Comparative analysis of sequence variability in the upstream regulatory region of the HLA-DQB1 gene

The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession number X74230-X74239.     

Short repeated elements in the upstream regulatory region of the SUC2 gene of Saccharomyces cerevisiae.

Expression of secreted invertase from the SUC2 gene is regulated by carbon catabolite repression. Previously, an upstream regulatory region that is required for derepression of secreted invertase was identified and shown to confer glucose-repressible expression to the heterologous promoter of a LEU2-lacZ fusion. In this paper we show that tandem copies of a 32-base pair (bp) sequence from the upstream regulatory region activate expression of the same LEU2-lacZ fusion. The level of expression increased with the number of copies of the element, but was independent of their orientation; the expression from constructions containing four copies of the sequence was only twofold lower than that when the entire SUC2 upstream regulatory region was present. This activation was not significantly glucose repressible. The 32-bp sequence includes a 7-bp motif with the consensus sequence (A/C)(A/G)GAAAT that is repeated at five sites within the upstream regulatory region. Genetic evidence supporting the functional significance of this repeated motif was obtained by pseudoreversion of a SUC2 deletion mutant lacking part of the upstream region, including two copies of the 7-bp element. In three of five pseudorevertants, the mutations that restored high-level SUC2 expression altered one of the remaining copies of the 7-bp element.     

Three distinct regulatory elements comprise the upstream promoter region of the nopaline synthase gene

Summary Fine deletion mutants were generated in the upstream control region of the nopaline synthase (nos) promoter to define the position and role of upstream regulatory elements. The results indicated that the 8 bp sequence (CAGAAACC) at -106/-113 and its inverted repeat (GGTTTCTG) at -140/-147 are important for promoter function. The downstream element appears more important than the upstream element since deletion of the former reduced promoter activity more significantly than deletion of the latter. Deletion of the element alone, however, did not abolish promoter function, whereas, deletion of the 10 bp potential Z-DNA-forming (Z) element located between the repeat elements nullified promoter activity. Therefore, it appears that the Z element is an essential upstream regulator and the repeated elements are upstream modulators of the nos promoter. These elements are functionally distinct since alteration of stereospecificity or insertion of short oligonucleotides between the elements did not significantly influence promoter activity. These regulatory elements were unable to function from 200 bp upstream of the CCAAT-TATA box region.     

Polymorphism in regulatory gene sequences

The extensive polymorphism revealed in non-coding gene-regulatory sequences, particularly in the immune system, suggests that this type of genetic variation is functionally and evolutionarily far more important than has been suspected, and provides a lead to new therapeutic strategies.     

Polymorphism in regulatory gene sequences

The extensive polymorphism revealed in non-coding gene-regulatory sequences, particularly in the immune system, suggests that this type of genetic variation is functionally and evolutionarily far more important than has been suspected, and provides a lead to new therapeutic strategies.     

An upstream regulatory region mediates high-level, tissue-specific expression of the human alpha 1(I) collagen gene in transgenic mice.

Studies in vitro have not adequately resolved the role of intronic and upstream elements in regulating expression of the alpha 1(I) collagen gene. To address this issue, we generated 12 separate lines of transgenic mice with alpha 1(I) collagen-human growth hormone (hGH) constructs containing different amounts of 5'-flanking sequence, with or without most of the first intron. Transgenes driven by 2.3 kb of alpha 1(I) 5'-flanking sequence, whether or not they contained the first intron, were expressed at a high level and in a tissue-specific manner in seven out of seven independent lines of transgenic mice. In most tissues, the transgene was expressed at levels approaching that of the endogenous alpha 1(I) gene and was regulated identically with the endogenous gene as animals aged. However, in lung, expression of the transgene was anomalously high, and in muscle, expression was lower than that of the endogenous gene, suggesting that in these tissues other regions of the gene may participate in directing appropriate expression. Five lines of mice were generated containing transgenes driven by 0.44 kb of alpha 1(I) 5'-flanking sequence (with or without the first intron), and expression was detected in four out of five of these lines. The level of expression of the 0.44-kb constructs in the major collagen-producing tissues was 15- to 500-fold lower than that observed with the longer 2.3-kb promoter. While transgenes containing the 0.44-kb promoter and the first intron retained a modest degree of tissue-specific expression, those without the first intron lacked tissue specificity and were poorly expressed in all tissues except lung. These results contribute to our understanding of the role of the first intron in regulating alpha1(I) gene expression and identify a region, upstream of the basal alpha1(I) promotor, which is necessary for full tissue-specific, developmentally regulated expression of the alpha1(I) collagen gene.     

A long region upstream of the IME1 gene regulates meiosis in yeast

Summary Meiosis and sporulation in yeast are subject to two types of regulation. The first depends on environmental conditions. The second depends on a genetic pathway which involves the control of the positive regulatory gene IME1 by RME1, which is in turn controlled by the MAT locus. The presence of IME1 on a multicopy plasmid enables cells to undergo meiosis regardless of their genotype at MAT or RME1. We show here that a multicopy plasmid carrying IME1 also enables meiosis, regardless of the environment. Therefore, both kinds of regulation appear to act through IME1. Furthermore, the behavior of multicopy plasmids carrying various segments from the IME1 region suggests that the region upstream of IME1 contains both positive and negative regulatory sites. Control of IME1 by the environment and by the MAT pathway both act through negative regulatory sites.     

Comparison of two yeast invertase genes: conservation of the upstream regulatory region.

The yeast genome contains a dispersed family of invertase structural genes (SUC1-SUC5, SUC7). Five of these genes are located very close to telomeres and are flanked by large regions of homologous sequence; recombination between telomeres could account for the dispersal of these SUC genes to different chromosomes. The SUC2 locus, in contrast, is not near a telomere and does not share large regions of flanking homology with the other loci. We examine here the relationship between SUC2 and one of the telomeric genes, SUC7. Sequence comparison revealed homology extending from about position -624 to +1791, which is close to the end of the mRNA. The 5' noncoding sequence includes two highly conserved regions: the region between -140 and +1, which contains the TATA box and presumably other promoter elements, and a second region extending from -508 to -400, which corresponds to the upstream regulatory region.     

用ＰＣＲ—ＳＳＯ方法研究云南西部彝族ＨＬＡ—ＤＱＢ１基因的多态性

应用ＰＣＲ－ＳＳＯ基因分型技术,对我国云南西部地区３代内无血缘关系的７６个彝族健康个体进行了ＬＡ－ＤＱＢ１位点的基因分型。结果显示,在ＤＱＢ１的３８个等位基因中,观察到１３个等位基因,云南西彝族表现为ＤＱＢ１＊０３０１（３６．１８％－３６．８４％）最常见。其他频率大于５％的等位基因还有ＤＱＢ１＊０５０２（１０．５３％－１１．１８％）、ＤＱＢ１＊０４０１（９．２１％）、ＤＱＢ１＊０３０２（８．５５％－９．２１％）、ＤＱＢ１*0601(7．８９％）ＤＱＢ１＊０５０３１（６．５８％）、ＤＱＢ１＊０３０３２（５．９２％－６．５８％）。和其他１３个华人群体ＤＱＢ１等位基因的频率比较分析表明,总体上,云南西彝族和其他各华人群体间都存在很大的差异。显示其ＨＬＡ等位基因频率分布的民族独特性。