Biochemical and ultrastructural analyses of the synaptonemal complex in mammalian spermatocytes

In order to study the molecular organization of synaptonemal complex (SC), a preparative method for isolation of relatively purified SC from rat, mouse and hamster testes was elaborated which involves isolation of SC-containing (pachytene) nuclei, their lysis, DNAase digestion of DNA and fractionation of nuclear elements by the discontinuous sucrose density gradient centrifugation. Electron microscopy revealed a rather good preservation of the SC structure after the isolation procedure. Effects of the dissociating agents on the SC structural integrity were studied. It has been demonstrated that the treatment with 2M NaCl, Triton X-100, sodium deoxycholate, 6M urea, and with a buffer containing 2% SDS and 5% mercaptoetthanol does not lead to a complete SC dissociation, though it results in some structural chanes. Possible reasons of the high resistance of SC to dissociating treatment are discussed.     

Peculiarities of chromosome organization in meiosis

Meiotic and mitotic chromosomes have a complex of differences. (1) At the early prophase I of meiosis, chromosomes acquire protein axial elements (AEs) that were absent in mitosis; in addition to somatic cohesins, AEs contain the meiosis-specific cohesins REC8, SMC1β, and STAG3. (2) At the middle prophase I, protein lateral elements (LEs) of synaptonemal complexes (SCs) are formed on the basis of AEs. The LE proteins are not conserved, but in Saccharomyces cerevisiae and Arabidopsis thaliana they contain functional domains with conserved secondary structures. Among the almost 679 thousand proteins of primitive eukaryotes that we studied by bioinformatics methods, in green and brown algae, some lower fungi, and Coelenterata, we revealed proteins or functional domains similar to SC proteins. (3) During the pachytene and diplotene stages of meiosis, chromosomes of spermatocytes and mother pollen cells acquire a general structure resembling the structure of amphibian and avian lampbrush chromosomes in miniature. Lateral chromatin loops with sizes of 90, 160, and even over 480 Kb were observed in human spermatocytes during the diplotene stage. In combination, all these observations confirm the considerable conservation of the scheme of molecular and ultrastructural organization of meiotic chromosomes in a large variety of eukaryotic organisms.     

Use of artificial neuronal nets in automation of analysis and genetic identification of electrophoretic spectra of gliadin from durum wheat]

Each wheat cultivar has a characteristic spectrum of gliadins. This makes it possible to use blocks of the components of reserve proteins as genetic markers when estimating seed quality. However, identification of the blocks that constitute the electrophoretic spectrum is a complicated task. For this purpose artificial neural network (ANN) technology is proposed. Based on experimental data, a teaching database and testing databases have been created. ANN was shown to be highly efficient (efficiency up to 100%) expert system for deciphering the electrophoretic spectra of gliadins of durum wheat cultivars.     

Meiotic mutations in rye Secale cereale L

Spontaneous meiotic mutations of winter rye Secale cereale L. (2n = 14) were revealed in inbred F2 progenies, which were obtained by self-pollination of F1 hybrids resulting from crosses of individual plants of cultivar Vyatka or weedy rye with plants of self-fertile inbred lines. The mutations cause partial or complete sterility, and are maintained in heterozygote condition. Six types of mutations were distinguished as the result of cytological analysis of meiosis and genetic analysis. (1) Plants with nonallelic asynaptic mutations sy1 and sy9 lacked bivalents in 96.8 and 67.0% metaphase I cells, respectively, formed only axial elements but not the mature synaptonemal complex (SC), and had defects in telomere clustering in early prophase I. (2) Weak asynaptic mutant sy3 showed incomplete synapsis at the start of SC degradation at diplotene and lower chiasma number; yet only 2% meiocytes lacked bivalents in MI. (3) Mutations sy2, sy6, sy7, sy8, sy10, and sy19 caused nonhomologous synapsis; i.e., a varying number of univalents and occasional multivalents were observed in MI, which was preceded by switches of pairing partners and fold-back synapsis at mid-prophase I. (4) Mutation mei6 led to the formation of protrusions and minor branched structures of the SC lateral elements. (5) Allelic mutations mei8 and mei8-10 caused irregular chromatin condensation along the chromosome length in prophase I, which was accompanied by chromosome sticking and fragmentation in MI. (6) Allelic mutations mei5 and mei10 determined chromosome supercondensation, caused the disturbance of meiotic spindle assembly, arrested meiosis at various stages but did not affect formation of the pollen wall, thus arrested meiocytes got covered with the pollen wall. Analysis of double mutants revealed recessive epistatic interactions for some mutations; the epistatic group was sy9 > sy1 > sy3 > sy19. This reflects the sequence of meiotic events controlled by the corresponding genes. The expression of sy2 and sy19 proved to be modified by additional genes. Most meiotic mutations found in rye have analogs in other plants.     

Identification and Characterization <Emphasis Type="Italic">in silico</Emphasis> of Meiotic DNA

A method of in silico search for specific repetitive DNA sequences related to the synaptonemal complex (meiDNA) in mammalian genomes was developed. A study of the distribution of these repeats over chromosomes revealed their scarcity on the Y chromosome and a decrease in recombination frequency in regions enriched in meiDNA. The results are discussed in context of the model of the looplike meiotic chromosome organization during the formation of the synaptonemal complex.__________Translated from Genetika, Vol. 41, No. 5, 2005, pp. 697–701.Original Russian Text Copyright © 2005 by Grishaeva, Dadashev, Bogdanov.     

In silico identification and characterization of meiotic DNA: AluJb possibly participates in the attachment of chromatin loops to synaptonemal complex

Earlier, using bioinformatic methods, we reported the identification of repeated DNA sequences (RS), presumably responsible for the attachment of chromatin loops to the lateral elements of synaptonemal complex in meiotic chromosomes. In the present study, consensus sequences for this class of RS were identified. It was demonstrated that at least part of these sequences belonged to the AluJb subfamily of Alu sequences. The Alu copies distribution along the major human histocompatibility complex (MHC) and their spatial separation from the sites of meiotic recombination was examined. It was demonstrated that simple sequences, like (GC/CA)n, were flanking meiotic recombination sites. A model of the RS organization in meiotic chromosome, most efficiently linking experimental data on the meiotic recombination in MHC and the in silico data on the RS localization (the coefficient of multiple correlation, r = 0.92) is suggested.     

DNA repeated sequences may be involved in synaptonemal complex formation

Synaptonemal complexes (SCs) are intranuclear structures that facilitate the reversible lateral synapsis of homologous chromosomes in the course of meiosis. It is still unclear which DNA nucleotide sequences are responsible for the attachment of chromatin to SC lateral elements. Considering the features of the dispersed repeated sequences (RSs), it is possible to assume that they participate in the structure and functional organization of the meiotic chromosomes. Using numerical analysis, we have investigated the relationship between the RS and the distribution of meiotic recombination events in mouse chromosome 1. Using in situ hybridization on spread mouse spermatocytes, we have examined the arrangement of different types of RSs relative to SCs. Hybridization signals of B1(Alu), B2, and minisatellite probes were localized predominantly in SCs regions. Based on the results, we proposed a model of meiotic chromosome organization. According to the model, RSs participate in the attachment of chromatin loops to SCs.     

Gene CG17604 of Drosophila melanogaster May Be a Functional Homolog of Yeast Gene ZIP1 and Mammal Gene SCP1 (SYCP1) Encoding Proteins of the Synaptonemal Complex

From data on the molecular organization of transverse filament proteins of the synaptonemal complex (SC)—Zip1 in yeast and SCP1 in mammals—and on the width of the SC central space in these organisms and in Drosophila, the putative molecular structure and size of a transverse filament protein of the SC in Drosophila has been inferred. Using genetic and molecular databases and software from the Internet, we carried out in silico screening for a candidate gene for the Drosophila transverse filament protein. As a most likely candidate, gene c(3)G was chosen. The search in the 250-kb region overlapping the locus of this gene (sections 88E-89B) and containing 78 predicted genes has revealed only one gene,CG17604, whose protein meets all requirements for the transverse filament protein of the SC. It was suggested that gene CG17604is gene c(3)G. In this case, genec(3)G must be localized in section 89A7-8 of the cytological map of Drosophila melanogaster.     

Comparative genomics and proteomics of Drosophila,Brenner's nematode,and Arabidopsis: identification of functionally similar genes and proteins of meiotic chromosome synapsis

The published principles of computer analysis of genomes and protein sets in taxonomically distant eukaryotes are expounded. The authors developed a search strategy to identify in genomes of such organisms genes and proteins nonhomologous in primary structure but having similar functions in cells dividing by meiosis. This strategy based on the combined principles of genomics, proteomics, and morphometric analysis of subcellular structures was applied to a computer search for genes encoding the proteins of synaptonemal complexes in genomes of Drosophila melanogaster, the nematode Caenorhabditis elegans, and the plant Arabidopsis thaliana. These proteins proved to be functionally similar to their counterparts in yeast Saccharomyces cerevisiae (protein Zip1p) and mammals (protein SCP1).