Unique or not unique? Comparative genetic analysis of bacterial O-antigens from the Oxalobacteraceae family.

Many plants and animals have symbiotic relationships with microorganisms, including bacteria. The interactions between bacteria and their hosts result in different outcomes for the host organism. The outcome can be neutral, harmful or have beneficial effects for participants. Remarkably, these relationships are not static, as they change throughout an organism's lifetime and on an evolutionary scale. One of the structures responsible for relationships in bacteria is O-antigen. Depending on the characteristics of its components, the bacteria can avoid the host's immune response or establish a mutualistic relationship with it. O-antigen is a key component in Gram-negative bacteria's outer membrane. This component facilitates interaction between the bacteria and host immune system or phages. The variability of the physical structure is caused by the genomic variability of genes encoding O-antigen synthesis components. The genes and pathways of O-polysaccharide (OPS) synthesis were intensively investigated mostly for Enterobacteriaceae species. Considering high genetic and molecular diversity of this structure even between strains, these findings may not have caught the entire variety possibly presented in non-model species. The current study presents a comparative analysis of genes associated with O-antigen synthesis in bacteria of the Oxalobacteraceae family. In contrast to existing studies based on PCR methods, we use a bioinformatics approach and compare O- antigens at the level of clusters rather than individual genes. We found that the O-antigen genes of these bacteria are represented by several clusters located at a distance from each other. The greatest similarity of the clusters is observed within individual bacterial genera, which is explained by the high variability of O-antigens. The study describes similarities of OPS genes inherent to the family as a whole and also considers individual unique cases of O-antigen genetic variability inherent to individual bacteria.

THE STRUCTURE OF DNA CHROMOCENTRES IN MOUSE IN SILICO AND IN SITU. LINE AND ERV FRAGMENTS ARE AN OBLIGATORY COMPONENTS OF DNA CHROMOCENTRES BESIDES TANDEM REPEATS.

Constitutive heterochromatin in higher eukaryotes is located in the primary chromosomal strangulation (centromeres and pericentromeres) and subtelomeric regions of chromosomes. In house mouse constitutive chromatin formes structures in the nuclei of cells, brightly colored with DAPI. It is known that the constitutive heterochromatin is enriched with large tandem repeats, however, its exact composition is unknown. In this paper chromocenters were studied using several approaches: cloning and sequencing by Sanger, as well as by high-throughput sequencing. We have shown that DNA components of chromocenters and constitutive chromatin are full-length endogenous retroviruses (ERV) and a 2 kbp fragment of the 3R-end of the LINE.

[Tandem repeats in rodents genome and their mapping].

Tandemly-repeated sequences represent a unique class of eukaryotic DNA. Their content in the genome of higher eukaryotes mounts to tens of percents. However, the evolution of this class of sequences is poorly-studied. In our paper, 62 families of Mus musculus tandem repeats are analyzed by bioinformatic methods, and 7 of them are analyzed by fluorescence in situ hybridization. It is shown that the same tandem repeat sets co-occure only in closely related species of mice. But even in such species we observe differences in localization on the chromosomes and the number of individual tandem repeats. With increasing evolutionary distance only some of the tandem repeat families remain common for different species. It is shown, that the use of a combination of bioinformatics and molecular biology techniques is very perspective for further studies of the evolution of tandem repeats.

[Mouse centromeric tandem repeats in silico and in situ].

The search for all sequences containing centromeric (CEN) minor satellite (MiSat) or pericentromeric (peri-CEN) mouse major satellite (MaSat) was conducted in the whole genome shotgun (WGS) database. The sequences were checked for the presence of the known dispersed repeats using the Censor software. The presence of tandem repeats was tested using Tandem Repeat Finder (TRF). Monotonous MiSat and MaSat arrays and MaSat to MiSat array transitions were detected. Moreover, two other types of contacts were revealed: (1) MiSat transition to fragments of retroelements LINE and IAP (ERV family, intracisternal A-type particles), mainly to ORF2 and 5'-LTR containing elements; (2) MaSat transition to two tandem repeats with monomers 21 bp and 31 bp in size. The presence of the MiSat/IAP transition could be checked experimentally. The common DNA motif among the IAP fragments close to MiSat was isolated. IAP-specific primers were constructed and the fragments obtained in PCR with LAP and MiSat primers compiled the plasmid vector library. Clone n51 with the maximum length of the possible insertion (approximately no. 800 bp) was selected from the library. FISH on extended chromatin fibers (fiberFISH) carried out on the n51 clone demonstrated that the main signal definitely belonged to CEN. However, the signals on the chromosome arms were also detected that could be due to the partial homology of n51 to the dispersed repeats. The duplicated fiberFISH with MiSat and n51 allowed to measure the distances between the fragments. The previously obtained MS3 sequence has some homology to IAP and CEN localization. Accordingly, the regular associations of MiSat with IAP retroelements were shown in silico and in situ. Together with the published data, the present findings suggest that retroelements or their fragments may be essential components of the normal centromere of higher eukaryotes.

[Heterochromatin and centromere structure paradox].

Centromere (CEN) is the structure responsible for the chromatid association, chromosome attachment to the spindle, and correct position in the plate. The only DNA found in the mammalian CEN belongs to the satellite DNA--high repeated tandem repeats. Mounting evidence indicates that both types of chromatin (CEN and peri-CEN) are required for proper centromere function. CEN, peri-CEN and peritelomeric regions remain white spots at the chromosome maps appeared after reading genomes of human, mouse, and rat. SatDNA is considered to be species-specific. Library hypothesis regards heterochromatin as the library of different satDNA one fragments of which became spread and fixed in species fixation. We have analyzed database Chromosome Unknown (ChrUn) and found several new classes of mouse tandem repeats. The features of these classes are similar with the ones from rat ChrUn, as well as their distributions according to GC-richness. We believe that similar fragments' structure, i. e. intermingling of fragments with different curvature rather than their primary sequence will help to solve the paradox, when CEN or peri-CEN fragments from different animals have nothing in common, but bind the same sets of proteins.