Retroposons in modern human genome evolution

The ascertainment of the rates and driving forces of human genome evolution along with the genetic diversity of populations or separate population groups remains a topical problem of fundamental and applied genomics. According to the results of comparative analysis, the most numerous human genome structure peculiarities are connected with the distribution of mobile genetic retroelements—LTR, LINE1, SVA, and Alu repeats. Due to the wide distribution in different genome loci, conversed retropositional activity, and the retroelements’ regulatory potential, let us regard them as one of the significant evolutionary driving forces and the source of human genome variability. In the current review, we summarize published data and recent results of our research aimed at the analysis of the evolutionary impact of the young retroelements group on the function and variability of the human genome. We examine modern approaches of the polygenomic identification of polymorphic retroelements inserts. Using an original Internet resource, we analyze special features of the genomic polymorphic inserts of AluY repeats. We thoroughly characterize the strategy of large-scale functional analysis of polymorphic retroelement inserts. The presented results confirm the hypothesis of the roles of retroelements as active cis regulatory elements that are able to modulate surrounding genes.     

An ancient solution to a modern problem

The dearth of new antibiotics and escalating emergence of multidrug resistant bacteria have created a global healthcare crisis and highlight the drastic need for novel antimicrobial agents. Complementary and alternative strategies including the investigation of ancient medicinals could address this problem. Natural clay minerals with a long history of medicinal and biomedical applications have become an interest due to their broad-spectrum antimicrobial activity. Such untapped natural sources may provide new therapeutic agents in the battle against infectious diseases in the post-antibiotic era.     

The evolution of the chemical isotopes as an analog of biological evolution

A comparison is made between a biological adaptive landscape and the chemical isotopic landscape defined with three dimensions: the number of protons, the number of neutrons, and the stability of each isotopic nucleus. The courses of both biological and elemental evolution have been stochastic, leading from the simple to the complex; this is in agreement with statistical thermodynamic predictions. Analogs of mutation and natural selection occur in elementary evolution. The isotopic landscape can be assumed to have an a priori existence; at least the general features of the biological adaptive landscape also have an a priori existence. Both landscapes were occupied by spontaneous processes, analogous to diffusion.     

Pathocoenoses ancient and modern

Problems concerning the concept of biocoenosis in ecology (the antecedent of the pathocoenosis concept) are discussed first of all. Six main problems are identified: the problem of emergent properties of ecological communities; the problem of ambiguity; the problem of heterogeneity; the boundary problem; the problem of retrospective differential diagnosis; and the problem of explaining change over time. The rest of the paper gives illustrations of these problems in relation to human pathogens drawn mainly from the interactions of malaria with other diseases, particularly but not exclusively in the Mediterranean world, from antiquity through to modern times.     

Flexible genomic islands as drivers of genome evolution

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In silico archeogenomics unveils modern plant genome organisation, regulation and evolution

Increasing access to plant genome sequences as well as high resolution gene-based genetic maps have recently offered the opportunity to compare modern genomes and model their evolutionary history from their reconstructed founder ancestors on an unprecedented scale. In silico paleogenomic data have revealed the evolutionary forces that have shaped present-day genomes and allowed us to gain insight into how they are organised and regulated today.     

古今演变中的云南植物若干特点探讨

云南的独特地理位置、地质历史、地形地貌和和季风气候环境等起源于印度板块与欧亚大陆碰撞并插入所产生的青藏高原隆起与古地中海西退。在这个从古到今演变的舞台上,云南不仅成为“植物王国”,而且形成了一些重要的特点。云南既是东亚、东南亚和东喜马拉雅等植物区系的交汇区,又是欧亚大陆植物区系与赤道热带的唯一陆地交流通道;它们既有丰富的古老、孑遗植物,又有数量处于我国榜首的特有分类群;在横断山区这个新分类群分布和演化中心中,新分类群的分布格局与其原始类群的起源密切相关。此外,由于地质历史变迁、第四纪冰期影响和山地垂直变化等,使云南的很多植物具有较多的生态遗传型和较强的生态适应性。     

Hox clusters as models for vertebrate genome evolution

The surprising variation in the number of Hox clusters and the genomic architecture within vertebrate lineages, especially within the ray-finned fish, reflects a history of duplications and subsequent lineage-specific gene loss. Recent research on the evolution of conserved non-coding sequences (CNS) in Hox clusters promises to reveal interesting results for functional and phenotypic diversification.     

The evolution of mitochondrial genomes in modern frogs (Neobatrachia): nonadaptive evolution of mitochondrial genome reorganization

Background

Although mitochondrial (mt) gene order is highly conserved among vertebrates, widespread gene rearrangements occur in anurans, especially in neobatrachians. Protein coding genes in the mitogenome experience adaptive or purifying selection, yet the role that selection plays on genomic reorganization remains unclear. We sequence the mitogenomes of three species of Glandirana and hot spots of gene rearrangements of 20 frog species to investigate the diversity of mitogenomic reorganization in the Neobatrachia. By combing these data with other mitogenomes in GenBank, we evaluate if selective pressures or functional constraints act on mitogenomic reorganization in the Neobatrachia. We also look for correlations between tRNA positions and codon usage.

Results

Gene organization in Glandirana was typical of neobatrachian mitogenomes except for the presence of pseudogene trnS (AGY). Surveyed ranids largely exhibited gene arrangements typical of neobatrachian mtDNA although some gene rearrangements occurred. The correlation between codon usage and tRNA positions in neobatrachians was weak, and did not increase after identifying recurrent rearrangements as revealed by basal neobatrachians. Codon usage and tRNA positions were not significantly correlated when considering tRNA gene duplications or losses. Change in number of tRNA gene copies, which was driven by genomic reorganization, did not influence codon usage bias. Nucleotide substitution rates and d_N/d_S ratios were higher in neobatrachian mitogenomes than in archaeobatrachians, but the rates of mitogenomic reorganization and mt nucleotide diversity were not significantly correlated.

Conclusions

No evidence suggests that adaptive selection drove the reorganization of neobatrachian mitogenomes. In contrast, protein-coding genes that function in metabolism showed evidence for purifying selection, and some functional constraints appear to act on the organization of rRNA and tRNA genes. As important nonadaptive forces, genetic drift and mutation pressure may drive the fixation and evolution of mitogenomic reorganizations.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-691) contains supplementary material, which is available to authorized users.     

The emergence of molecular machines as a prerequisite of the ancient RNA world evolution

The problem of the start of biological evolution in the ancient RNA world is considered. It is postulated that the appearance of catalytic RNAs — ribozymes — via spontaneous cis- and trans-rearrangements of polyribonucleotides in primordial Darwin ponds should not have been sufficient for the start of evolution, until a new class of functional RNA, namely energy-dependent molecular machines, arose. The proposed hypothesis is that the simplest and primary type of molecular machines could be nucleoside triphosphate-dependent RNA-based helicases, which were capable of unwinding the stable double-helical RNAs inevitably formed during RNA syntheses on complementary templates. Thereupon, unwinding RNA polymerases could appear as a result of association or fusion of helicases and polyribonucleotide-polymerizing ribozymes. The latter event provided the mechanism of RNA replication using the double-helical RNAs as a communal genofond (gene pool) of a Darwin pond, and thus initiated the fast evolution of the ancient RNA world.     

Classical catalase: ancient and modern

This review describes the historical difficulties in devising a kinetically satisfactory mechanism for the classical catalase after its identification as a unique catalytic entity in 1902 and prior to the breakthrough 1947 analysis by Chance and co-workers which led to the identification of peroxide compounds I and II. The role of protons in the formation of these two ferryl complexes is discussed and current problems of inhibitory ligand and hydrogen donor binding at the active site are outlined, especially the multiple roles involving formate or formic acid. A previous mechanism of NADPH-dependent catalase protection against substrate inhibition is defended. A revised model linking the catalytic ('catalatic') action and the one-electron side reactions involving compound II is suggested. And it is concluded that, contrary to an idea proposed in 1963 that eukaryotic catalase might be a 'fossil enzyme', current thinking gives it a central role in the redox protective processes of long term importance for human and other eukaryotic and prokaryotic life.     

Microbiology of ancient and modern hydrothermal systems

Hydrothermal systems have prevailed throughout geological history on earth, and ancient ARCHAEAN hydrothermal deposits could provide clues to understanding earth's earliest biosphere. Modern hydrothermal systems support a plethora of microorganisms and macroorganisms, and provide good comparisons for paleontological interpretation of ancient hydrothermal systems. However, all of the microfossils associated with ancient hydrothermal deposits reported to date are filamentous, and limited STABLE ISOTOPE analysis suggests that these microfossils were probably autotrophs. Therefore, the morphology and mode of carbon metabolism are attributes of microorganisms from modern hydrothermal systems that provide valuable information for interpreting the geological record using morphological and isotopic signatures.     

Biological evolution and ancient DNA

Twenty years after the advent of ancient DNA studies, this discipline seems to have reached the maturity formerly lacking to the fulfilment of its objectives. In its early development paleogenetics, as it is now acknowledged, had to cope with very limited data due to the technical limitations of molecular biology. It led to phylogenetic assumptions often limited in their scope and sometimes non-focused or even spurious results that cast the reluctance of the scientific community. This time seems now over and huge amounts of sequences have become available which overcome the former limitations and bridge the gap between paleogenetics, genomics and population biology. The recent studies over the charismatic woolly mammoth (independent sequencing of the whole mitochondrial genome and of millions of base pairs of the nuclear genome) exemplify the growing accuracy of ancient DNA studies thanks to new molecular approaches. From the earliest publications up to now, the number of mammoth nucleotides was multiplied by 100,000. Likewise, populational approaches of ice-age taxa provide new historical scenarios about the diversification and extinction of the Pleistocene megafauna on the one hand, and about the processes of domestication of animal and vegetal species by Man on the other. They also shed light on the differential structure of molecular diversity between short-term populational research (below 2 My) and long-term (over 2 My) phylogenetic approaches. All those results confirm the growing importance of paleogenetics among the evolutionary biology disciplines.