Wheat beta-expansin (EXPB11) genes: Identification of the expressed gene on chromosome 3BS carrying a pollen allergen domain.

BACKGROUND: Expansins form a large multi-gene family found in wheat and other cereal genomes that are involved in the expansion of cell walls as a tissue grows. The expansin family can be divided up into two main groups, namely, alpha-expansin (EXPA) and beta-expansin proteins (EXPB), with the EXPB group being of particular interest as group 1-pollen allergens. RESULTS: In this study, three beta-expansin genes were identified and characterized from a newly sequenced region of the Triticum aestivum cv. Chinese Spring chromosome 3B physical map at the Sr2 locus (FPC contig ctg11). The analysis of a 357 kb sub-sequence of FPC contig ctg11 identified one beta-expansin genes to be TaEXPB11, originally identified as a cDNA from the wheat cv Wyuna. Through the analysis of intron sequences of the three wheat cv. Chinese Spring genes, we propose that two of these beta-expansin genes are duplications of the TaEXPB11 gene. Comparative sequence analysis with two other wheat cultivars (cv. Westonia and cv. Hope) and a Triticum aestivum var. spelta line validated the identification of the Chinese Spring variant of TaEXPB11. The expression in maternal and grain tissues was confirmed by examining EST databases and carrying out RT-PCR experiments. Detailed examination of the position of TaEXPB11 relative to the locus encoding Sr2 disease resistance ruled out the possibility of this gene directly contributing to the resistance phenotype. CONCLUSIONS: Through 3-D structural protein comparisons with Zea mays EXPB1, we proposed that variations within the coding sequence of TaEXPB11 in wheats may produce a functional change within features such as domain 1 related to possible involvement in cell wall structure and domain 2 defining the pollen allergen domain and binding to IgE protein. The variation established in this gene suggests it is a clearly identifiable member of a gene family and reflects the dynamic features of the wheat genome as it adapted to a range of different environments and uses. Accession Numbers: ctg11 =FN564426Survey sequences of TaEXPB11ws and TsEXPB11 are provided request.

The transcript repeat element: the human Alu sequence as a component of gene networks influencing cancer.

A small percentage (3%) of the 1.3 million copies of Alu sequences in the human genome is expressed individually or as part of various gene transcripts with potential regulatory and pathophysiological importance. In order to better understand the role of repetitive elements within transcripts, this review focuses on Alu-containing transcripts of normal and cancerous tissue in a transcriptome-wide survey of the H-Invitational human transcript database on 106,825 tissue-derived transcripts expressed at 29,979 loci. The Alu elements in transcripts of cancerous tissues are significantly underrepresented in comparison to those in normal tissues. In this review, we propose a model for Alu-mediated siRNA down-regulation of Alu-containing transcripts in cancer tissues. In cancer or other rapidly dividing tissues, hypomethylation of repeat element regions triggers the expression of transposon elements including Alu, which can potentially form double-stranded RNA molecules for use as templates to generate Alu-derived siRNAs (Alu-siRNAs). The generated Alu-siRNAs target endogenous messenger RNAs harbouring sequence similarity to Alu elements. This model correlates with the observation that there is substantial under-representation of Alu-containing mRNAs in cancer cells. This new perspective of gene regulation in disease conditions can provide a basis for starting to account for changes in complex gene network in cancer.

Genome sequence of the pathogenic intestinal spirochete brachyspira hyodysenteriae reveals adaptations to its lifestyle in the porcine large intestine.

Brachyspira hyodysenteriae is an anaerobic intestinal spirochete that colonizes the large intestine of pigs and causes swine dysentery, a disease of significant economic importance. The genome sequence of B. hyodysenteriae strain WA1 was determined, making it the first representative of the genus Brachyspira to be sequenced, and the seventeenth spirochete genome to be reported. The genome consisted of a circular 3,000,694 base pair (bp) chromosome, and a 35,940 bp circular plasmid that has not previously been described. The spirochete had 2,122 protein-coding sequences. Of the predicted proteins, more had similarities to proteins of the enteric Escherichia coli and Clostridium species than they did to proteins of other spirochetes. Many of these genes were associated with transport and metabolism, and they may have been gradually acquired through horizontal gene transfer in the environment of the large intestine. A reconstruction of central metabolic pathways identified a complete set of coding sequences for glycolysis, gluconeogenesis, a non-oxidative pentose phosphate pathway, nucleotide metabolism, lipooligosaccharide biosynthesis, and a respiratory electron transport chain. A notable finding was the presence on the plasmid of the genes involved in rhamnose biosynthesis. Potential virulence genes included those for 15 proteases and six hemolysins. Other adaptations to an enteric lifestyle included the presence of large numbers of genes associated with chemotaxis and motility. B. hyodysenteriae has diverged from other spirochetes in the process of accommodating to its habitat in the porcine large intestine.

Identification of genes associated with prophage-like gene transfer agents in the pathogenic intestinal spirochaetes Brachyspira hyodysenteriae, Brachyspira pilosicoli and Brachyspira intermedia.

VSH-1 is an unusual prophage-like gene transfer agent (GTA) that has been described in the intestinal spirochaete Brachyspira hyodysenteriae. The GTA does not self-propagate, but it assembles into a virus-like particle and transfers random 7.5kb fragments of host DNA to other B. hyodysenteriae cells. To date the GTA VSH-1 has only been analysed in B. hyodysenteriae strain B204, in which 11 late function genes encoding prophage capsid, tail and lysis elements have been described. The aim of the current study was to look for these 11 genes in the near-complete genomes of B. hyodysenteriae WA1, B. pilosicoli 95/1000 and B. intermedia HB60. All 11 genes were found in the three new strains. The GTA genes in WA1 and 95/1000 were contiguous, whilst some of those in HB60 were not-although in all three strains some gene rearrangements were present. A new predicted open reading frame with potential functional importance was found in a consistent position associated with all four GTAs, located between the genes for head protein Hvp24 and tail protein Hvp53, overlapping with the hvp24 sequence. Differences in the nucleotide and predicted amino acid sequences of the GTA genes in the spirochaete strains were consistent with the overall genetic distances between the strains. Hence the GTAs in the two B. hyodysenteriae strains were considered to be strain specific variants, and were designated GTA/Bh-B204 and GTA/Bh-WA1 respectively. The GTAs in the strains of B. intermedia and B. pilosicoli were designated GTA/Bint-HB60 and GTA/Bp-95/1000 respectively. Further work is required to determine the extent to which these GTAs can transfer host genes between different Brachyspira species and strains.

A promoter with bidirectional activity is located between TLX1/HOX11 and a divergently transcribed novel human gene.

The chromosomal region 10q24 is involved in reciprocal translocations with one of the T-cell receptor loci in a significant proportion of human T-cell acute lymphoblastic leukemias. The breakpoints of these rearrangements cluster immediately upstream of the TLX1 homeobox gene and lead to its transcriptional activation. Genomic analysis using sequences located on the opposite side of the breakpoint cluster region identified a novel gene composed of three exons that is oriented in a head-to-head manner with TLX1. The novel gene, named TDI (TLX1 divergent) codes for a 1.9 kb transcript with an atypically long 5' leader sequence. Although predicted to be a transcriptional regulator of 13.4 kDa, the TDI protein has no significant sequence similarity to any known protein. The TLX1 and TDI genes are separated by a short spacer of only 161 bp that contains numerous GC boxes and a centrally located CCAAT box embedded within a CpG island. Using luciferase as the reporter in transient transfection assays, the intergenic region was found to be a functional promoter with robust bidirectional activity. TLX1 and TDI thus appear to represent another example of a divergently transcribed gene pair whose expression is regulated by a common promoter. Our finding that TDI is transcriptionally co-activated in leukemic cells that aberrantly express TLX1, additionally suggests that it may have the potential to act as a co-operating oncogene in leukemogenesis.

The distribution of polymorphic Alu insertions within the MHC class I HLA-B7 and HLA-B57 haplotypes.

There are five polymorphic Alu insertion (POALIN) loci within the major histocompatibility complex (MHC) class I region that have been strongly associated with HLA class I alleles, such as HLA-A1, HLA-A2 and HLA-B57. In order to assess the variability and frequency of POALIN distribution within two common HLA-B haplotypes, we detected the presence of the MHC class I POALIN by PCR in a panel of 15 individuals with HLA-B57 and 47 homozygous individuals with 7.1 AH (HLA-B7, -Cw7, -A3) obtained from the Australian Bone Marrow Donor Registry, and also from four families (25 individuals) containing the HLA-B57 allele. Only two of the 47 HLA-B7 genotypes had a detectable POALIN, whereas all of the HLA-B57 genotypes had at least one or more POALINs present, confirming that certain MHC class I haplotypes are relatively POALIN-free and others are POALIN-enriched. Six distinct HLA-B57 haplotypes, based on differences at the HLA-A locus and three of five POALIN loci, were identified that appear to have evolved by different mechanisms, including either by shuffling different combinations of conserved alpha and beta blocks or by recombination events involving two or more previously generated HLA-B57 haplotypes.

Dimorphic Alu element located between the TFIIH and CDSN genes within the major histocompatibility complex.

Most Alu members of the large SINE family are fixed within the human genome but some younger mobile members are dimorphic, that is, they are either present or absent in the genome. Four different dimorphic Alu insertions have been identified and characterized previously within the class I region of the major histocompatibility complex (MHC). Here we report on (i) the identification and characterization of a new dimorphic Alu insertion, AluyTF, located between the transcription factor II H (TFIIH) and corneodesmosin (CDSN) genes within a region of the MHC that is telomeric of the human leukocyte antigen type B (HLA-B) locus and centromeric of the HLA-A locus, (ii) the haplotypic relationships between the AluyTF dimorphism and the HLA-A and -B loci within a panel of 48 IHW cell-lines representing at least 36 different HLA class I haplotypes, (iii) the AluyTF genotype, allele and haplotype frequencies present in the Australian caucasian and Japanese populations, and (iv) the frequency of association between the AluTF dimorphisms and HLA-A and -B alleles in 108 Australian caucasians and 99 Japanese. The AluyTF insertion was present at 27% in the IHW cell lines, and the gene frequency was 0.107 and 0.083 in the Australian caucasian and Japanese population, respectively. The Alu haplotype frequencies constructed from four different dimorphic Alu loci including AluyTF within the MHC were not significantly different (p > 0.05) between the two populations. There were no significant associations between the Alu insertion and either the HLA-A or -B alleles except for a moderately strong association with HLA-A29 in the Australians (71.7%). This polymorphic AluyTF element, along with the four other previously described polymorphic Alu elements within the class I region of the MHC, will be useful lineage and linkage markers in human population studies and for elucidating the evolution of HLA class I haplotypes.

Genomic and phylogenetic analysis of the S100A7 (Psoriasin) gene duplications within the region of the S100 gene cluster on human chromosome 1q21.

The human S100 gene family encodes the EF-hand superfamily of calcium-binding proteins, with at least 14 family members clustered relatively closely together on chromosome 1q21. We have analyzed the most recently available genomic sequence of the human S100 gene cluster for evidence of tandem gene duplications during primate evolutionary history. The sequences obtained from both GenBank and GoldenPath were analyzed in detail using various comparative sequence analysis tools. We found that of the S100A genes clustered relatively closely together within a genomic region of 260 kb, only the S100A7 (psoriasin) gene region showed evidence of recent duplications. The S100A7 gene duplicated region is composed of three distinct genomic regions, 33, 11, and 31 kb, respectively, that together harbor at least five identifiable S100A7-like genes. Regions 1 and 3 are in opposite orientation to each other, but each region carries two S100A7-like genes separated by an 11-kb intergenic region (region 2) that has only one S100A7-like gene, providing limited sequence resemblance to regions 1 and 3. The duplicated genomic regions 1 and 3 share a number of different retroelements including five Alu subfamily members that serve as molecular clocks. The shared (paralogous) Alu S insertions suggest that regions 1 and 3 were probably duplicated during or after the phase of AluS amplification some 30-40 mya. We used PCR to amplify an indel within intron 1 of the S100A7a and S100A7c genes that gave the same two expected product sizes using 40 human DNA samples and 1 chimpanzee sample, therefore confirming the presence of the region 1 and 3 duplication in these species. Comparative genomic analysis of the other S100 gene members shows no similarity between intergenic regions, suggesting that they diverged long before the emergence of the primates. This view was supported by the phylogenetic analysis of different human S100 proteins including the human S100A7 protein members. The S100A7 protein, also known as psoriasin, has important functions as a mediator and regulator in skin differentiation and disease (psoriasis), in breast cancer, and as a chemotactic factor for inflammatory cells. This is the first report of five copies of the S100A7 gene in the human genome, which may impact on our understanding of the possible dose effects of these genes in inflammation and normal skin development and pathogenesis.

The association between HLA-A alleles and young Alu dimorphisms near the HLA-J, -H, and -F genes in workshop cell lines and Japanese and Australian populations.

At least two polymorphic Alu insertions have been previously identified and characterized within the class I region of the major histocompatibility complex (MHC). We have identified another two new polymorphic Alu insertions, AluyHJ and AluyHF, located near HLA-J and HLA-F, respectively, within the a block of the MHC. Here we report on (1). the haplotypic relationships between the Alu dimorphisms and the HLA-A locus within a panel of 51 IHW homozygous cell lines representing at least 36 HLA class I haplotypes, (2). the Alu genotype, allele, and haplotype frequencies present in the Australian Caucasians and Japanese populations, and (3). the frequency of association between the different Alu dimorphisms and the HLA-A alleles in 109 Australian Caucasians and 99 Japanese. PCR was used to detect the presence or absence of insertion for AluyHJ, AluyHG, and AluyHF within the DNA samples prepared from the cell lines and the two population groups that had been previously typed for HLA-A. In the homozygous cell lines, all three Alu insertions were found in only one HLA class I haplotype (HLA-A1, -B57, -Cw6), no Alu insertions were detected in six HLA class I haplotypes and one or more of the Alu insertions were found in 29 HLA class I haplotypes. At least one of the Alu insertions was found in about 86% of the Japanese and Australian individuals, with the AluyHJ generally related inversely to AluyHG and/or AluyHF. The gene frequency of the AluyHJ and AluyHF insertions was significantly different (p <0.05) between Japanese and Australians, whereas there was no difference (P > 0.05) between the frequencies of AluyHG in the two populations. The Alu haplotype frequencies were also significantly different between the Japanese and the Australians. In the cell lines and the population groups, the AluyHJ insertion was most frequently found associated with HLA-A1 or A24, AluyHG with HLA-A2, and AluyHF with HLA-A2, -A10, or -A26. This study suggests that the three polymorphic Alu elements have been inserted into the a block of the MHC in different progenitor groups and therefore will be useful lineage and linkage markers in human population studies and for elucidating the evolution of HLA class I haplotypes.

Alu polymorphism within the MICB gene and association with HLA-B alleles.

We describe the finding of an Alu repeat dimorphism within the first intron of the MICB gene. The frequencies of the two AluyMICB alleles, AluyMICB*0(absence of insertion) and AluyMICB*1(presence of insertion), and their associations with the highly polymorphic HLA-B locus were determined for 51 human cell lines and for 109 and 200 Caucasians and northeastern Thais, respectively. Analysis of the AluyMICB and HLA-B allelic relationships revealed that AluyMICB*1 occurred at relatively low gene frequency (0.118-0.157) [corrected] but was strongly associated with HLA-B17 (HLA-B57,HLA-B58) and HLA-B13. The AluyMICB locus provides a useful dimorphic marker for investigations on the level of linkage disequilibrium between MICB, MICA, and HLA-B loci.

Distribution of erythrocytic allozymes in two sibling species of greater galago [Galago crassicaudatus E. Geoffroy 1812 and G. garnettii (Ogilby 1838)].

This study investigated the use of erythrocyte enzymes as indicators of the presence or absence of gene flow between the sibling species G. crassicaudatus and G. garnettii. Fifty-five animals deriving from 14 different source populations were included in the analyses. In addition to hemoglobin, eight enzyme systems were examined: acid phosphatase, adenylate kinase, carbonic anhydrase II, esterase D, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, peptidase A, and peptidase B. of these, adenylate kinase, glucose-6-phosphate dehydrogenase, hemoglobin, peptidase A, and peptidase B showed no interspecific or intraspecific variation. Esterase D was polymorphic in certain populations of G. crassicaudatus but not in others or in G. garnettii. Acid phosphatase and 6-phosphogluconate dehydrogenase were polymorphic in G. garnettii but monomorphic in all G. crassicaudatus populations. The taxa showed fixation for different alleles at the carbonic anhydrase II locus, indicating a lack of gene exchange between the taxa. We suggest that acid phosphatase, 6-phosphogluconate dehydrogenase, and carbonic anhydrase II may be used as genetic markers in the identification of these two taxa.