Asynchronous distance between homologous DNA sequences

The distance between homologous DNA sequences of two species is proposed to be -1/4 ln[det(P)], where P is the conditional probability matrix specifying the proportions of the various nucleotides in the second sequence, corresponding to each of the four nucleotides in the first sequence. A probability model is described which supports this choice of distance. Distance measures based on a constant evolutionary rate assumption are described and compared with the proposed measure. Sampling properties of both types of distance are examined and we conclude by applying the distance measures to mitochondrial DNA sequences of the hominoids.     

Upstream curved sequences influence the initiation of transcription at the Escherichia coli galactose operon.

The two overlapping promoters that control mRNA synthesis at the galactose operon contain three phased stretches of adenine residues, located around positions -84.5, -74 and -63, with respect ot the start of the P1 promoter. As a result, the corresponding DNA sequence is bent, an anomaly that is relieved by the addition of small concentrations of drugs like distamycin A or netropsin. By abortive initiation assays performed on several DNA fragments derived from the wild-type promoter or from various mutants we show that the curved sequence increases the strength of the P1 promoter. In the absence of cyclic AMP (cAMP) and of the corresponding receptor protein (CRP), the upstream curved sequences enhance the rate of isomerization from the closed to the open complex at P1. This effect is abolished when distamycin A is bound in the bent region. In the presence of cAMP-CRP, a more drastic change is observed: activation of the gal P1 promoter takes place at a different formal step, depending whether the upstream curved sequence is present or not (enhancement of the rate of conversion from a closed to an open complex instead of an increase in the affinity of the enzyme during closed complex formation). These data, together with previous results obtained with other mutants of the gal control region, suggest that several closed complexes corresponding to different nucleoprotein arrangements are formed during open complex formation at gal P1, in the presence of CRP.     

Identification of DNA sequences flanking T-DNA insertions by PCR-walking

In recent years, concerns over genetic modification issues have resulted in regulatory authorities requiring comprehensive analysis of transgene insertion events in the plants that are to be commercialized. Determining that plants are devoid of vector backbone sequences is a trivial task that is best achieved by Southern blot analysis; however, identifying the DNA sequences flanking the T-DNA insertions can be arduous. In this paper, we present a robust method of characterizing this insertion event. We have applied and modified a genomic walking method that combines vectorette and suppression PCR walking.     

Degradative potential of Stenotrophomonas strain HPC383 having genes homologous to dmp operon

A strain, Stenotrophomonas HPC383 is isolated from effluent treatment plant treating wastewater from pesticide industry; degrades various aromatic compounds (cresols, phenol, catechol, 4methyl-catechol and hydroquinone) and crude oil, as determined through HPLC and GC analysis. Culture HPC383 could degrade (%) various compounds (1 mM) from a mixture: phenol - 99, p-cresol - 100, 4-methylcatechol - 96 and hydroquinone - 43 within 48 h of incubation, whereas it took 7 days to degrade 94% of 0.5% crude oil. Gene locus dmpN, to identify phenol degrading capacity was determined by PCR followed by southern analysis. The sequenced DNA fragment exhibited 99% sequence similarity to phenol hydroxylase gene from Arthrobacter sp. W1 (FJ610336). Amino acid sequence analysis of phenol hydroxylase reveals it to belong to high-Ks (affinity constant) group. Application of HPC383 in bioremediation of aquatic and terrestrial sites contaminated with petrochemical has been suggested.     

GC-rich DNA sequences block homologous recombination in vitro

The capacity of the RecA protein of Escherichia coli to promote an essential step in homologous recombination, strand transfer, was tested on DNA substrates varying in percentage GC. GC content was determined by a novel method using the polymerase chain reaction. Strand transfer activity is greatly reduced as a function of increasing GC content of the DNA. Some reduction is observed with substrates having a GC percentage similar to that of E. coli. The transfer reaction between sequences adjacent, but not distal, to GC-rich sequences is similarly decreased, suggesting that the structure of RecA-DNA complexes may differ with the GC content of DNA. Our results implicate an important role of DNA sequence in homologous recombination and suggest that many sequences are excluded due to their GC content.     

I-BasI and I-HmuI: two phage intron-encoded endonucleases with homologous DNA recognition sequences but distinct DNA specificities

I-HmuI and I-BasI are two highly similar nicking DNA endonucleases, which are each encoded by a group I intron inserted into homologous sites within the DNA polymerase genes of Bacillus phages SPO1 and Bastille, respectively. Here, we present a comparison of the DNA specificities and cleavage activities of these enconucleases with homologous target sites. I-BasI has properties that are typical of homing endonucleases, nicking the intron-minus polymerase genes in either host genome, three nucleotides downstream of the intron insertion site. In contrast, I-HmuI nicks both the intron-plus and intron-minus site in its own host genome, but does not act on the target from Bastille phage. Although the enzymes have distinct DNA substrate specificities, both bind to an identical 25bp region of their respective intron-minus DNA polymerase genes surrounding the intron insertion site. The endonucleases appear to interact with the DNA substrates in the downstream exon 2 in a similar manner. However, whereas I-HmuI is known to make its only base-specific contacts within this exon region, structural modeling analyses predict that I-BasI might make specific base contacts both upstream and downstream of the site of intron insertion. The predicted requirement for base-specific contacts in exon 1 for cleavage by I-BasI was confirmed experimentally. This explains the difference in substrate specificities between the two enzymes, including the observation that the former enzyme is relatively insensitive to the presence of an intron upstream of exon 2. These differences are likely a consequence of divergent evolutionary constraints.     

Mutual information content of homologous DNA sequences

The necessary information to reproduce and keep an organism is codified in acid nucleic molecules. Deepening the knowledge about how the information is stored in these bio-sequences can lead to more efficient methods of comparing genomic sequences. In the present study, we analyzed the quantity of information contained in a DNA sequence that can be useful to identify sequences homologous to it. To reach it, we used signal processing techniques, specially spectral analysis and information theory.     

Transiently beneficial insertions could maintain mobile DNA sequences in variable environments

The maintenance of mobile DNA sequences in clonal organisms has been seen as a paradox. If selfish mobile sequences spread through genomes only by overreplication in transposition, then sexuality is necessary for their spread through populations. The persistence of bacterial transposable elements without obvious dominant selectable markers has previously been explained by horizontal transfer. However, advantageous insertions of mobile DNAs are known in bacteria. Here we model maintenance of an otherwise selfish mobile DNA element in a clonal species in which selection for null mutations occurs during one of two temporally alternating environments. Large areas of parameter space permit maintenance of mobile DNAs where, without selection, they would have gone extinct. Horizontal transfer diminishes, rather than enhances, mean copy number. In finite populations, effective population sizes are greatly reduced by selective sweeps, and mean copy number can be increased as the reduced variance in copy number results in reduced selection.     

Distribution of sequences homologous to the impCAB operon of TP110 among bacterial plasmids of different incompatibility groups

Summary Mutagenic DNA repair is a function of many naturally occurring plasmids belonging to several different incompatibility groups. A DNA probe corresponding to the impCAB operon of the IncIl plasmid TP110, which encodes such functions, was used to investigate the distribution of homologous sequences in both related and unrelated plasmids. Southern blotting was used to demonstrate considerable sequence conservation amongst a number of plasmid types, with imp-related sequences being found on plasmids belonging to the I1, I1/B, B and FIV incompatibility groups. However, no homology was detected amongst plasmids of the N and L/M incompatibility groups, many of which carry functionally similar gene clusters. It appears that sequences determining mutagenic repair functions have been largely conserved within any one incompatibility group, but that significant divergent evolution has occurred between groups.     

Two homologous domains of similar structure but different stability in the yeast linker histone, Hho1p

The Saccharomyces cerevisiae homologue of the linker histone H1, Hho1p, has two domains that are similar in sequence to the globular domain of H1 (and variants such as H5). It is an open question whether both domains are functional and whether they play similar structural roles. Preliminary structural studies showed that the two isolated domains, GI and GII, differ significantly in stability. In 10 mM sodium phosphate (pH 7), the GI domain, like the globular domains of H1 and H5, GH1 and GH5, was stably folded, whereas GII was largely unstructured. However, at high concentrations of large tetrahedral anions (phosphate, sulphate, perchlorate), which might mimic the charge-screening effects of DNA phosphate groups, GII was folded. In view of the potential significance of these observations in relation to the role of Hho1p, we have now determined the structures of its GI and GII domains by NMR spectroscopy under conditions in which GII (like GI) is folded. The backbone r.m.s.d. over the ordered residues is 0.43 A for GI and 0.97 A for GII. Both structures show the "winged-helix" fold typical of GH1 and GH5 and are very similar to each other, with an r.m.s.d. over the structured regions of 1.3 A, although there are distinct differences. The potential for GII to adopt a structure similar to that of GI when Hho1p is bound to chromatin in vivo suggests that both globular domains might be functional. Whether Hho1p performs a structural role by bridging two nucleosomes remains to be determined.     

Length and interspersion of repetitive and non repetitive DNA sequences in four Amphibian species with different genome sizes

The interspersion period of repetitive and unique sequences was analyzed by two different methods, electron microscopy and agarose gel electrophoresis, for four Amphibian species with different nuclear DNA content, namely the Anura Xenopus laevis (3 pg DNA per haploid genome) and Bufo bufo (7 pg) and the Urodela Triturus cristatus (23 pg) and Necturus maculosus (52 pg). Within each of the two subclasses it has been found that interspecific differences, in DNA content, due to variations in the amount of repetitive sequences, do not involve variations in length of the interspersed repetitive sequences. They remain about 380 base pairs. Furthermore, the unique sequences length has been found to be shorter in Bufo (760 base pairs) than in Xenopus (1600) and in Necturus (880) than in Triturus (1340). A study of the interspersion period has shown that the great difference in DNA content between Anura and Urodela, which had been previously shown not to have involved changes in the relative amounts of the various sequence classes, does not involve changes in the interspersion period.     

An improved PCR-based amplification of unknown homologous DNA sequences

The PCR primers used for cloning of evolutionary conserved genes or homologous DNA sequences are usually guessmer oligonucleotides. We introduce a simple way using Pfu polymerase to overcome possible PCR amplification failure because of 3'-end mismatches of guessed primers with the target DNA.