Position-effect variegation in Drosophila melanogaster X chromosome inversion with a breakpoint in a satellite block and its suppression in a secondary rearrangement

In(1LR)pn2a is a pericentric inversion with a euchromatic breakpoint in the 2E polytene region and a heterochromatic breakpoint in the right arm of the X chromosome. It is associated with position-effect variegation (PEV) of the pn, wapl, Pgd and other vital loci of the 2E region, which are relocated near the bulk of the X heterochromatin. Cytological analysis showed that the rearrangement brings the 1A–2E euchromatic segment directly into contact with a major portion of the h34 block, a heterochromatic region that is positively stained by the N-banding technique and contains the AAGAG satellite sequences. Molecular cloning revealed the presence of a new junction between euchromatin and AAGAG satellite sequences and demonstrated that the euchromatic breakpoint of In(1LR)pn2a lies in the vinculin gene. In the X ray-induced secondary rearrangement In(1LR)r30, consisting of a pericentric inversion superimposed on In(1LR)pn2a, the h34 material remains associated with the 2E region but is separated from the rest of the X heterochromatin. In this case, the pn, wapl and Pgd loci no longer variegate, suggesting that the satellite-containing h34 region is not able per se to induce detectable PEV on the adjacent euchromatic genes. Received in revised form: 15 June 1997 / Accepted: 16 September 1997     

Poriferan mtDNA and animal phylogeny based on mitochondrial gene arrangements

Phylogenetic relationships among the metazoan phyla are the subject of an ongoing controversy. Analysis of mitochondrial gene arrangements is a powerful tool to investigate these relationships; however, its previous application outside of individual animal phyla has been hampered by the lack of informative out-group data. To address this shortcoming, we determined complete mitochondrial DNA sequences for the demosponges Geodia neptuni and Tethya actinia, two representatives of the most basal animal phylum, the Porifera. With sponges as an outgroup, we investigated phylogenetic relationships of nine bilaterian phyla using both breakpoint analysis of global mitochondrial gene arrangements and maximum parsimony analysis of mitochondrial gene adjacencies. Our results provide strong support for a group that includes protostome (but not deuterostome) coelomate, pseudocoelomate, and acoelomate animals, thus clearly rejecting the Coelomata hypothesis. Two other groups of bilaterian animals, Lophotrochozoa and Ambulacraria, are also supported by our analyses. However, due to the remarkable stability of mitochondrial gene arrangements in Deuterostomia and the Ecdysozoa, conclusions on their evolutionary history cannot be drawn.     

Experimental studies of the effect of beaver (<Emphasis Type="Italic">Castor fiber</Emphasis> L.) vital activity products on the formation of zooplankton structure (by the example of growth of two cladoceran species of different sizes)

Experiments in microcosms have demonstrated that beaver vital activity products (BVAPs) promote an increase in concentrations of total nitrogen (N) and total phosphorus (P), a decrease in the N/P value in water, and an increase in the abundance and biomass of bacterioplankton. Under such conditions, the abundance and biomass of small Ceriodaphnia dubia Richard and large Daphnia (Ctenodaphnia) magna Straus, which live separately, increase. The coexistence of these cladocerans in microcosms under the BVAP influences results in a high increase in the abundance and biomass of D. magna; in similar experiments without the influence of BVAP, Ceriodaphnia dubia becomes more abundant. The results of bioassay demonstrate that the number of newborns of Ceriodaphnia dubia decreases in water where Daphnia magna is numerous owing to BVAPs. It is suggested that the vital activity products of large representatives of the genus Daphnia inhibit the fecundity of small species of Cladocera. This fact, along with the high competitiveness of large cladoceran species under conditions of a high level of nutritive base, determine the formation of zooplankton communities in beaver ponds which are characterized by a high abundance and biomass and low uniformity     

Comparison of Haemophilus parasuis reference strains and field isolates by using random amplified polymorphic DNA and protein profiles

ABSTRACT: BACKGROUND: Haemophilus parasuis is the causative agent of Glasser's disease and is a pathogen of swine in high-health status herds. Reports on serotyping of field strains from outbreaks describe that approximately 30% of them are nontypeable and therefore cannot be traced. Molecular typing methods have been used as alternatives to serotyping. This study was done to compare random amplified polymorphic DNA (RAPD) profiles and whole cell protein (WCP) lysate profiles as methods for distinguishing H. parasuis reference strains and field isolates. RESULTS: The DNA and WCP lysate profiles of 15 reference strains and 31 field isolates of H. parasuis were analyzed using the Dice and neighbor joining algorithms. The results revealed unique and reproducible DNA and protein profiles among the reference strains and field isolates studied. Simpson's index of diversity showed significant discrimination between isolates when three 10mer primers were combined for the RAPD method and also when both the RAPD and WCP lysate typing methods were combined. CONCLUSIONS: The RAPD profiles seen among the reference strains and field isolates did not appear to change over time which may reflect a lack of DNA mutations in the genes of the samples. The recent field isolates had different WCP lysate profiles than the reference strains, possibly because the number of passages of the type strains may affect their protein expression.     

Mitochondrial genomes of two demosponges provide insights into an early stage of animal evolution

Mitochondrial DNA (mtDNA) of multicellular animals (Metazoa) is typically a small ( approximately 16 kbp), circular-mapping molecule that encodes 37 tightly packed genes. The structures of mtDNA-encoded transfer RNAs (tRNAs) and ribosomal RNAs (rRNAs) are usually highly unorthodox, and proteins are translated with multiple deviations from the standard genetic code. In contrast, mtDNA of the choanoflagellate Monosiga brevicollis, the closest unicellular relative of animals, is four times larger, contains 1.5 times as many genes, and lacks mentioned peculiarities of animal mtDNA. To investigate the evolutionary transition that led to the specific organization of metazoan mtDNA, we determined complete mitochondrial sequences from the demosponges Geodia neptuni and Tethya actinia, two representatives of the most basal animal phylum, the Porifera. We found that poriferan mtDNAs resemble those of other animals in their compact organization, lack of introns, and a well-conserved animal-like gene order. Yet, they contain several extra genes, encode bacterial-like rRNAs and tRNAs, and use a minimally derived genetic code. Our findings suggest that the evolution of the typical metazoan mtDNA has been a multistep process in which the compact genome organization and the reduced gene content were established prior to the reduction of tRNA and rRNA structures and the introduction of multiple changes of the translation code.     

Frequent variations in cancer-related genes may play prognostic role in treatment of patients with chronic myeloid leukemia

Genome variability of host genome and cancer cells play critical role in diversity of response to existing therapies and overall success in treating oncological diseases. In chronic myeloid leukemia targeted therapy with tyrosine kinase inhibitors demonstrates high efficacy in most of the patients. However about 15 % of patients demonstrate primary resistance to standard therapy. Whole exome sequencing is a good tool for unbiased search of genetic variations important for prognosis of survival and therapy efficacy in many cancers. We apply this approach to CML patients with optimal response and failure of tyrosine kinase therapy. We analyzed exome variations between optimal responders and failures and found 7 variants in cancer-related genes with different genotypes in two groups of patients. Five of them were found in optimal responders: rs11579366, rs1990236, rs176037, rs10653661, rs3803264 and two in failures: rs3099950, rs9471966. These variants were found in genes associated with cancers (ANKRD35, DNAH9, MAGEC1, TOX3) or participating in cancer-related signaling pathways (THSD1, MORN2, PTCRA). We found gene variants which may become early predictors of the therapy outcome and allow development of new early prognostic tests for estimation of therapy efficacy in CML patients. Normal genetic variation may influence therapy efficacy during targeted treatment of cancers.     

Comparative study of human mitochondrial proteome reveals extensive protein subcellular relocalization after gene duplications

Background  

Gene and genome duplication is the principle creative force in evolution. Recently, protein subcellular relocalization, or neolocalization was proposed as one of the mechanisms responsible for the retention of duplicated genes. This hypothesis received support from the analysis of yeast genomes, but has not been tested thoroughly on animal genomes. In order to evaluate the importance of subcellular relocalizations for retention of duplicated genes in animal genomes, we systematically analyzed nuclear encoded mitochondrial proteins in the human genome by reconstructing phylogenies of mitochondrial multigene families.     

Significance of presetting an analyzer system in discriminating light intensity in the cat

EEG and behavioural reactions were studied at the action of signal and nonsignal light flashes. The minimal time of stimulus exposition necessary for preserving differences in EEG activation reactions to nonreinforced stimuli of different intensity (in a diapason from 3.5 to 250 lk) was shown to exceed 1 s. After giving the signal meaning to the flashes the minimal time of stimulus exposition when the animals were capable to discriminate intensity of the flashes (in a diapason from 3.5 to 30 lk) just at the first presentation, was equal to 0.1 s. Decrease of the minimal time of stimulus exposition necessary for discrimination of the light signals was supposed to be stipulated by their biological significance and presetting of the analyzing system being organized by preliminary learning a crude analysis of stimuli. Discrimination of the light stimuli of short duration was impossible without such presetting.     

Trichinella spiralis mtDNA: a nematode mitochondrial genome that encodes a putative ATP8 and normally structured tRNAS and has a gene arrangement relatable to those of coelomate metazoans

The complete mitochondrial DNA (mtDNA) of the nematode Trichinella spiralis has been amplified in four overlapping fragments and 16,656 bp of its sequence has been determined. This sequence contains the 37 genes typical of metazoan mtDNAs, including a putative atp8, which is absent from all other nematode mtDNAs examined. The genes are transcribed from both mtDNA strands and have an arrangement relatable to those of coelomate metazoans, but not to those of secernentean nematodes. All protein genes appear to initiate with ATN codons, typical for metazoans. Neither TTG nor GTT start codons, inferred for several genes of other nematodes, were found. The 22 T. spiralis tRNA genes fall into three categories: (i) those with the potential to form conventional "cloverleaf" secondary structures, (ii) those with TPsiC arm + variable arm replacement loops, and (iii) those with DHU-arm replacement loops. Mt-tRNA(R) has a 5'-UCG-3' anticodon, as in most other metazoans, instead of the very unusual 5'-ACG-3' present in the secernentean nematodes. The sequence also contains a large repeat region that is polymorphic in size at the population and/or individual level.     

The earliest musk deer of the genus <Emphasis Type="Italic">Moschus</Emphasis> and their significance in clarifying of evolution and relationships of the family Moschidae

Moschus grandaevus Schlosser, the most ancient musk deer, is recorded from two Late Miocene localities in the south of Eastern Siberia, Olkhon Island (Lake Baikal) and Taralyk-Cher near Kyzyl (Tuva). The morphological study of the species elucidates the origin, evolution, and relationships of the genus Moschus and the entire family Moschidae. A new classification of the Moschidae is proposed.