Diversity in G + C content at the third position of codons in vertebrate genes and its cause.

Correlation was positive between the G + C content at the codon third position in genes of vertebrates and the G + C content of the genome portion surrounding each gene. Exons of genes with a high G + C% at the codon 3rd position are surrounded by G + C-rich introns and G + C-rich flanking sequences, and those with a low G + C% at the position by A + T-rich introns and flanking sequences. Analysis of G + C content distribution along DNA sequences using a DNA Sequence Data Bank supported the view that the vertebrate genome is a mosaic of regions with clear differences in their G + C content. The biological significance of the variation in G + C content throughout the vertebrate genome is discussed in connection with chromosomal banding.     

Brain Swelling and Loss of Gray and White Matter Differentiation in Human Postmortem Cases by Computed Tomography

The purpose of this study was to evaluate the brain by postmortem computed tomography (PMCT) versus antemortem computed tomography (AMCT) using brains from the same patients. We studied 36 nontraumatic subjects who underwent AMCT, PMCT, and pathological autopsy in our hospital between April 2009 and December 2013. PMCT was performed within 20 h after death, followed by pathological autopsy including the brain. Autopsy confirmed the absence of intracranial disorders that might be related to the cause of death or might affect measurements in our study. Width of the third ventricle, width of the central sulcus, and attenuation in gray matter (GM) and white matter (WM) from the same area of the basal ganglia, centrum semiovale, and high convexity were statistically compared between AMCT and PMCT. Both the width of the third ventricle and the central sulcus were significantly shorter in PMCT than in AMCT (P < 0.0001). GM attenuation increased after death at the level of the centrum semiovale and high convexity, but the differences were not statistically significant considering the differences in attenuation among the different computed tomography scanners. WM attenuation significantly increased after death at all levels (P<0.0001). The differences were larger than the differences in scanners. GM/WM ratio of attenuation was significantly lower by PMCT than by AMCT at all levels (P<0.0001). PMCT showed an increase in WM attenuation, loss of GM–WM differentiation, and brain swelling, evidenced by a decrease in the size of ventricles and sulci.     

Growth inhibition of Helicobacter pylori by apolyamine synthesis inhibitor, methylglyoxal bis(cyclopentylamidinohydrazone)

The anti-proliferative effect of methylglyoxal bis(cyclopentyl-amidino-hydrazone) (MGBCP), a multi-enzyme inhibitor of polyamine biosynthesis, on the growth of Helicobacter pylori was investigated. MGBCP inhibited the cell growth of H. pylori in a dose-dependent manner. The inhibition was partially reversed by the addition of spermidine. Synthesis of macromolecules, DNA, RNA and protein, was inhibited in the spermidine-depleted H. pylori cells. These findings suggest that MGBCP exhibits an anti-proliferative effect on H. pylori by suppression of macromolecule synthesis.     

Dinucleosome DNA of human K562 cells: experimental and computational characterizations

Dinucleosome formation is the first step in the organization of the higher order chromatin structure. With the ultimate aim of elucidating the dinucleosome structure, we constructed a library of human dinucleosome DNA. The library consists of PCR-amplifiable DNA fragments obtained by treatment of nuclei of erythroid K562 cells with micrococcal nuclease followed by extraction of DNA and adaptor ligation to the blunt-ended DNA fragments. The library was then cloned using a plasmid vector and the sequences of the clones were determined. The dominating clones containing the Alu elements were removed. A total of 1002 clones, which comprised a dinucleosome database, contained 84 and 918 clones from the clones before and after removing Alu elements, respectively. Approximately 70% of the clones were between 300 and 400 bp in size and they were distributed to various locations of all chromosomes except the Y chromosome. The clones containing A(2)N(8)A(2)N(8)A(2) or T(2)N(8)T(2)N(8)T(2) sequences were classified into three types, Type I (N shape), Type II (V shape) and Type III (M shape) according to DNA curvature plots. The locations of experimentally determined curved DNA segments matched well with the calculated ones though the clones of Types I and III showed additional curved DNA segments as revealed by the curvature plots. The distributions of complementary dinucleotides in the nucleosome DNA, at the ends of the dinucleosome DNA clones, allowed us to predict the positions of the nucleosome dyad axis, and estimate the size of the nucleosome core DNA, 125nt. The distributions of AA and TT dinucleotides, as well as other RR and YY dinucleotides, showed a periodicity with an average period of 10.4 bases, close to the values observed before. Mapping of nucleosome positions in the dinucleosome database based on the observed periodicity revealed that the nucleosomes were separated by a linker of 7.5+ approximately 10 x n nt. This indicates that the nucleosome-nucleosome orientations are, typically, halfway between parallel and antiparallel. Also an important finding is that the distributions of AA/TT and other RR/YY dinucleotides, apparently, reflect both DNA curvature and DNA bendability, cooperatively contributing to the nucleosome formation.     

Amplicons on human chromosome 11q are located in the early/late-switch regions of replication timing

Amplicons are frequently found in human tumor genomes, but the mechanism of their generation is still poorly understood. We previously measured the replication timing of the genes along the entire length of human chromosomes 11q and 21q and found that many "disease-related" genes are located in timing-transition regions. In this study, further scrutiny of the updated replication-timing map of human chromosome 11q revealed that both amplicons on human chromosomal bands 11q13 and 11q22 are located in the early/late-switch regions of replication timing in two human cell lines (THP-1 and Jurkat). Moreover, examination of synteny in the human and mouse genomes revealed that synteny breakage in both genomes occurred primarily at the early/late-switch regions of replication timing that we had identified. In conclusion, we found that the early/late-switch regions of replication timing coincided with "unstable" regions of the genome.     

Codon usage tabulated from the international DNA sequence databases.

CUTG (codon usage tabulated from GenBank) is a comprehensive database for codon usage. The codon usage for each full-length protein gene has been calculated using the nucleotide sequence obtained from GenBank sequence database. The sum of the codon use of each organism has been also calculated. The data files can be obtained from anonymous ftp sites of DDBJ, DISC and EBI. The list of codonusage of genes in organisms was made searchableby name of organism through a web site http://www.dna.affrc.go.jp/ approximately nakamura/CUTG.html The compilation is synchronized with major release of GenBank.     

Two-dimensional display of lambda and Escherichia coli restriction fragments separated by Hg-Cs2SO4 centrifugation and gel electrophoresis

EcoRI restriction fragments derived from the DNA of bacteriophage lambda and Escherichia coli were fractionated by density gradient centrifugation of their mercury complexes in Cs2SO4 and subsequent electrophoresis on a horizontal agarose-gel slab. In this two-dimensional display, lambda fragments were resolved into six components and E coli fragments into more than 108 components. Bacterial chromosome regions contiguous to lambda prophage integrated at different sites were amplified by induction, and the EcoRI fragments were subjected to the two-dimensional analysis. As expected, the sets of amplified fragments were clearly different among the various lysogens. The approximate genome region affected by induction was estimated as one-tenth of the whole chromosome.     

Correlation between the abundance of yeast transfer RNAs and the occurrence of the respective codons in protein genes. Differences in synonymous codon choice patterns of yeast and Escherichia coli with reference to the abundance of isoaccepting transfer RNAs

There exists a similarity among the synonymous codon choice patterns of the yeast nuclear genes that have been sequenced thus far although these genes encode different types of protein molecules, and the patterns are significantly different from those of Escherichia coli genes. Based on constraints caused by the availability of E. coli transfer RNAs and the nature of their codon recognition related to the modified nucleotides at the anticodon wobble position, the characteristic patterns of synonymous codon choice commonly found for E. coli genes have been almost completely explained (Ikemura, 1981a, b). In the present paper, tRNAs of the yeast Saccharomyces cerevisiae were separated by two-dimensional polyacrylamide gel electrophoresis and the relative abundance of purified tRNA molecules was measured on the basis of molecular numbers in cells. A strong correlation between tRNA abundance and codon choice was found for each nuclear gene of yeast, but the correlation was less significant for 2μ plasmid genes. According to the criteria proposed for E. coli genes (Ikemura, 1981b) the order of codon preference in yeast nuclear genes was predicted based on the abundance of yeast isoaccepting tRNAs and on the nature of the modified nucleotides at their anticodons. Clear correlations between predictions and the actual preferences among synonymous codons were revealed, indicating that the codon choices in yeast genes are also constrained by a combination of tRNA availability and nature of its codon recognition. Then the difference in synonymous codon use between the two organisms can be attributed to the difference in these two factors.