Candidate Cancer Driver Mutations in Distal Regulatory Elements and Long-Range Chromatin Interaction Networks

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Escape from Premature Death Due to Nuclear Mutations inPodospora anserina:Repeal versus Respite

Premature death has been defined as a growth stoppage linked to the accumulation of specific deletions of the mitochondrial genome (mtDNA) inPodospora anserina. This occurs only in strains carrying theAS1-4mutation which lies in a gene encoding a cytosolic ribosomal protein. Here we describe the isolation and genetic characterization of 10 nuclear mutations which either delay the appearance of this syndrome (respite from premature death) or cause a switch to the classical senescence process (repeal of premature death). These mutations lie in at least six genes. Some cause defects at the levels of ascospore germination, growth rates, and/or sensitivity toward inhibitors of protein syntheses. All modify the onset of senescence in wild-type (AS1⁺) strains. The role played by these genes is discussed with respect to the control of diseases due to mtDNA rearrangements in filamentous fungi.     

The tendency of lentiviral open reading frames to become A-rich: constraints imposed by viral genome organization and cellular tRNA availability

Human immunodeficiency virus type 1 (HIV-1) and other lentiviridae demonstrate a strong preference for the A-nucleotide, which can account for up to 40% of the viral RNA genome. The biological mechanism responsible for this nucleotide bias is currently unknown. The increased A-content of these viral genomes corresponds to the typical use of synonymous codons by all members of the lentiviral family (HIV, SIV, BIV, FIV, CAEV, EIAV, visna) and the human spuma retrovirus, but not by other retroviruses like the human T-cell leukemia viruses HTLV-I and HTLV-II. In this article, we analyzed A-bias for all codon groups in all open reading frames of several lentiviruses. The extent of lentiviral codon bias could be related to host cellular translation. By calculating codon bias indices (CBIs), we were able to demonstrate an inverse correlation between the extent of codon bias and the rate of translation of individual reading frames in these viruses. Specifically, the shift toward A-rich codons is more pronounced in pol than in gag lentiviral genes. Since it is known that Gag synthesis exceeds Pol synthesis by a factor of 20 due to infrequent ribosomal frame-shifting during translation of the gap-pol mRNA molecule, we propose that the aminoacyl-tRNA availability in the host cell restricts the lentiviral preference for A-rich codons. In addition, less A-nucleotides were found in regions of the viral genome encoding multiple functions; e.g., overlapping reading frames (tat-rev-env) or in genes that overlap regulatory sequences (nef-LTR region). Finally, the characteristics of lentiviral codon usage are presented as a phylogenetic tree without the need for prior sequence alignment.Correspondence to: B. Berkhout     

A Model of Genome Size Dynamics During Speciation

A model developed for the evolving size of the repetitive part of the eukaryote genome during speciation was subjected to analytical and computer treatment. The basic assumption of the model was that two classes of repetitive DNA contribute mainly to macroevolutionary changes in genome size: arrays of tandem repeats (ATR) changing through unequal crossover and mobile genetic elements (MGE) changing presumably through an integration mechanism of the Tn- and Is-kind operating in bacteria. Within the framework of this model, the macroevolution of the MGE size is formally equivalent to that of the ATR in the particular case when shifts of chromatids have only one repeat out of register. This allowed us to consider genome size as a large set of various ATRs. The results obtained are as follows. If the duplication and deletion of repeats have unequal fixation probabilities during each speciation act, the predicted species distributions of genome size significantly deviate from the real ones; if they have equal fixation probabilities, there is a conformance between calculated and real distributions. In the latter case, the model reproduces the salient features of real distributions upon acceptance of 1) upper selective boundary nonspecifically limiting increase in genome size within the evolving taxonomic group and 2) non-neutrality of variability in genome size with respect to speciation.     

PHYLOGENETIC ANALYSIS AND GENOME SIZE OF OSTREOCOCCUS TAURI (CHLOROPHYTA, PRASINOPHYCEAE)

Ostreococcus tauri Courties et Chrétiennot-Dinet is the smallest described autotrophic eukaryote dominating the phytoplanktonic assemblage of the marine Mediterranean Thau lagoon (France). Its taxonomic position was partly elucidated from ultrastructure and high-pressure liquid chromatography (HLPC) pigment analysis. The sequence analysis of the 18S rDNA gene of O. tauri measured here is available in EMBL Nucleotide Sequence Database (accession number: Y15814) and allowed to clarify its phylogenetic position. O. tauri belongs to the Prasinophyceae and appears very close to Mantoniella, a typical scaly Prasinophyceae, morphologically very different from the naked and coccoid Ostreococcus. An electrophoretic analysis of O. tauri shows that the nucleus contains 10.20 mbp. This small genome, fragmented into 14 chromosomes ranging in size from 300 to 1500 kbp, confirms the minimalist characteristics of Ostreococcus tauri.     

Characterization of twenty‐four microsatellite markers for rainbow trout (Oncorhynchus mykiss)

Twenty‐four new microsatellite markers were developed for genome mapping and population genetics studies in rainbow trout (Oncorhynchus mykiss). The amount of polymorphism, percentage heterozygosity and ability of each marker to amplify genomic DNA from other salmonids were recorded. Seven markers were observed to be duplicated in the rainbow trout genome by containing more than one allele in homozygous (clonal) fish.