Genome analyses and modelling the relationships between coding density, recombination rate and chromosome length

Mackiewicz, Dorota; Zawierta, Marta; Waga, Wojciech; Cebrat, S.

doi:10.1016/j.jtbi.2010.08.022

Cited by 10 publications

(11 citation statements)

References 50 publications

(52 reference statements)

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“…Such a preferential placement of the linked genes in the centre of chromosome suppresses recombination in this region that may influence the global distribution of recombination hotspots observed in human chromosomes. This is in agreement with the view that humans have evolved in relatively small populations [39], [52], in which the formation of linked genes is preferred [38]–[40], [51]. If we consider this problem from the point of evolutionary costs, it seems that avoiding recombination in a region of linked genes is more effective than elimination of recombinants from the population [38], [53].…”

Section: Resultssupporting

confidence: 86%

“…These groups of genes consisted mainly of heterozygous loci that could complement their defects with other corresponding haplotypes present in the population. Therefore, when these groups became established by selection, any recombinations breaking these haplotypes had a deleterious effect and were selected against [38], [39]. Such groups of linked genes were not formed at the ends of chromosomes where purifying selection associated with a high recombination rate dominated.…”

Section: Resultsmentioning

confidence: 99%

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Distribution of Recombination Hotspots in the Human Genome – A Comparison of Computer Simulations with Real Data

Mackiewicz

Oliveira

et al. 2013

PLoS ONE

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Recombination is the main cause of genetic diversity. Thus, errors in this process can lead to chromosomal abnormalities. Recombination events are confined to narrow chromosome regions called hotspots in which characteristic DNA motifs are found. Genomic analyses have shown that both recombination hotspots and DNA motifs are distributed unevenly along human chromosomes and are much more frequent in the subtelomeric regions of chromosomes than in their central parts. Clusters of motifs roughly follow the distribution of recombination hotspots whereas single motifs show a negative correlation with the hotspot distribution. To model the phenomena related to recombination, we carried out computer Monte Carlo simulations of genome evolution. Computer simulations generated uneven distribution of hotspots with their domination in the subtelomeric regions of chromosomes. They also revealed that purifying selection eliminating defective alleles is strong enough to cause such hotspot distribution. After sufficiently long time of simulations, the structure of chromosomes reached a dynamic equilibrium, in which number and global distribution of both hotspots and defective alleles remained statistically unchanged, while their precise positions were shifted. This resembles the dynamic structure of human and chimpanzee genomes, where hotspots change their exact locations but the global distributions of recombination events are very similar.

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Section: Resultssupporting

confidence: 86%

Section: Resultsmentioning

confidence: 99%

Distribution of Recombination Hotspots in the Human Genome – A Comparison of Computer Simulations with Real Data

Mackiewicz

Oliveira

et al. 2013

PLoS ONE

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“…The smallest human chromosome (excluding Y chromosome) contains 280 genes while the largest one about 2200 genes. On the other hand genetic length of the shortest one is 62cM while of the largest chromosome is 278cM (for details see International HapMap Consortium 2005 and [22]). Since the correlation between coding capacity and recombination rate is not very high in the human genome ( Fig.11) -our natural chromosomes may differ significantly in relations between recombination rate and number of genes.…”

Section: Relations Between Chromosome Size Coding Density and Criticmentioning

confidence: 99%

The Role of Haplotype Complementation and Purifying Selection in the Genome Evolution

Cebrat

Waga

Stauffer

2012

Advs. Complex Syst.

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We discuss two different ways of evolution for chromosomes and genomes. Purifying selection dominates in large panmictic populations, where the Mendelian law of independent gene assortment is valid. If instead the populations are small, recombination processes are not effective enough to ensure an independent assortment of linked genes, and larger clusters of genes could be inherited as genetic units. There are whole clusters of genes which tend to complement in such conditions instead of single pairs of alleles like in the case of purifying selection. Computer simulations have shown that switching between complementation and purification strategies has the characteristic of a phase transition. This is also responsible for specific distribution of recombination events observed along eukaryotic chromosomes (a higher recombination rate is observed in subtelomeric regions than in central parts of chromosomes) and for sympatric speciation.

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“…At the Faculty of Biology and Animal Science of the Wrocław University of Environmental and Life Sciences, Joanna Szyda's group works on statistic genomics of animals [82]. Stanisław Cebrat's group at the Faculty of Biotechnology of the University of Wrocław is working in the area of theoretical and computational genomics, e.g., on Monte Carlo simulations of genome and population evolution [26], [83].…”

Section: Main Bioinformatics Research Centers In Polandmentioning

confidence: 99%

Bioinformatics and Computational Biology in Poland

Bujnicki

Tiuryn

2013

PLoS Comput Biol

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Genome analyses and modelling the relationships between coding density, recombination rate and chromosome length

Cited by 10 publications

References 50 publications

Distribution of Recombination Hotspots in the Human Genome – A Comparison of Computer Simulations with Real Data

Distribution of Recombination Hotspots in the Human Genome – A Comparison of Computer Simulations with Real Data

The Role of Haplotype Complementation and Purifying Selection in the Genome Evolution

Bioinformatics and Computational Biology in Poland

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