Sequence homology to the Drosophila per locus in higher plant nuclear DNA and in Acetabularia chloroplast DNA

Summary In plant cells a DNA sequence was found which is homologous to the Drosophila per locus. In rape and spinach the homologous sequence occurs in the nuclear but not in the chloroplast genome while in Acetabularia it is found in the chloroplast but not in the nuclear genome. A 1.175 kb EcoRI-SalI fragment of the chloroplast genome of Acetabularia containing the homologous sequence was subcloned into pUC12 and sequenced. The core of the 1.175 kb fragment is a repetitive tandemly arranged sequence of 43 units of the hexamer GGA ACT coding for glycine and threonine.Abbreviations MES N-morpholinoethanesulfonic acid - DTE dithioerythritol - DTT dithiothreitol - nDNA nuclear DNA - ctDNA chloroplast DNA - TEP Tris, EDTA, proteinase K buffer     

DNA from human lymphocytes contains a sequence, homologous to immunoglobulin gene kappa

DNA released by human lymphocytes and hyman blood plasma DNA were examined by the electrophoresis, electron microscopy and Southern blot hybridization. The data obtained suggested that DNA released by lymphocytes contains covalently closed circular molecules. By the technique of the Southern blot analysis it was shown that DNA released by lymphocytes and human blood plasma DNA contain discretely sized molecules homologous to the C kappa fragment of the human Ig gene.     

DNA sequence analysis of the KM19 locus linked to cystic fibrosis

Summary The PstI polymorphism detected by probe KM19 is a highly informative marker in linkage disequilibrium with the cystic fibrosis locus and has been used extensively for prenatal diagnosis. The currently available primers used for polymerase chain reaction- (PCR-) based analysis of this locus have been shown to produce spurious amplification products. In this report, we describe the sequence of the KM19 locus and the major contaminating PCR product. We have used this information to design a more specific amplification procedure for analysis of the KM19 locus.     

DNA sequence of the white locus of Drosophila melanogaster

The DNA sequence of the white locus of Drosophila melanogaster is presented. This 14,100 base-pair sequence includes the region of the locus required for wild-type levels of expression and control of expression. We also report the sequence of a complementary DNA clone which established the position of the 3' end of the white RNA on this genomic sequence. The probable exon-intron structure of the gene has been predicted from the DNA sequence of the regions known to be represented in the RNA. The amino acid sequence of the protein which would be produced by translation of this RNA suggests that the white locus gene product may be a membrane protein. The DNA sequence rearrangements associated with seven insertion mutants (white-dominant-zeste-like (wDZL), white-spotted (wsp), white-honey (wh), white-zeste-mottled (wzm), white-apricot (wa), white-buff (wbf) and white-hd81b11 (whd81b11)), one deletion mutant (white-spotted 4 (wsp4)) and one internal duplication mutant (white-ivory (wi)) have been determined and positioned on the wild-type sequence. The positions of these insertions and those of previously characterized insertions associated with six other mutations suggest that some insertions within an intron may still allow the production of correctly spliced RNA, but affect the amount, and correspondingly the expression of the w locus.     

A contiguous sequence in spinach nuclear DNA is homologous to three separated sequences in chloroplast DNA

Summary A 3.4-kbp nuclear (n) DNA sequence has greater than 99% sequence homology to three segments of the chloroplast (cp) genes rps2, psbD/C, and psaA respectively. Each of these cpDNA segments is less than 3 kbp in length and appears to be integrated, at least in part, into several (>5) different sites flanked by unique sequences in the nuclear genome. Some of these sites contain longer homologies to the particular genes, while others are only homologous to smaller parts of the cp genes. Both the cpDNA fragments found in the nuclear genome and their flanking nDNA sequences are invested with short repeated A-T rich sequences but, apart from a hexanucleotide sequence and a palindromic sequence identified near each recombination point, there is no obvious structure that can suggest a mechanism of DNA transfer from the chloroplast to the nucleus in spinach.     

Maize chloroplast DNA encodes a protein sequence homologous to the bacterial ribosome assembly protein S4.

A cloned restriction fragment of maize chloroplast DNA (Bam H1 fragment 5) is shown to contain an open reading frame which encodes a basic protein of 201 amino acid residues with 40-50% sequence homology to E. coli ribosomal protein S4. Based on the experimentally determined sequence homology between the highly conserved bacterial ribosomal protein L12 and its chloroplast homologue (Bartsch M., Kimura, M. and Subramanian, A.R. (1982) Proc. Natl. Acad. Sci. USA 79, 6871), we conclude that this reading frame represents the maize chloroplast S4 gene. The nucleotide sequence of a 1100 base pair DNA segment containing the putative gene is presented.     

The location of the left-handedly curved DNA sequence affects exogenous DNA expression in vivo

The intranuclear disposition of a plasmid is extremely important for transgene expression. The effects of a left-handedly curved sequence with high histone affinity on plasmid expression were examined in vivo. A naked luciferase-plasmid was delivered into mouse liver by a hydrodynamics-based injection, and the luciferase activities were quantitated at various time points. The location of the left-handedly curved sequence determined the transgene expression, without affecting the amount of intranuclear exogenous DNA. The plasmid containing the curved sequence at the location that results in the exposure of the TATA box out of the nucleosome core showed the highest expression. These results suggest that sequences with high histone affinity could control transgene expression from plasmids in vivo.     

Identification of a disease resistance locus in Arabidopsis that is functionally homologous to the RPG1 locus of soybean

A new disease resistance locus in Arabidopsis, RPS3 , was identified using a previously cloned avirulence gene from a non- Arabidopsis pathogen. The avrB avirulence gene from the soybean pathogen Pseudomonas syringae pv. glycinea was transferred into a P. syringae pv. tomato strain that is virulent on Arabidopsis , and conversion to avirulence was assayed on Arabidopsis plants. The avrB gene had avirulence activity on most, but not all, Arabidopsis ecotypes. Of 53 ecotypes examined, 45 were resistant to a P. syringae pv. tomato strain carrying avrB , and eight were susceptible. The inheritance of this resistance was examined using crosses between the resistant ecotype Col-0 and the susceptible ecotype Bla-2. In F₂ plants from this cross, the ratio of resistant:susceptible plants was approximately 3:1, indicating that resistance to P. syringae expressing avrB is determined by a single dominant locus in ecotype Col-0, which we have designated RPS3 . Using RFLP analysis, RPS3 was mapped to chromosome 3, adjacent to markers M583 and G4523, and ≤ 1 cM from another disease resistance locus, RPM1 . In soybean, resistance to P. syringae strains that carry avrB is controlled by the locus RPG1 . Thus, RPG1 and RPS3 both confer avrB -specific disease resistance, suggesting that these genes may be homologs.     

Duplication of a DNA sequence homologous to genes for immunoglobulin receptors and M proteins in Streptococcus pyogenes.

The nucleotide sequence of an open reading frame of 355 amino acids downstream of the IgA-binding protein gene arp4 in Streptococcus pyogenes M-type 4 has been determined. Analysis of the deduced amino acid sequence for the open reading frame shows an extensive homology to streptococcal M proteins and immunoglobulin binding proteins. Expression of the open reading frame has not been detected and the function may be as a genetic reservoir in the generation of new immunoglobulin receptors and antigenic variants of M proteins.     

Interruption of a human nuclear sequence homologous to mitochondrial DNA by a member of the KpnI 1.8 kb family.

We reported that several DNA sequences homologous to mitochondrial DNA (mtDNA) are present in the human nuclear genome (Tsuzuki et al. (1983) Gene 25, 223-229). Detailed Southern blot analyses revealed that one of such sequences is interrupted by a repetitive sequence about 1.8 kb long, and that the insert is one member of the dispersed repeated DNA sequences of the KpnI 1.8 kb family. Nucleotide sequence analysis showed that the KpnI 1.8 kb DNA is flanked with imperfect 15-base pair (bp) direct repeats of mtDNA. This KpnI 1.8 kb DNA has an A-rich sequence at its 3'-end, and has a considerable homology with one of the published cDNA sequences homologous to one of the human KpnI families and also to one of the African green monkey KpnI families, KpnI-LS1. These structural features suggest that the KpnI 1.8 kb DNA is a movable element and is inserted within the mtDNA-like sequence by an RNA-mediated process.     

DNA sequence determination of gamma-radiation-induced mutations of the hamster aprt locus

From a collection of 85 independent gamma-radiation hamster aprt- mutants, 27 having no major structural alterations were analysed at the nucleotide level by using the polymerase chain reaction to amplify mutant exons and then directly sequencing the double-stranded products. The majority of these mutations were simple base substitutions of all types, particularly transversions (11/27). Frameshifts and small deletions were also induced. The 'spectrum' of mutations produced by gamma-radiation was not significantly different from that occurring spontaneously at this locus. Differences with respect to the target and structure of frameshifts and small deletions occurring in the two collections were apparent.     

DNA sequence variability at the rplX locus of Bacillus subtilis.

The pattern and extent of DNA sequence variability at the rplX locus (encoding ribosomal protein L24) has been investigated in nine strains of Bacillus subtilis. Overall, there is a very low level of nucleotide diversity, even at silent sites, which is probably due to selection among synonymous codons. By analogy with Escherichia coli, there may also be some effect of the relative proximity of rplX to the chromosomal origin of replication. The small number of nucleotide substitutions are non-randomly distributed: all of the synonymous changes are in valine codons. From the sequence differences the strains can be divided into two groups, which are not coincident with their previous classification; this observation is consistent with recombination among strains.     

Mitochondrial DNA evolution in theDrosophila nasuta subgroup of species

Summary TheDrosophila nasuta group consists of about 12 closely related species distributed throughout the Indo-Pacific region. They are of great interest because of their evolutionary idiosyncrasies including little morphological differentiation, the ability to intercross in the laboratory often producing fertile offspring, and substantial chromosomal evolution. Studies of metric traits, reproductive isolation, and chromosomal and enzyme polymorphisms have failed to resolve the phylogeny of the species. We report the results of a survey of the mitochondrial DNA (mtDNA) restriction patterns of the species. The phylogeny obtained is consistent with other available information and suggests thatD. albomicans may represent the ancestral lineage of the group. The amount of polymorphism in local populations (=1.0% per site) is within the typical range observed in other animals, includingDrosophila. The degree of differentiation between species is, however, low: the origin of the group is tentatively dated about 6–8 million years ago. This study confirms the usefulness of mtDNA restriction patterns for ascertaining the phylogeny of closely related species.     

HOMED: a homologous sequence editor

The alignment of homologous sequences with each other and theirdisplay has proved a–difficult task, despite a frequentrequirement for this process. HOMED enables related sequencesto be edited and listed in parallel with each other. The editorfunction uses a full screen editor which emulates the text editorsKED and EDT (on PDP–11 and VAX–11 respectively)and which can be adapted to emulate other text editors. Thisemulation has been adopted to simplify user learning of editingfunctions. HOMED provides functions for listing the sequencesin a variety of formats and for generating a consensus sequenceas well as providing a series of tools for maintenance of thesequence database. HOMED has been implemented in Pascal in amodular fashion to enhance portability. Received on November 27, 1986; accepted on January 8, 1987     

Effect of DNA sequence divergence on homologous recombination as analyzed by a random-walk model

A point connecting a pair of homologous regions of DNA duplexes moves along the homology in a reaction intermediate of the homologous recombination. Formulating this movement as a random walk, we were previously successful at explaining the dependence of the recombination frequency on the homology length. Recently, the dependence of the recombination frequency on the DNA sequence divergence in the homologous region was investigated experimentally; if the methyl-directed mismatch repair (MMR) system is active, the logarithm of the recombination frequency decreases very rapidly with an increase of the divergence in a low-divergence regime. Beyond this regime, the logarithm decreases slowly and linearly with the divergence. This "very rapid drop-off" is not observed when the MMR system is defective. In this article, we show that our random-walk model can explain these data in a straightforward way. When a connecting point encounters a diverged base pair, it is assumed to be destroyed with a probability that depends on the level of MMR activity.