Actin genes expressed during early development ofPatella vulgata

Summary The actin gene family of the marine molluscPatella vulgata was chosen as a model system to study the regulation of genes expressed during early development in molluscs. Using a hamster actin cDNA clone as a probe, we isolated nine actin cDNA clones from trochophore larvae. The total nucleic acid sequence of three of these clones has been determined. Each clone contains the whole protein encoding region. The deduced amino acid sequences resemble actin proteins from other species to a high extent. The nucleotide sequence from the 3UTR (UnTranslated Region) and 5UTR from all nine clones has been resolved. In this way we could identify four different subtypes. Southern blots with genomic DNA were probed with different 3UTR's corresponding to each subtype to determine the genomic organization. One 3UTR detected one band probably corresponding with one gene. Another 3UTR detected one or two genes and the third 3UTR between two and four genes. Northern blots were used to detect the presence of actin mRNA during different stages of development. In the mature oocyte, actin mRNA is present in low amounts. The level of actin mRNA starts to rise steadily from 8 h after fertilization (88-cell stage) onwards. The level of the different subtype mRNAs, as specified by their 3UTR rises at different developmental stages and to various extents. This indicates that the expression of each type is regulated independently and in relation to the developmental stage of the embryo. Correspondence to: A.E. van Loon     

Sixty-nine kilobases of contiguous human genomic sequence containing the α-galactosidase A and Bruton's tyrosine kinase loci

Several disease loci have been mapped to the Xq21.3–Xq22 region of the human X Chromosome (Chr) including X-linked agammaglobulinemia (XLA), Fabry disease, Alport syndrome, and Pelizaeus Merzbacher disease. Upon cloning of the XLA gene, Bruton's tyrosine kinase (btk), both Fabry disease and XLA were mapped within the same 50- to 70-kb interval. In order to investigate the genomic organization of the region surrounding btk and the Fabry disease gene, -galactosidase A (gla), we constructed a 6-cosmid contig spanning the region from 5 of gla to 3 of btk. Two of these cosmids spanning most of the coding sequence and the upstream region of btk and gla, U237D10 and U230D1, were sequenced by a random shotgun strategy combined with automated sequencing, resulting in 69 kb of contiguous genomic sequence. Sequencing of U237D10 showed btk to be comprised of 19 exons spanning over 35 kb. Sequencing of U230D1 showed that the 3 end of gla is 9 kb from the 5 end of btk and also demonstrated the presence of two additional genes in the region immediately 5 to btk. The surprisingly high gene density is similar to that seen previously only in the human major histocompatibility locus.     

Developmental regulatory elements in the 5′ flanking DNA of the Drosophila choline acetyltransferase gene

Summary Choline acetyltransferase (ChAT, EC 2.3.1.6) catalyzes the production of the neurotransmitter acetylcholine, and is an essential factor for neurons to be cholinergic. We have analyzed regulation of the Drosophila ChAT gene during development by examining the -galactosidase expression pattern in transformed lines carrying different lengths of 5 flanking DNA fused to a lacZ reporter gene. The largest fragment tested, 7.4 kb, resulted in the most extensive expression pattern in embryonic and larval nervous system and likely reflects all the cis-regulatory elements necessary for ChAT expression. We also found that 5 flanking DNA located between 3.3 kb and 1.2 kb is essential for the reporter gene expression in most of the segmentally arranged embryonic sensory neurons as well as other distinct cells in the CNS. The existence of negative regulatory elements was suggested by the observation that differentiating photoreceptor cells in eye imaginal discs showed the reporter gene expression in several 1.2 kb and 3.3 kb transformants but not in 7.4 kb transformants. Furthermore, we have fused the 5 flanking DNA fragments to a wild type ChAT cDNA and used these constructs to transform Drosophila with a Cha mutant background. Surprisingly, even though different amounts of 5 flanking DNA resulted in different spatial expression patterns, all of the positively expressing cDNA transformed lines were rescued from lethality. Our results suggest that developmental expression of the ChAT gene is regulated both positively and negatively by the combined action of several elements located in the 7.4 kb upstream region, and that the more distal 5 flanking DNA is not necessary for embryonic survival and development to adult flies. Correspondence to: P.M. Salvaterra     

Identification of the domain of Saccharomyces cerevisiae adenylate cyclase associated with the regulatory function of RAS products

Summary Various truncated CYR1 genes of Saccharomyces cerevisiae were fused to efficient promoters and expressed in Escherichia coli and S. cerevisiae cells with or without the RAS genes. The catalytic domain of adenylate cyclase encoded by the 3-terminal 1.3 kb region of the open reading frame of the CYR1 gene produced cyclic AMP, irrespective of the presence of RAS genes. The product of the 3-terminal 2.1 kb region of CYR1 showed guanine nucleotidedependent adenylate cyclase activity and produced a large amount of cAMP in the presence of the RAS gene. Thus, the domain encoded by the 0.8 kb region adjacent to the catalytic domain is associated with the regulatory function of the RAS products. The cyr1 RAS1 RAS2 cells carrying the 3-terminal 1.3 kb region of CYR1 were unable to respond to environmental signals such as sulfur starvation and temperature shift, but the cyr1 cells carrying the 2.1 kb region and at least one RAS gene were able to respond to these signals. The environmental signals may be transferred to the adenylate cyclase system through the RAS products.     

A complete sequence of the rice sucrose synthase-1 (RSs1) gene

Using a fragment of the maize sucrose synthase gene Sh-1 as probe, the rice genome was shown to contain at least three genes encoding sucrose synthase. One of these genes was isolated from a genomic library, and its full sequence, including 1.7 kb of 5 flanking sequence and 0.9 kb of 3 flanking sequence, is reported. The new rice gene, designated RSs1, is highly homologous to maize Sh-1 (approx. 94% identity in derived amino acid sequence), and contains an identical intron-exon structure (16 exons and 15 introns). Both RSs1 and maize Sh-1 show similar sequence homologies to a second rice sucrose synthase gene described recently (designated RSs2, Yu et al. (1992) Plant Mol Biol 18: 139–142), although both the rice genes predict an extra 6 amino acids at the C-terminus of the protein when compared to the maize gene. The RSs1 5 flanking sequence contains a number of promoter-like sequences, including putative protein-binding regions similar to maize zein genes.     

Ozone-induced gene expression occurs via ethylene-dependent and -independent signalling

Recent studies suggest that ethylene is involved in signalling ozone-induced gene expression. We show here that application of ozone increased glucuronidase (GUS) expression of chimeric reporter genes regulated by the promoters of the tobacco class I -1,3-glucanases (GLB and Gln2) and the grapevine resveratrol synthase (Vst1) genes in transgenic tobacco leaves. 5-deletion analysis of the class I -1,3-glucanase promoter revealed that ozone-induced gene regulation is mainly mediated by the distal enhancer region containing the positively acting ethylene-responsive element (ERE). In addition, application of 1-methylcyclopropene (1-MCP), an inhibitor of ethylene action, blocked ozone-induced class I -1,3-glucanase promoter activity. Enhancer activity and ethylene-responsiveness depended on the integrity of the GCC boxes, cis-acting elements present in the ERE of the class I -1,3-glucanase and the basic-type pathogenesis-related PR-1 protein (PRB-1b) gene promoters. The minimal PRB-1b promoter containing only the ERE with intact GCC boxes, was sufficient to confer 10-fold ozone inducibility to a GUS-reporter gene, while a substitution mutation in the GCC box abolished ozone responsiveness. The ERE region of the class I -1,3-glucanase promoter containing two intact GCC boxes confered strong ozone inducibility to a minimal cauliflower mosaic virus (CaMV) 35S RNA promoter, whereas two single-base substitution in the GCC boxes resulted in a complete loss of ozone inducibility. Taken together, these data strongly suggest that ethylene is signalling ozone-induced expression of class I -1,3-glucanase and PRB-1b genes. Promoter analysis of the stilbene synthase Vst1 gene unravelled different regions for ozone and ethylene-responsiveness. Application of 1-MCP blocked ethylene-induced Vst1 induction, but ozone induction was not affected. This shows that ozone-induced gene expression occurs via at least two different signalling mechanisms and suggests an additional ethylene independent signalling pathway for ozone-induced expression of genes involved in phytoalexin biosynthesis.     

Proximity of an ARS consensus sequence to a replication origin of pea (Pisum sativum)

The replication origin (ori-r9) of the 9.0 kb rDNA repeats of pea (Pisum sativum, cv. Alaska) was cloned and found to reside in a 1.5 kb fragment of the non-transcribed spacer region located between the 25 S and 18 S genes. Labeled rDNA rich in replication forks, from cells positioned at the G₁/S phase boundary, was used to map ori-r9 by hybridization procedures. Ori-r9 is in a 210-base fragment that is 1.6 kb from the 5 end of the 18 S gene and about 1.5 kb from the 3 end of the 25 S gene. The same procedures, using labeled synthetic ARS consensus sequence as a probe, showed than an ARS consensus sequence is located 3 to ori-r9 in a 710-base fragment. An ARS consensus sequence is, therefore, adjacent to ori-r9 but not coincidental with it.     

Cloning and molecular characterisation of the amdR controlled gatA gene of Aspergillus nidulans

Summary The gamma-amino-n-butyrate transaminase gene (gatA) of Aspergillus nidulans is one of several genes under positive control by the regulatory gene amdR (also called intA). The gatA gene has been cloned from a cosmid library by complementation of a gatA mutation. The sequence of a 2.6 kb genomic fragment containing gatA has been determined. An open reading frame of 1497 bp within this sequences is interrupted by three putative introns and predicts a protein of 55 kDa. Northern analysis confirms control of gatA RNA levels by amdR and also indicates that gatA is not strongly regulated by areA-mediated nitrogen metabolite repression. A. nidulans transformants containing multiple copies of a plasmid carrying an 88 bp fragment from the 5 untranscribed region of gatA grew poorly on substrates whose utilisation is dependent on genes controlled by amdR. This indicated titration of limiting amounts of the amdR gene product by this 88 bp fragment. Comparison of this sequence with the 5 region of the coregulated gene, amdS, reveals probable sites of action for the amdR protein.     

Organization and characterization of Cucurbita phloem lectin genes

The phloem of pumpkin and squash contains a dimeric chitin-binding lectin called PP2 (phloem protein 2). We have isolated three genomic clones from pumpkin (Cucurbita maxima Duch.) that encoded PP2. One clone, gPC13-1, contained two PP2 genes that were 99.8% identical over a region of 3055 nucleotides. This conserved region included 1922 bp of 5 non-coding sequence, 844 bp of protein coding sequence (including two introns), and 289 bp of 3 non-coding sequence. To examine the conservation of the phloem lectin within the genus Cucurbita, we analyzed nine different species for PP2, its mRNA, and the genes that encode PP2. DNA blot analysis indicated that each species contained genes that encoded PP2, however, there was considerable restriction fragment length polymorphism (RFLP) among the species. PP2 gene copy number reconstructions indicated that PP2 is encoded by a small gene family (two to eight genes). Although a high level of PP2 DNA polymorphism existed among species, a single mRNA (ca. 1 kb) was detected in each species. PP2, affinity-purified from the vascular exudate of each species, reacted with PP2-specific antibodies; five species contained a single PP2 polypeptide while four species contained two PP2 polypeptides.     

The heat shock cognate 80 gene of tomato is flanked by matrix attachment regions

Matrix attachment regions (MARs) are thought to participate in the organization and segregation of independent chromosomal loop domains. Although there are several reports on the action of MARs in the context of heterologous genes, information is more limited on the role of MARs associated with plant genes. Transgenic studies suggest that the upstream, intron and downstream regions of the developmentally regulated heat shock cognate 80 gene (HSC80) of tomato participate in chromatin organization. In this study, we tested the in vitro affinity of the HSC80 gene to chromosomal scaffolds prepared from shoot apices of tomato. We found that a 1.5 kb upstream region and a 1.4 kb downstream region, but not the intron region, are MARs. These MARs interact with tomato and pea scaffolds and bind regardless of the expression status of HSC80 in the tissue from which the nuclei were isolated. Comparison to two known yeast MARs ARS1 and CENIII, showed that the HSC80 5MAR binds more avidly to tomato scaffolds than ARS1, while no binding of CENIII was observed. Competition binding between the two HSC80 MARs indicated that the 5 MAR can outcompete the 3 MAR and not vice versa. Last, we observed that the interaction of the 3 MAR with the scaffold could result in an electrophoretic mobility shift resistant to SDS, protease, and phenol treatment. In conclusion, MARs whose binding properties can be clearly differentiated are closely flanking the HSC80 gene. The discovery of MARs in regions which have a distinct function in HSC80 transgenes but not in transient expression assays, is consistent with a chromosomal scaffold role in HSC80 gene regulation.