangement. Pathogenic bacteria such as Yersinia pestis, which causes bubonic and pneumonic plague, often exhibit a high degree of genomic rearrangement. The recent availability of several Yersinia genomes offers an unprecedented opportunity to study the evolution of genome structure and arrangement. We introduce a set of statistical methods to study patterns of rearrangement in circular chromosomes and apply them to the Yersinia. We constructed a multiple alignment of eight Yersinia genomes using Mauve software to identify 78 conserved segments that are internally free from genome rearrangement. Based on the alignment, we applied Bayesian statistical methods to infer the phylogenetic inversion history of Yersinia. The sampling of genome arrangement reconstructions contains seven parsimonious tree topologies, each having different histories of 79 inversions. Topologies with a greater number of inversions also exist, but were sampled less frequently. The inversion phylogenies agree with results suggested by SNP patterns. We then analyzed reconstructed inversion histories to identify patterns of rearrangement. We confirm an over-representation of "symmetric inversions"-inversions with endpoints that are equally distant from the origin of chromosomal replication. Ancestral genome arrangements demonstrate moderate preference for replichore balance in Yersinia. We found that all inversions are shorter than expected under a neutral model, whereas inversions acting within a single replichore are much shorter than expected. We also found evidence for a canonical configuration of the origin and terminus of replication. Finally, breakpoint reuse analysis reveals that inversions with endpoints proximal to the origin of DNA replication are nearly three times more frequent. Our findings represent the first characterization of genome arrangement evolution in a bacterial population evolving outside laboratory conditions. Insight into the process of genomic rearrangement may further the understanding of pathogen population dynamics and selection on the architecture of circular bacterial chromosomes.     

Extreme genome reduction in symbiotic bacteria

Since 2006, numerous cases of bacterial symbionts with extraordinarily small genomes have been reported. These organisms represent independent lineages from diverse bacterial groups. They have diminutive gene sets that rival some mitochondria and chloroplasts in terms of gene numbers and lack genes that are considered to be essential in other bacteria. These symbionts have numerous features in common, such as extraordinarily fast protein evolution and a high abundance of chaperones. Together, these features point to highly degenerate genomes that retain only the most essential functions, often including a considerable fraction of genes that serve the hosts. These discoveries have implications for the concept of minimal genomes, the origins of cellular organelles, and studies of symbiosis and host-associated microbiota.     

The genome of alpha-proteobacteria : complexity, reduction, diversity and fluidity

The alpha-proteobacteria displayed diverse and often unconventional life-styles. In particular, they keep close relationships with the eucaryotic cell. Their genomic organization is often atypical. Indeed, complex genomes, with two or more chromosomes that could be linear and sometimes associated with plasmids larger than one megabase, have been described. Moreover, polymorphism in genome size and topology as well as in replicon number was observed among very related bacteria, even in a same species. Alpha-proteobacteria provide a good model to study the reductive evolution, the role and origin of multiple chromosomes, and the genomic fluidity. The amount of new data harvested in the last decade should lead us to better understand emergence of bacterial life-styles and to build the conceptual basis to improve the definition of the bacterial species.     

Nested genes in the human genome

Here we studied one special type of gene, i.e., the nested gene, in the human genome. We collected 373 reliably annotated nested genes. Two-thirds of them were on the strand opposite that of their host gene. About 58% coding nested gene pairs were conserved in mouse and some were even maintained in chicken and fish, while nested pseudogenes were poorly conserved. Ka/Ks analysis revealed that nested genes were under strong selection, although they did not demonstrate greater conservation than other genes. With microarray data we observed that two partners of one nested pair seemed to be expressed reciprocally. A significant proportion of nested genes were tissue-specifically expressed. Gene ontology analysis demonstrated that quite a number of nested genes participated in cellular signal transduction. Based on these observations, we think that nested genes are a group of genes with important physiological functions.     

Neutral and selection-driven decay of sexual traits in asexual stick insects

Environmental shifts and lifestyle changes may result in formerly adaptive traits becoming non-functional or maladaptive. The subsequent decay of such traits highlights the importance of natural selection for adaptations, yet its causes have rarely been investigated. To study the fate of formerly adaptive traits after lifestyle changes, we evaluated sexual traits in five independently derived asexual lineages, including traits that are specific to males and therefore not exposed to selection. At least four of the asexual lineages retained the capacity to produce males that display normal courtship behaviours and are able to fertilize eggs of females from related sexual species. The maintenance of male traits may stem from pleiotropy, or from these traits only regressing via drift, which may require millions of years to generate phenotypic effects. By contrast, we found parallel decay of sexual traits in females. Asexual females produced altered airborne and contact signals, had modified sperm storage organs, and lost the ability to fertilize their eggs, impeding reversals to sexual reproduction. Female sexual traits were decayed even in recently derived asexuals, suggesting that trait changes following the evolution of asexuality, when they occur, proceed rapidly and are driven by selective processes rather than drift.     

Repeated secondary loss of adaptin complex genes in the Apicomplexa

The Apicomplexa include parasites of devastating medical and economic consequence. While obviously essential for their parasitic mechanism, the molecular machinery underpinning membrane-trafficking in many apicomplexans is poorly understood. One potentially key set of players, the adaptins, selects cargo for incorporation into trafficking vesicles. Four distinct adaptin (AP) complexes exist in eukaryotes; AP1 and AP3 are involved in transport between the trans-Golgi Network (TGN) and endosomes, AP4 in TGN to cell surface transport, and AP2 in endocytosis from the cell surface. Of particular interest is the involvement of AP1 in Toxoplasma rhoptry biogenesis. The recent completion of several apicomplexan genomes should jump-start molecular parasitological studies and provide systems-level insight into the apicomplexan adaptin machinery. However, many of the encoded adaptin proteins are annotated conservatively and not to the necessary complex or subunit level. Prompted by previous evidence suggesting the lack of AP3 in Plasmodium falciparum, we undertook homology-searching and phylogenetic analysis to produce a rigorously annotated set of adaptin subunits encoded in diverse apicomplexan genomes. We found multiple losses of adaptins across the phylum; in particular Theileria, Babesia, and Cryptosporidium, but surprisingly not Plasmodium, appear to have lost the entirety of the AP3 complex. The losses correlate with a degenerate Golgi body structure and are reminiscent of recently reported secondary losses of additional endocytic components (i.e. the ESCRTs) in several Apicomplexa. These data may indicate a relaxation of the selective pressure on the apicomplexan endocytic system and, regardless, should greatly facilitate future molecular cell biological investigation of the role of adaptins in these important parasites.     

Sex-linked genes in age-structured populations.

We study the progress towards equilibrium of the frequencies of sex-linked genes in elementary discrete time models of age-structured, overlapping generation populations. It is found that, if a finite upper age limit is assumed, the difference in the frequencies of an allele in males and females will oscillate as in the familiar non-overlapping generation models, although the oscillations may be irregular. Monotonic convergence of that difference, as found by Nagylaki (1975) in continuous-time overlapping generation models without age-structure, occurs in the models considered here only when there is no upper age limit and when there is "sufficient" overlap of generations.     

Repeated evolution of an acetate-crossfeeding polymorphism in long-term populations of Escherichia coli

Six out of 12 independent replicate populations of Escherichia coli maintained in long-term glucose-limited continuous culture for up to approximately 1,750 generations evolve polymorphisms maintained by acetate crossfeeding. In all cases, the acetate-crossfeeding phenotype is associated with semiconstitutive overexpression of acetyl CoA synthetase, which allows for the enhanced uptake of low levels of exogenous acetate. Mutations in the 5' regulatory region of the acetyl CoA synthetase locus are responsible for all the acetate crossfeeding phenotypes found. These changes were either transposable-element insertions or a single T-->A nucleotide substitution at position -93 relative to the acs gene translation start site.      

Microbial minimalism: genome reduction in bacterial pathogens

When bacterial lineages make the transition from free-living or facultatively parasitic life cycles to permanent associations with hosts, they undergo a major loss of genes and DNA. Complete genome sequences are providing an understanding of how extreme genome reduction affects evolutionary directions and metabolic capabilities of obligate pathogens and symbionts.     

The distribution of genes in the Drosophila genome

In the present work we show that in the Drosophila genome (which covers a 37-51% GC range at a DNA size of approx.50kb) a linear correlation holds between GC (or GC(3)50kb) genomic sequences embedding them. This correlation allows us to position the two compositional distributions of (a) coding sequences, and (b) of long DNA segments relative to each other and to calculate gene concentration across the compositional range of the Drosophila genome. Using this approach, we show that gene concentration increases with increasing GC of the regions embedding the genes, reaching a 7-fold higher level in the GC-richest regions compared with the GC-poorest regions. The gene distribution of the Drosophila genome is, therefore, similar to (although less striking than) that of the human genome, whereas it is very different from those of the Arabidopsis genome, which has about the same size as the Drosophila genome.     

Repeated sequences from theArabidopsis thaliana genome function as enhancers in transgenic tobacco

Sixteen segments ofArabidopsis thaliana DNA that function as enhancers in transgenic tobacco plants were isolated using the pROA97 enhancer cloning vehicle and library transformation ofNicotiana tabacum. The sequences were compared for AT content, homology, repeated motifs, and expression pattern in transgenicN. tabacum. The sequences were average with respect to the AT content ofA. thaliana DNA. They could be placed into seven homology groups. Five of the sequences are single-copy sequences. The remaining eleven sequences represent two homology groups. Homology Group I contains seven sequences with minor differences. Homology Group II contains four sequences with minor differences. Two repeated motifs were identified (5′-CCTCT-3′ and 5′-AAGGAT-3′). Both repeated motifs are found in other plant enhancers, and in the promoter region of the cauliflower mosaic virus 35S gene. In the 35S gene TATA region, the motifs can form two alternative stem-loop structures. The TATATAA sequence is located in the loop region of both stem-loop structures.     

Retention of cryptic genes in microbial populations

Cryptic genes are silenced genes that can still be reactivated by mutation.Since they can make no positive contribution to the fitness of theircarriers, it is not clear why many cryptic genes in microbial populationshave not degenerated into useless DNA sequences. Hall et al. (1983) havesuggested that cryptic genes have persisted because of occasional strongenvironmental selection for reactivated genes. The present mathematicalstudy supports their suggestion. It shows that a cryptic gene can beretained without having any selective advantage over a useless DNAsequence, if selection for the reactivated gene occasionally occurs for asubstantially long time.     

Distribution of miRNA genes in the pig genome

Background

Recent completion of swine genome may simplify the production of swine as a large biomedical model. Here we studied sequence and location of known swine miRNA genes, key regulators of protein-coding genes at the level of RNA, and compared them to human and mouse data to prioritize future molecular studies.

Results

Distribution of miRNA genes in pig genome shows no particular relation to different genomic features including protein coding genes - proportions of miRNA genes in intergenic regions, introns and exons roughly agree with the size of these regions in the pig genome. Our analyses indicate that host genes harbouring intragenic miRNAs are longer from other protein-coding genes, however, no important GO enrichment was found. Swine mature miRNAs show high sequence similarity to their human and mouse orthologues. Location of miRNA genes relative to protein-coding genes is also similar among studied species, however, there are differences in the precise position in particular intergenic regions and within particular hosts. The most prominent difference between pig and human miRNAs is a large group of pig-specific sequences (53% of swine miRNAs). We found no evidence that this group of evolutionary new pig miRNAs is different from old miRNAs genes with respect to genomic location except that they are less likely to be clustered.

Conclusions

There are differences in precise location of orthologues miRNA genes in particular intergenic regions and within particular hosts, and their meaning for coexpression with protein-coding genes deserves experimental studies. Functional studies of a large group of pig-specific sequences in future may reveal limits of the pig as a model organism to study human gene expression.

Electronic supplementary material

The online version of this article (doi:10.1186/s12863-015-0166-3) contains supplementary material, which is available to authorized users.     

The bat genome: GC-biased small chromosomes associated with reduction in genome size

Bats are distinct from other mammals in their small genome size as well as their high metabolic rate, possibly related to flight ability. Although the genome sequence has been published in two species, the data lack cytogenetic information. In this study, the size and GC content of each chromosome are measured from the flow karyotype of the mouse-eared bat, Myotis myotis (MMY). The smaller chromosomes are GC-rich compared to the larger chromosomes, and the relative proportions of homologous segments between MMY and human differ among the MMY chromosomes. The MMY genome size calculated from the sum of the chromosome sizes is 2.25 Gb, and the total GC content is 42.3 %, compared to human and dog with 41.0 and 41.2 %, respectively. The GC-rich small MMY genome is characterised by GC-biased smaller chromosomes resulting from preferential loss of AT-rich sequences. Although the association between GC-rich small chromosomes and small genome size has been reported only in birds so far, we show in this paper, for the first time, that the same phenomenon is observed in at least one group of mammals, implying that this may be a mechanism common to genome evolution in general.