Fractionation of chromatin of liver cell nuclei after mild micrococcal nuclease digestion

Mild micrococcal nuclease treatment of rat and mouse nuclei and fractionation were based on the method of Tata and Baker. Three chromatin fractions, S, P1, P2, were separated, and for each of these fractions the sensitivity to the DNase 1 action was determined. The relative content in these fractions of non-transcribed DNA sequences was established by hydridization with a mouse satellite DNA, and the relative content of transcribed DNA sequences--by hydridization with DNA synthesised on the total poly (A) mRNA. None of the fractions displayed the properties characteristic of active chromatin.     

Polymorphism of angiotensinogen T174M gene and cardiovascular diseases in the Moscow population]

The groups of patients with myocardial infarction (MI) and hypertrophy of the left ventricle (HLV) (n = 45 and n = 53, respectively) and a sample of healthy individuals from the Moscow population (n = 60) were examined for T174M polymorphism of AGT gene (replacement of methionine for threonine at position 174 of the correspondent amino acid sequence). In MI patients the content of TT genotypes and T allele was significantly lower than in the control group (57.8% against 80% and 67.9 against 89.2%, respectively), whereas the proportion of M allele and TM heterozygotes was increased (32.1 against 10.8% and 37.8 against 18.3%, respectively). In patients with HLV, the proportion of TT genotype (64.2%) and T allele (77.4%) was also lower than in the control group, whereas the frequency of M allele was increased (22.6%). Our results suggest that the T174M polymorphism of AGT gene is associated with MI and HLV in the Moscow population.     

Polymorphic markers Val762Ala and Leu54Phe of the ADPRT1 gene associated with chronic glomerulonephritis in Russian patients from the city of Moscow

A comparative analysis of allelic and genotype distribution of polymorphic markers Val762Ala and Leu54Phe of ADPRT1 gene encoding poly(ADP-ribose)polymerase I has been performed in chronic glomerulonephritis patients compared to normal controls. This has shown a significant difference in the ADPRTI gene polymorphic marker Val762Ala allelic and genotype frequency distribution between chronic glomerulonephritis patients and healthy controls (according to Fisher's exact test). At the same time the allelic and genotype frequency for a polymorphic marker Leu54Phe distribution did not show significant difference between these groups. Therefore, we have concluded that the ADPRTI gene polymorphic marker Val762Ala is associated with the development of chronic glomerulonephritis in Russian patients of the Moscow region.     

Use of the polymerase chain reaction for typing allelic variants of the human HLA-DQA1 by hybridization with oligonucleotide probes, specific for specific alleles]

Class II HLA molecules are the most useful markers for susceptibility to different autoimmune diseases, including insulin-dependent diabetes mellitus (IDDM) and rheumatoid arthritis (RA). Polymerase chain reaction and hybridization with a set of allele-specific oligonucleotide have been used for analysis of allelic sequence variation. The analysis of frequencies of HLA-DQA1 alleles among 10 patients of the russian population revealed a uneven distribution. We have developed a method for preparing non-radioactive oligonucleotide probes with terminal deoxynucleotidyl transferase and Bio-11-dUTP. Comparison of biotinylated and 32P-labeled hybridization probes gave the same sensitivity for HLA-DQA1 typing of amplified DNA. Amplification of the HLA-DQA1 gene has been successful on 10 pg of total DNA. This amount of DNA is close to the amount of DNA in a single cell. Alternatively, HLA-DQA1 typing could be based on the analysis of buccal cells of saliva that would avoid the problem of individuals who object to giving blood samples.     

Primary and secondary structure of rat 28 S ribosomal RNA.

The primary structure of rat (Rattus norvegicus) 28 S rRNA is determined inferred from the sequence of cloned rDNA fragments. The rat 28 S rRNA contains 4802 nucleotides and has an estimated relative molecular mass (Mr, Na-salt) of 1.66 X 10(6). Several regions of high sequence homology with S. cerevisiae 25 S rRNA are present. These regions can be folded in characteristic base-paired structures homologous to those proposed for Saccharomyces and E. coli. The excess of about 1400 nucleotides in the rat 28 S rRNA (as compared to Saccharomyces 25 S rRNA) is accounted for mainly by the presence of eight distinct G+C-rich segments of different length inserted within the regions of high sequence homology. The G+C content of the four insertions, containing more than 200 nucleotides, is in the range of 78 to 85 percent. All G+C-rich segments appear to form strongly base-paired structures. The two largest G+C-rich segments (about 760 and 560 nucleotides, respectively) are located near the 5'-end and in the middle of the 28 S rRNA molecule. These two segments can be folded into long base-paired structures, corresponding to the ones observed previously by electron microscopy of partly denatured 28 S rRNA molecules.     

Mapping of the major early endonuclease cleavage site of the rat precursor to rRNA within the internal transcribed spacer sequence of rDNA

The endonuclease cleavage of 41 S pre-rRNA to yield 32 S and 21 S pre-rRNA constitutes a major early step in the processing of pre-rRNA in rat liver. The 5'-terminus of 32 S pre-rRNA and the 3'-terminus of 21 S pre-rRNA were precisely located within the rDNA sequence by S1 nuclease protection mapping and use of appropriate rDNA restriction fragments. The 5'-terminus of 12 S pre-rRNA, an initial product of 32 S pre-rRNA processing, was also mapped within the rDNA sequence. The 5'-termini of 32 S and 12 S pre-rRNA coincide and map within a 14-residue T-tract (non-coding strand) at 161-163 bp upstream from the 5'-end of the 5.8 S rRNA gene. The 3'-terminus of 21 S pre-rRNA maps within the same T-tract. These results show that the endonuclease cleavage occurs within a U-tract in the internal transcribed spacer 1 sequence of 41 S pre-rRNA. The homogeneity of the 5'- or 3'-termini of 32 S, 12 S and 21 S pre-rRNA indicates also that the terminal processing of these molecules, if any, is markedly slower. The coincidence in the location of 32 S and 12 S pre-rRNA 5'-termini shows further that the endonuclease cleavage of 32 S pre-rRNA precedes the removal of its 5'-terminal segment to yield 5.8 S rRNA. The absence in the whole pre-rRNA internal transcribed spacer of sequences complementary to the target U-tract suggests that the endonuclease cleavage, generating 32 S and 21 S pre-rRNA, occurs in a single-stranded loop of U-residues.