Features of the structure and evolution of complex, tandemly organized Bsp-repeats in the fox genome. I. Structure and internal organization of the BamHI-dimer

A 1468 b.p. DNA BamHI-fragment homologous to the Bsp-repeat was isolated from the fox genome and sequenced. This fragment is an hierarchically arranged dimer. Its 734 b.p.-monomers consist of three subrepeats (SR), each 245 b.p. long, abundant with overlapping imperfect tandem repeats which in turn are rich in short direct related repeats (each 4-7 b.p. in size). The latters are mainly composed of AG, TG dinucleotides and their complements CT, CA. All subrepeats in the BamHI-dimer are flanked by motifs homologous to Jeffreys' sites. At certain points the sites are doubled. The above data allow to assume that the Bsp-repeat complex structure is likely to have developed throughout long multi-step evolution of relatively simple DNA sequences which had emerged de novo. Single substitutions, small inserts and deletions, multiple duplication and recombination events seem to have most contributed to the evolution of the Bsp-repeats. Single substitutions in SRs with respect to the consensus are not equally distributed along their length. A wave-like pattern of this distribution is the evidence for non-random character of mutations accumulation. A correspondence was noted between conservative regions in SR and the presence therein of functional motifs homologous to the binding sites of already known regulatory proteins.     

Organization of Bsp-repeats in the fox genome

Bsp repeats comprise approximately 1% of silver for total DNA and are preferentially localized in centromeric regions. Two of Bsp fragments cloned earlier, such as non-homologous rsV1 and rsV3, make up together a Bsp unit (680 bp) and possess a set of sites known to have regulatory functions in eucaryotic genomes. In this work, tandem organization of Bsp repeats is demonstrated. A stretched Bsp sequence (approximately 1460 bp, dimeric form) flanked by BamHI sites was cloned and its restriction map was plotted. With use of rsV1 and rsV3 probes the new sequence exhibited linked structure: rsV1-rsV3-rsV1-rsV3-rsV1. Blot-hybridization with the restriction fragments of fox total DNA suggested hierarchical order of Bsp clustes in the genome. It is supposed that the processes of selective amplification of individual fragments had been of real importance during evolution of Bsp repeats.     

Species-specific features of the distribution of restriction sites in Bsp-repeats of Canidae genome]

Differences and similarities of the Bsp-repeats' organization in fox, dog, polar fox and raccoon dog genomes were studied. Specificity of Bsp-repeats to the Canidae family was demonstrated. The repeats are mainly organized in large clusters in all species studied. The species-specific features in restriction patterns were revealed for all five genomes, in spite of high intragenomic polymorphism exhibited in each case. This suggests that certain unique sets of structural versions of Bsp-repeats were fixed in canid genomes by amplification during the process of speciation. Fox and polar fox exhibited the highest similarity in restriction patterns of Bsp-repeats. Raccoon dog pattern is most unusual among others: its distinguishable character is the absence of large multimeric series. The EcoRI hydrolysate of raccoon dog Bsp-repeats consists mainly of one band corresponding to 1600 bp. These are in accordance with phylogenetic relations between canids.     

Complex prokaryotic genome structure: rapid evolution of chromosome II

Although many bacteria with two chromosomes have been sequenced, the roles of such complex genome structuring are still unclear. To uncover levels of chromosome I (CI) and chromosome II (CII) sequence divergence, Mauve 2.2.0 was used to align the CI- and CII-specific sequences of bacteria with complex genome structuring in two sets of comparisons: the first set was conducted among the CI and CII of bacterial strains of the same species, while the second set was conducted among the CI and CII of species in Alphaproteobacteria that possess two chromosomes. The analyses revealed a rapid evolution of CII-specific DNA sequences compared with CI-specific sequences in a majority of organisms. In addition, levels of protein divergence between CI-specific and CII-specific genes were determined using phylogenetic analyses and confirmed the DNA alignment findings. Analysis of synonymous and nonsynonymous substitutions revealed that the structural and functional constraints on CI and CII genes are not significantly different. Also, horizontal gene transfer estimates in selected organisms demonstrated that CII in many species has acquired higher levels of horizontally transferred segments than CI. In summary, rapid evolution of CII may perform particular roles for organisms such as aiding in adapting to specialized niches.     

Chromatin structure and evolution in the human genome

Background  

Evolutionary rates are not constant across the human genome but genes in close proximity have been shown to experience similar levels of divergence and selection. The higher-order organisation of chromosomes has often been invoked to explain such phenomena but previously there has been insufficient data on chromosome structure to investigate this rigorously. Using the results of a recent genome-wide analysis of open and closed human chromatin structures we have investigated the global association between divergence, selection and chromatin structure for the first time.     

Genome mapping in capsicum and the evolution of genome structure in the solanaceae.

We have created a genetic map of Capsicum (pepper) from an interspecific F2 population consisting of 11 large (76.2-192.3 cM) and 2 small (19.1 and 12.5 cM) linkage groups that cover a total of 1245.7 cM. Many of the markers are tomato probes that were chosen to cover the tomato genome, allowing comparison of this pepper map to the genetic map of tomato. Hybridization of all tomato-derived probes included in this study to positions throughout the pepper map suggests that no major losses have occurred during the divergence of these genomes. Comparison of the pepper and tomato genetic maps showed that 18 homeologous linkage blocks cover 98.1% of the tomato genome and 95.0% of the pepper genome. Through these maps and the potato map, we determined the number and types of rearrangements that differentiate these species and reconstructed a hypothetical progenitor genome. We conclude there have been 30 breaks as part of 5 translocations, 10 paracentric inversions, 2 pericentric inversions, and 4 disassociations or associations of genomic regions that differentiate tomato, potato, and pepper, as well as an additional reciprocal translocation, nonreciprocal translocation, and a duplication or deletion that differentiate the two pepper mapping parents.     

SINEs, evolution and genome structure in the opossum

Short INterspersed Elements (SINEs) are non-autonomous retrotransposons, usually between 100 and 500 base pairs (bp) in length, which are ubiquitous components of eukaryotic genomes. Their activity, distribution, and evolution can be highly informative on genomic structure and evolutionary processes. To determine recent activity, we amplified more than one hundred SINE1 loci in a panel of 43 M. domestica individuals derived from five diverse geographic locations. The SINE1 family has expanded recently enough that many loci were polymorphic, and the SINE1 insertion-based genetic distances among populations reflected geographic distance. Genome-wide comparisons of SINE1 densities and GC content revealed that high SINE1 density is associated with high GC content in a few long and many short spans. Young SINE1s, whether fixed or polymorphic, showed an unbiased GC content preference for insertion, indicating that the GC preference accumulates over long time periods, possibly in periodic bursts. SINE1 evolution is thus broadly similar to human Alu evolution, although it has an independent origin. High GC content adjacent to SINE1s is strongly correlated with bias towards higher AT to GC substitutions and lower GC to AT substitutions. This is consistent with biased gene conversion, and also indicates that like chickens, but unlike eutherian mammals, GC content heterogeneity (isochore structure) is reinforced by substitution processes in the M. domestica genome. Nevertheless, both high and low GC content regions are apparently headed towards lower GC content equilibria, possibly due to a relative shift to lower recombination rates in the recent Monodelphis ancestral lineage. Like eutherians, metatherian (marsupial) mammals have evolved high CpG substitution rates, but this is apparently a convergence in process rather than a shared ancestral state.     

Isolated clusters of paired tandemly repeated sequences in the Xenopus laevis genome.

There exist in the Xenopus laevis genome clusters of tandemly repeated DNA sequences, consisting of two types of 393-base-pair repeating unit. Each such cluster contains several units of one of these paired tandem repeats (PTR-1), followed by several units of the other repeat (PTR-2). The number of repeats of each type is variable from cluster to cluster and averages about seven of each type per cluster. Every cluster has ca. 1,000 base pairs of common left flanking sequence (adjacent to the PTR-1 repeats) and 1,000 base pairs of common right flanking sequence (adjacent to the PTR-2 repeats). Beyond these common flanks, the DNA sequences are different in the eight cloned genomic fragments we have studied. Thus, the hundreds of PTR clusters in the genome are dispersed at apparently unrelated sites. Nucleotide sequences of representative PTR-1 and PTR-2 repeats are 64% homologous. These sequences do not reveal an obvious function. However, the related species X. mulleri and X. borealis have sequences homologous to PTR-1 and PTR-2, which show the same repeat lengths and genomic organization. This evolutionary conservation suggests positive selection for the clusters. Maintenance of these sequences at dispersed sites imposes constraints on possible mechanisms of concerted evolution.     

Tandem DNA repeats in the vertebrate genome: structure, possible mechanisms of formation and evolution]

Possible models for the generation and the evolution of tandem repeats are discussed. The model of A.J. Jeffreys and co-workers as well as facts, supporting or contradicting this model are discussed. Facts supporting the hypothesis of the generation of the tandem repeats as the result of mitotic recombination are described. On the basis of an analysis of the structure of the tandem repeats containing loci, it is supposed that there exist space and time relations between the multimerization of the tandem repeats and tandem gene duplication. On the basis of this supposition, the generation of majority of the tandem repeated gene as a result of sister chromatids recombination in mitosis is proposed. Factors determining the existence of recombination hotspots of are discussed. Some specific features of the evolution of tandem repeats of the coding region are also described.     

The evolution of chloroplast genome structure in ferns

The plastid genome (plastome) is a rich source of phylogenetic and other comparative data in plants. Most land plants possess a plastome of similar structure. However, in a major group of plants, the ferns, a unique plastome structure has evolved. The gene order in ferns has been explained by a series of genomic inversions relative to the plastome organization of seed plants. Here, we examine for the first time the structure of the plastome across fern phylogeny. We used a PCR-based strategy to map and partially sequence plastomes. We found that a pair of partially overlapping inversions in the region of the inverted repeat occurred in the common ancestor of most ferns. However, the ancestral (seed plant) structure is still found in early diverging branches leading to the osmundoid and filmy fern lineages. We found that a second pair of overlapping inversions occurred on a branch leading to the core leptosporangiates. We also found that the unique placement of the gene matK in ferns (lacking a flanking intron) is not a result of a large-scale inversion, as previously thought. This is because the intron loss maps to an earlier point on the phylogeny than the nearby inversion. We speculate on why inversions may occur in pairs and what this may mean for the dynamics of plastome evolution.     

Rectification of tandemly repetitious DNA. II. Clustering and periodicity

In a given segment of tandemly repetitious DNA, the repeating units are similar but not always identical. Current techniques in molecular biology allow determination of whether variants are clustered or randomly interspersed along the segment. Such findings have been used as evidence for, or against, different models for internal rearrangement of the DNA, such as the rolling circle model or unequal sister chromatid exchange. Information has not been available, however, as to the extent to which observed patterns of clustering or interspersion are compatible with the different models. In the present study, computer simulations were used to obtain this information. As measured by certain indices of clustering and periodicity, each model generates a reproducible pattern that is relatively independent of the degree of heterogeneity in the segment.     

石松类和蕨类植物质体基因组结构演化研究进展

近年来, 随着测序技术的发展, 石松类和蕨类植物的核基因组、质体基因组以及线粒体基因组研究发展迅速, 质体基因组研究工作更是呈爆发式增长。截至2019年3月1日, GenBank公布的石松类和蕨类植物的175个质体基因组中, 约3/4为最近两年新增。研究内容从早期对个别质体基因组结构和序列特征的简单报道, 逐渐发展到综合性的比较基因组学和系统发育基因组学研究。目前已发表的质体基因组覆盖了石松类和蕨类植物的所有目和大部分科, 这两大类群的质体基因组结构变异和系统发育的基本框架已逐渐清晰。这些研究为我们理解维管植物的早期演化提供了重要参考。本文对石松类和蕨类植物的质体基因组结构特征进行了系统梳理, 发现其结构变异主要包括大片段倒位、IR区边界变动、基因或内含子丢失等, 其中一些结构变异可作为较高分类阶元的共衍征。RNA编辑和长片段非编码序列插入普遍存在于石松类和蕨类植物的质体基因组中, 但其起源、演化机制和功能等仍不清楚。我们对质体基因组的应用、系统发育研究中质体和核基因组的优劣性, 以及系统发育基因组学的前景进行了评述。     

Localization of binding sites in the hemoglobin-haptoglobin complex]

The binding and specific elution of Hb peptides from Hp was studied. Our results were confirmed by the study of inhibition of binding of alpha chains to Hp. In conclusion, a model of contact areas of Hp-Hb complex is proposed.     

Potential functional differentiation of genome in the course of evolution and approaches to its study. II. Elucidation of diversity of phylogenetic lines]

It has been shown elsewhere (Chupov, 2001) that the branching of phylogenetical trunks goes by anisotomical way. Thus, in one of newly formed branches a possibility remains of a further evolutionary transformation, while taxa belonging to another branch sink into a prolonged evolutionary stasis. In the author's opinion, such a phenomenon is to be accompanied by distinctions in constitution of genetical cell devices of the taxa belonging to the branches with evolutionary contrasting potencies. In the article, an attempt is done to consider some other approaches relevant to this problem.     

Carotenoid-binding sites of the major light-harvesting complex II of higher plants.

Recombinant light-harvesting complex II (LHCII) proteins with modified carotenoid composition have been obtained by in vitro reconstitution of the Lhcb1 protein overexpressed in bacteria. The monomeric protein possesses three xanthophyll-binding sites. The L1 and L2 sites, localized by electron crystallography in the helix A/helix B cross, have the highest affinity for lutein, but also bind violaxanthin and zeaxanthin with lower affinity. The latter xanthophyll causes disruption of excitation energy transfer. The occupancy of at least one of these sites, probably L1, is essential for protein folding. Neoxanthin is bound to a distinct site (N1) that is highly selective for this species and whose occupancy is not essential for protein folding. Whereas xanthophylls in the L1 and L2 sites interact mainly with chlorophyll a, neoxanthin shows strong interaction with chlorophyll b, inducing the hyperchromic effect of the 652 nm absorption band. This observation explains the recent results of energy transfer from carotenoids to chlorophyll b obtained by femtosecond absorption spectroscopy. Whereas xanthophylls in the L1 and L2 sites are active in photoprotection through chlorophyll-triplet quenching, neoxanthin seems to act mainly in (1)O(2)(*) scavenging.