Chromosomal arrangement of leghemoglobin genes in soybean.

A cluster of four different leghemoglobin (Lb) genes was isolated from AluI-HaeIII and EcoRI genomic libraries of soybean in a set of overlapping clones which together include 45 kilobases (kb) of contiguous DNA. These four genes, including a pseudogene, are present in the same orientation and are arranged in the order: 5'-Lba-Lbc1-Lb psi-Lbc3-3'. The intergenic regions average 2.5 kb. In addition to this main Lb locus, there are other Lb genes which do not appear to be contiguous to this locus. A sequence probably common to the 3' region of Lb loci was found flanking the Lbc3 gene. The 3' flanking region of the main Lb locus also contains a sequence that appears to be expressed more abundantly in root tissue. Another sequence which is primarily expressed in root and leaf is found 5' to two Lb loci. Overall, the main leghemoglobin locus is similar in structure to the mammalian globin gene loci.     

Preparation of a complementary DNA for leghaemoglobin and direct demonstration that leghaemoglobin is encoded by the soybean genome

In soybean root nodules, leghaemoglobin (Lb) accounts for 25--30% of the total soluble protein but is not detected in other tissues. In order to determine whether the Lb genes are plant or bacterial in origin a cDNA probe for Lb was prepared from 9S poly (A) containing mRNA of root nodules. Although this 9S mRNA directed synthesis of predominantly three forms of Lb in vitro, the kinetics of hybridisation of cDNA and the 9S mRNA showed a transition at about 30% hybridisation which suggested that the 9S-cDNA was not pure Lb-cDNA. The abundant, Lb-cDNA was prepared by two cycles of hybridising 9S mRNA and cDNA to a Rot of 3 X 10(-3) and isolation of the hybridised cDNA on hydroxyapatite. The Lb-cDNA was homogeneous in hybridisation analysis with 9S mRNA and electrophoresis in 98% formamide gels. This cDNA hybridised with soybean DNA and not with Rhizobium DNA, thus directly demonstrating that Lb genes are of plant origin. Titration of Lb-cDNA with soybean DNA showed that Lb genes are reiterated about forty-fold per haploid genome.     

Nonuniform recombination within the human beta-globin gene cluster.

Population genetic analysis of 15 restriction site polymorphisms demonstrates nonuniform recombination within the human beta-globin gene cluster. These DNA polymorphisms show two clusters of high nonrandom associations, one 5' and another 3' to the beta-globin structural gene, with no significant linkage disequilibrium between the two clusters. The 5'- and 3'-association clusters are 34.6 kilobases (kb) and 19.4 kb long, respectively, and are separated by 9.1 kb of DNA immediately 5' to the beta-globin gene. For each of these three DNA regions, we have observed a relationship between nonrandom associations and physical distance between the polymorphisms. However, this relationship differed for each of these regions. On the assumption that the effective population size (Ne) is 5,000-50,000, we estimate the total recombination rate to be 0.0017%-0.0002% in the 5' cluster, 0.0931%-0.0093% in the 3' cluster, and 0.2912%-0.0219% in the 9.1-kb region between them. The beta cluster thus shows nonuniformity in recombination. Moreover, the recombination rate in the 9.1-kb DNA segment is 3-30 times greater than expected and is thus a hot spot for meiotic recombination.     

Structure and chromosomal arrangement of leghemoglobin genes in kidney bean suggest divergence in soybean leghemoglobin gene loci following tetraploidization

We have determined the structure of one of the leghemoglobin (Lb) genes of Phaseolus vulgaris (kidney bean) and deduced the chromosomal arrangement of leghemoglobin genes by genomic hybridizations with Lb and two other sequences, each specific to the 5' or 3' region of the soybean leghemoglobin loci. By comparing this organization with two other species of legumes, Glycine max (soybean) and G. soja (wild soybean), a phylogeny of leghemoglobin gene loci was traced. The intragenic structure of the kidney bean leghemoglobin gene shows the same intron/exon arrangement as that of soybean leghemoglobin genes and extensive sequence homologies in both coding as well as 5' and 3' non-coding regions. The presence in the kidney bean genome of four leghemoglobin genes suggests that tandem duplications of a single primordial plant globin gene had occurred to generate four leghemoglobin genes in an `Lb-locus' before Glycine and Phaseolus species diverged. Chromosome duplication by tetraploidization in Glycine generated two loci containing four genes each. A large deletion in one of the two four-gene loci in soybean resulted in the generation of the Lbc₂ locus containing two leghemoglobin genes, one functional and another pseudo (LbΨ₂). This pseudogene, unlike that present on the main locus, is represented by only two and a half exons and appears to be truncated. The two other truncated genes (LbT₁ and LbT₂) were probably generated similarly in the genome of Glycine spp. following tetraploidization before the divergence of G. max and G. soja.     

Staphylococcus aureus has clustered tRNA genes.

The polymerase chain reaction (PCR) was used to detect large tRNA gene clusters in Bacillus subtilis, Bacillus badius, Bacillus megaterium, Lactobacillus brevis, Lactobacillus casei, and Staphylococcus aureus. The primers were based on conserved sequences of known gram-positive bacterial tRNA(Arg) and tRNA(Phe) genes. This PCR procedure detected an unusually large tRNA gene cluster in S. aureus. PCR-generated probes were used to identify a 4.5-kb EcoRI fragment that contained 27 tRNA genes immediately 3' to an rRNA operon. Some of these 27 tRNA genes are very similar, but only 1 is exactly repeated in the cluster. The 5' end of this cluster has a gene order similar to that found in the 9- and 21-tRNA gene clusters of B. subtilis. The 3' end of this S. aureus cluster exhibits more similarity to the 16-tRNA gene cluster of B. subtilis. The 24th, 25th, and 26th tRNA genes of this S. aureus tRNA gene cluster code for three similar, unusual Gly-tRNAs that may be used in the synthesis of the peptidoglycan in the cell wall but not in protein synthesis. Southern analysis of restriction digests of S. aureus DNA indicate that there are five to six rRNA operons in this bacterium's genome and that most or all may have large tRNA gene clusters at the 3' end.     

The distribution patterns of bases of protein-coding genes, non-coding ORFs, and intergenic sequences in pseudomonas aeruginosa PA01 genome and its implications

The distribution patterns of bases of DNA fragments in different regions in P. aeruginosa genome are analyzed in this paper. It's shown that 5565 protein-coding genes, 17315 non-coding ORFs, and 1104 intergenic sequences are located into seven clusters based on their base frequencies. Almost all the protein-coding genes are contained in one of the seven clusters. The significant difference of base frequencies among three codon positions in high GC genome, which arouse the division between the distribution patterns of bases of six reading frames of protein-coding genes, is responsible for the appearance of the clustering phenomenon. In the light of the clustering phenomenon, the author supposes that the anitisense strand ORFs, particularly those corresponding to Frame 2' and Frame 3', may not code for proteins in P. aeruginosa genome.     

African trypanosome glucose transporter genes: organization and evolution of a multigene family

Trypanosoma brucei brucei (EATRO-164) contains a tandem array of six genes encoding a glucose transporter, THT1 (trypanosome hexose transporter), followed by five genes encoding a second isoform, THT2. Two distinct clusters containing THT1 and THT2 genes have been identified in the EATRO-164 clone and in most other African trypanosome clones analyzed. Analysis of progeny from crosses between clones of T. b. brucei displaying polymorphism in THT1 copy number per cluster suggests that the two clusters of THT genes are present on homologous chromosomes. In addition, analysis of 30 African trypanosome clones revealed a high degree of polymorphism in THT1 copy number per cluster. Sequence comparison of five THT1 and two and one-half THT2 unit repeats, present within a 20-kb region, provided information about the genesis and evolution of the THT multigene family. The most divergent regions between THT1 and THT2 unit repeats probably arose from insertion of DNA fragments into an ancestral THT region. Genes of each of the different families are almost identical, and there are large regions of identity shared between THT1 and THT2 members. A mosaic copy containing most of a THT1 gene with the 3' extremity of a THT2 gene is found within the cluster. These results suggest that THT1 and THT2 arose by modification (insertion, mutation, or conversion) of duplicated ancestral genes. Functional constraints and homologous recombination may be evoked to explain the maintenance of the conserved sequences of THT1 and THT2.      

Relationships of the Col plasmids E2, E3, E4, E5, E6, and E7: Restriction mapping and colicin gene fusions

Thirteen ColE plasmids representing the E2-E7 types have been compared by restriction mapping. Over 80% of their restriction sites were found to be similarly positioned, indicating that these plasmids share a common structure. Three variants are ColE2-CA42 and ColE7-K317, both of which contain 1.8-kb DNA segments in place of a 2.5-kb segment common to the other plasmids, and ColE6-CT14, which has an additional 5.0-kb DNA segment compared to the other plasmids. The colicin (col), immunity (imm), and colicin release (hic) genes of these plasmids have been localized to regions corresponding to those known for ColE3-CA38 and ColE2-P9, with the imm and hic genes adjacent to the 3' end of the col gene. Active colicin is produced from hybrid col genes containing 5' and 3' ends from different E-type plasmids. The 3'-termini of the fused col genes specify the colicin type.     

The primary structures of two leghemoglobin genes from soybean

We present the complete nucleotide sequences of two leghemoglobin genes isolated from soybean DNA. Both genes contain three intervening sequences which interrupt the two coding sequences in identical positions. The 5' and 3' flanking sequences in both genes contain conserved sequences similar to those found in corresponding positions in other eukaryotic genes. Thus, the general DNA sequence organization of these plant genes is similar to that of other eukaryotic genes.     

Comparative sequence analysis of the sorghum Rph region and the maize Rp1 resistance gene complex

A 268-kb chromosomal segment containing sorghum (Sorghum bicolor) genes that are orthologous to the maize (Zea mays) Rp1 disease resistance (R) gene complex was sequenced. A region of approximately 27 kb in sorghum was found to contain five Rp1 homologs, but most have structures indicating that they are not functional. In contrast, maize inbred B73 has 15 Rp1 homologs in two nearby clusters of 250 and 300 kb. As at maize Rp1, the cluster of R gene homologs is interrupted by the presence of several genes that appear to have no resistance role, but these genes were different from the ones found within the maize Rp1 complex. More than 200 kb of DNA downstream from the sorghum Rp1-orthologous R gene cluster was sequenced and found to contain many duplicated and/or truncated genes. None of the duplications currently exist as simple tandem events, suggesting that numerous rearrangements were required to generate the current genomic structure. Four truncated genes were observed, including one gene that appears to have both 5' and 3' deletions. The maize Rp1 region is also unusually enriched in truncated genes. Hence, the orthologous maize and sorghum regions share numerous structural features, but all involve events that occurred independently in each species. The data suggest that complex R gene clusters are unusually prone to frequent internal and adjacent chromosomal rearrangements of several types.     

Condition-specific coregulation with cis-regulatory motifs and modules in the mouse genome

Deciphering genetic regulatory codes remains a challenge. Here, we present an effective approach to identifying in vivo condition-specific coregulation with cis-regulatory motifs and modules in the mouse genome. A resampling-based algorithm was adopted to cluster our microarray data of a stress response, which generated 35 tight clusters with unique expression patterns containing 811 genes of 5652 genes significantly altered. Database searches identified many known motifs within the 3-kb regulatory regions of 40 genes from 3 clusters and modules with six to nine motifs that were commonly shared by 60-100% of these genes. The upstream regulatory region contained the highest frequency of these common motifs. CisModule program predictions were comparable with the results from database searches and found four potentially novel motifs. This result indicates that these motifs and modules could be responsible for gene coregulation of the stress response in the lacrimal gland.     

Comparative and functional analysis of the rRNA-operons and their tRNA gene complement in different lactic acid bacteria

The complete genome sequences of the lactic acid bacteria (LAB), Lactobacillus plantarum, Lactococcus lactis, and Lactobacillus johnsonii were used to compare location, sequence, organisation, and regulation of the ribosomal RNA (rrn) operons. All rrn operons of the examined LAB diverge from the origin of replication, which is compatible with their efficient expression. All operons show a common organisation of 5'-16S-23S-5S-3' structure, but differ in the number, location and specificity of the tRNA genes. In the 16S-23S intergenic spacer region, two of the five rrn operons of Lb. plantarum and three of the six of Lb. johnsonii contain tRNA-ala and tRNA-ile genes, while L. lactis has a tRNA-ala gene in all six operons. The number of tRNA genes following the 5S rRNA gene ranges up to 14, 16, and 21 for L. lactis, Lb. johnsonii and Lb. plantarum, respectively. The tRNA gene complements are similar to each other and to those of other bacteria. Micro-heterogeneity was found within the rRNA structural genes and spacer regions of each strain. In the rrn operon promoter regions of Lb. plantarum and L. lactis marked differences were found, while the promoter regions of Lb. johnsonii showed a similar tandem promoter structure in all operons. The rrn promoters of L. lactis show either a single or a tandem promoter structure. All promoters of Lb. plantarum contain two or three -10 and -35 regions, of which either zero to two were followed by an UP-element. The Lb. plantarum rrnA, rrnB, and rrnC promoter regions display similarity to the rrn promoter structure of Esherichia coli. Differences in regulation between the five Lb. plantarum promoters were studied using a low copy promoter-probe plasmid. Taking copy number and growth rate into account, a differential expression over time was shown. Although all five Lb. plantarum rrn promoters are significantly different, this study shows that their activity was very similar under the circumstances tested. An active promoter was also identified within the Lb. plantarum rrnC operon preceding a cluster of 17 tRNA genes.