Regulatory motifs identified from a maize developmental coexpression network

Transcriptional control is an important determinant of plant development, and distinct modules of coordinated genes characterize the maize developmental transcriptome. Upstream regulatory sequences are often the primary factors that control gene expression pattern and abundance. Here, we identify 244 regulatory motifs that are significantly enriched within 24 gene expression modules previously constructed from transcript abundances of 34 876 Zea mays (maize) gene models from embryogenesis to senescence. Within modules, we identify motifs that have not been characterized. In addition, we identify motifs similar to experimentally verified motifs, and the functions of these motifs overlap with predicted module functions. This work demonstrates the power of transcript-level coexpression modules to identify both variants of known regulatory motifs and novel motifs that control a species’ developmental transcriptome.

Identification of a Gain-of-Function SNP Causing a New Model of α-Thalassaemia.

The human α globin cluster includes an embryonic gene ζ and 2 fetal/adult genes (α2 and α1) arranged along the chromosome in the order in which they are expressed in development (5′-ζ-pseudoζ- αD- α2-α1-𝛉-3′). Fully activated expression of these genes in erythroid cells depends on upstream regulatory elements of which HS-40, located 40kb upstream of the cluster, appears to exert the greatest effect. We have recently shown that during terminal differentiation, key transcription factors (GATA-2, GATA-1, NF-E2, SCL complex) sequentially bind the α promoters and their regulatory elements and a domain of histone acetylation develops which eventually encompasses the entire α globin cluster including the upstream regulatory sequences. α-thalassemia most frequently results from deletions or point mutations affecting the structural α globin genes, but may also result from rare sporadic deletions which remove the upstream regulatory sequences. In a single family α globin expression was silenced by a mutation which drives an anti-sense RNA through the α gene. Alpha thalassemia may also result from inherited and acquired mutations in a trans-acting factor called ATRX. Over the past few years we have continued to screen for new mechanisms which lead to α thalassemia and thereby elucidate new principles underlying the regulation of gene expression in hemopoiesis. Here we describe a new mechanism of α thalassemia occurring in Pacific Islanders in whom we could detect no mutations or rearrangements in the α globin gene locus. Despite this, extensive genetic analysis showed unequivocally that the causative mutation is linked to the terminal 169kb of chromosome 16 (Viprakasit et al accompanying abstract). Analysis of globin synthesis, steady state RNA levels and detection of RNA in situ demonstrated that the mutation downregulates α globin transcription. To identify the mutation, we constructed a new BAC library from an affected homozygote, isolated and re-sequenced the candidate region and focussed further analysis on 8 SNPS within the α globin cluster, one of which creates a new GATA-1 binding site (GACA>GATA). Using primary erythroblasts from normal individuals and patients with this form of thalassemia, together with interspecific hybrids containing either the normal or abnormal copy of chromosome 16, we have shown that this SNP creates a new binding site in vivo for GATA-1 and the SCL complex. Furthermore, the chromatin at this site becomes activated as judged by acetylation of histone H3 and H4 (H3ac2 and H4ac4) and methylation of histone H3 (H3K4me2). Based on these data we postulate that an active transcriptional complex binding this new GATA site created by the SNP-mutation, could distract the upstream regulatory regions, which normally interact with the α globin promoter, and silence α globin gene expression. This model thus represents a new example of α globin gene down-regulation and a new mechanism by which gene expression can be perturbed during hemopoiesis.

Interaction of Ler at the LEE5 (tir) Operon of Enteropathogenic Escherichia coli

ABSTRACT The genome of enteropathogenic Escherichia coli (EPEC) encodes a global regulator, Ler (locus of enterocyte effacement [LEE]-encoded regulator), which activates expression of several polycistronic operons within the 35.6-kb LEE pathogenicity island, including the LEE2-LEE3 divergent operon pair containing overlapping −10 regions and the LEE5 (tir) operon. Ler is a predicted 15-kDa protein that exhibits amino acid similarity with the nucleoid protein H-NS. In order to study Ler-mediated activation of virulence operons in EPEC, we used a molecular approach to characterize the interactions of purified Ler protein with the upstream regulatory sequences of the LEE5 operon. We determined the cis-acting DNA sequences necessary for Ler binding at LEE5 by mobility shift and DNase I protection assays, demonstrating that Ler acts directly at LEE5 by binding sequences between positions −190 and −73 in relation to the transcriptional start site. Based on the molecular weight of Ler, the similarity to H-NS, and the extended region of protection observed in a DNase I footprint at LEE5, we hypothesized that multiple Ler proteins bind upstream of the LEE5 promoter to increase transcriptional activity from a distance. Using an hns deletion strain, we demonstrated that like the LEE2-LEE3 operon pair, H-NS represses LEE5 transcription. We describe a model in which Ler activates transcription at both divergent overlapping paired and single promoters by displacing H-NS, which results in the disruption of a repressing nucleoprotein complex.

Control of Meiotic Recombination and Gene Expression in Yeast by a Simple Repetitive DNA Sequence That Excludes Nucleosomes

ABSTRACT Tandem repeats of the pentanucleotide 5′-CCGNN (where N indicates any base) were previously shown to exclude nucleosomes in vitro (Y.-H. Wang and J. D. Griffith, Proc. Natl. Acad. Sci. USA 93:8863–8867, 1996). To determine the in vivo effects of these sequences, we replaced the upstream regulatory sequences of the HIS4 gene ofSaccharomyces cerevisiae with either 12 or 48 tandem copies of CCGNN. Both tracts activated HIS4 transcription. We found that (CCGNN)12 tracts elevated meiotic recombination (hot spot activity), whereas the (CCGNN)48 tract repressed recombination (cold spot activity). In addition, a “pure” tract of (CCGAT)12 activated both transcription and meiotic recombination. We suggest that the cold spot activity of the (CCGNN)48 tract is related to the phenomenon of the suppressive interactions of adjacent hot spots previously described in yeast (Q.-Q. Fan, F. Xu, and T. D. Petes, Mol. Cell. Biol. 15:1679–1688, 1995; Q.-Q. Fan, F. Xu, M. A. White, and T. D. Petes, Genetics 145:661–670, 1997; T.-C. Wu and M. Lichten, Genetics 140:55–66, 1995; L. Xu and N. Kleckner, EMBO J. 16:5115–5128, 1995).