Cis-acting sequences which regulate expression of the Sgs-4 glue protein gene of Drosophila.

The Sgs-4 glue protein gene of Drosophila is expressed only in third-instar larval salivary glands. Previous work suggests that a regulatory region lies 5' and remote to the gene, as indicated by a region of tissue-specific DNase I hypersensitivity and by underproducing mutants with DNA lesions in the hypersensitive region. Here we demonstrate by germ line transformation of cloned fragments containing Sgs-4 that the sequences between 840 bp 5' and 130 bp 3' to the gene are sufficient for Sgs-4 activity. When 5' sequence was removed to -392, activity was eliminated, thereby verifying the existence of essential sequences far upstream. Fragments that are active include, in addition to the capacity for normal levels of expression, three other cis-acting regulatory activities: developmental timing, tissue specificity, and dosage compensation. In contrast, the fragments tested did not specify formation of the puff with which Sgs-4 is normally associated. As shown by chromosomal rearrangements, the region required for puffing is limited to 16-19 kb surrounding the gene.     

A trans-acting regulatory product necessary for expression of the Drosophila melanogaster 68C glue gene cluster

The mutation I(1)npr-1 is located at cytological location 2B5 on the X chromosome in Drosophila melanogaster. We have found that this mutation causes absence of the normal product of the 2B5 locus and that it has the following phenotypes: the 68C glue puff on the third chromosome does not regress when mutant salivary glands are cultured in the presence of ecdysterone; the three 68C glue protein mRNAs are not synthesized; and a transformed Drosophila strain carrying both a normal resident 68C Sgs-3 gene and an introduced functional Sgs-3 gene with only a few kb of flanking sequences expresses neither Sgs-3 RNA if the I(1)npr-1 mutation is crossed into the stock. Thus the normal product of the I(1)npr11 gene is required for regression of the 68C puff, and the I(1)npr-1 gene product allows expression of the Sgs-3 gene by interacting, either directly or indirectly, with DNA sequences near this glue protein gene.     

Sequences sufficient for correct regulation of Sgs-3 lie close to or within the gene.

The Drosophila melanogaster 68C chromosomal locus is the site of a prominent polytene chromosome puff that harbors the genes Sgs-3, Sgs-7 and Sgs-8. These genes code for proteins that are part of the salivary glue that Drosophila larvae secrete as a means of fixing themselves to an external substrate for the duration of the pre-pupal and pupal period. The 68C glue genes are regulated by the steroid hormone ecdysterone, with the hormone required for both initiation and cessation of gene expression during the third larval instar. Previous work has defined sequences sufficient for expression of abundant levels of Sgs-3 mRNA at the correct time and in the correct tissue. We show here that sequences sufficient for normal tissue- and stage-specific accumulation of Sgs-3 RNA, but adequate only for low levels of expression, lie within 130 bp of the 5' end of the gene, or within the gene.     

Regulatory sequences of the Sgs-4 gene of Drosophila melanogaster analysed by P element-mediated transformation

The X chromosomally located allele Sgs-4 ^c for a larval secretion protein of Drosophila melanogaster is normally expressed in female larvae of the strain Oregon R and is hyperexpressed in male larvae exhibiting dosage compensation; the allele Sgs-4 ^d in the strain Samarkand is weakly expressed and is not hyperexpressed in male larvae showing a dosage effect. P element-mediated transformation of upstream DNA sequences from both alleles combined with Sgs-4 ^d coding and downstream sequences was performed to localize sequences which are responsible for the level of gene expression and for hyperexpression of Sgs-4 ^c in male larvae. Our results demonstrate that weak expression and dosage effect are inherited with the upstream region from –1 to –838. This Samarkand fragment differs from the homologous Oregon R region only by a C to T transiion at –344 which lies within an assumed binding sequence for the ecdysone receptor complex of dyad base symmetry. Replacing the Samarkand upstream region from –1 to –838 by the Oregon R region restores normal Sgs-4 expression and dosage compensation. Hyperexpression in male larvae displays high sensitivity to position effect and is nearly completely inhibited in one transformed line under heterozygous conditions. The integration of an Sgs-4 ^d transposon into a weak spot of polytene chromosome 2L results in a decrease in gene expression. The GTT- and GT-rich regions at –1.2 and –2.0 kb do not obviously influence Sgs-4 expression but possibly play a role in induction of stage-specific chromosome puffing.     

Association of a Drosophila transposable element of the roo family with chromosomal deletion breakpoints.

A 9.3 kb transposable element of the roo family has been found inserted 3' to the Sgs-4 glue protein gene of Drosophila. The X chromosome which carries this insert also carries wDZL, a dominant, unstable allele of the white locus caused by the insertion of the 13 kb wDZL element. Three deletions isolated from the wDZL strain have molecular breakpoints 3' to Sgs-4 that are associated with the roo element. Though the deletions eliminate much of the DNA between white and Sgs-4, none of the distal breakpoints fall at or near the wDZL element. The results suggest that this copia-like element, which is structurally similar to an integrated retrovirus, is capable of promoting chromosomal deletions.     

The glucose kinase gene of Streptomyces coelicolor and its use in selecting spontaneous deletions for desired regions of the genome

Summary A number of deletions in the glucose kinase (glk) region of the Streptomyces coelicolor chromosome were found among spontaneous glk mutants. The deletions were identified by probing Southern blots of chromosomal DNA from glk mutants with cloned glk DNA. The deletions ranged in size from 0.3 kb to greater than 2.9 kb. When cloned glk DNA was introduced on a C31 phage vector into a glk mutant that contained a deletion of the entire homolgous chromosomal glk region, glucose kinase activity was detected in extracts of these cells. The entire coding information for at least a subunit of glucose kinase is there-fore present on the cloned glk DNA. The 0.3 kb glk chromosomal deletion was used to demonstrate that transfer of chromosomal glk mutations on the the C31::glk phage could occur by recombination in vivo. Since glk mutations frequently arise from deletion events, a method was devised for inserting the cloned glk DNA at sites in the chromosome for which cloned DNA is available, and thus facilitating the isolation of deletions in those DNA regions. C31::glk vectors containing a deletion of the phage att site cannot lysogenize S. coelicolor recipients containing a deletion of the glk chromosomal gene unless these phages contain S. coelicolor chromosomal DNA. In such lysogens, the glk gene becomes integrated into the chromosome by homologous recombination directed by the chromosomal insert on the phage DNA. In appropriate selective conditions, mutants which contain deletions of the glk gene that extend into the adjacent host DNA can be easily isolated. This method was used to insert glk into the methylenomycin biosynthetic genes, and isolate derivatives with deletions of host DNA from within the prophage into the adjacent host DNA. Phenotypic and Southern blot analysis of the deletions showed that there are no genes essential for methylenomycin biosynthesis for at least 13 kb to the left of a region concerned with negative regulation of methylenomycin biosynthesis. Many of the deletions also removed part of the C31 prophage.     

The secretory proteins of the larval salivary gland of Drosophila melanogaster

The gene for a major salivary gland secretion protein (Sgs-1) in Drosophila melanogaster has been mapped to chromosome 2 between dp (13.0) and cl (16.5). In the late third instar larva, a puff forms in this region. This puff (25 B) regresses as the ecdysteroid concentration increases prior to puparium formation. Quantitative analysis of the secretory protein 1, showed that, when present in extra dose, region 25 B results in a significant elevation in its relative amount. This suggests that the structural gene for this protein is localized in this region and that its synthesis is directly correlated to the activity of the 25 B puff.     

A deletion in the sapA homologue cluster is responsible for the loss of the S-layer in Campylobacter fetus strain TK

The surface array protein (SAP) of Campylobacter fetus strain TK is encoded by seven homologous sapA genes clustered on the chromosomal DNA. The spontaneously arising variant strain TK(SAP^–) produces no SAP and carries an approximately 10-kb chromosomal deletion. To elucidate the mechanism underlying the loss of SAP synthesis, we analyzed the region containing the sapA homologues and the deletion. We constructed a physical map of the sapA cluster region by aligning the clones that contain sapA homologues. These analyses demonstrated that all sapA homologues were located within a limited region of about 50 kb of chromosomal DNA of strain TK. The TK(SAP^–) deletion was located within this cluster and was 13.3 kb in size. The deletion occurred between two sapA homologues and resulted in the formation of a chimeric sapA homologue in the variant strain. Sequence analysis of the upstream regions and the conserved regions of all sapA homologues revealed a high degree of similarity. However, only one sapA homologue contained a putative promoter sequence. This promoter sequence was located in the deleted region. Thus, the deletion of the promoter appears to be responsible for the loss of SAP expression in TK(SAP^–). Received: 17 May 1996 / Accepted: 6 December 1996     

Rearrangements of nitrogen fixation (nif) genes in the heterocystous cyanobacteria

In the vegetative cells of heterocystous cyanobacteria, such asAnabaena, two Operons harbouring the nitrogen fixaton (nif) genes contain two separate intervening DNA elements resulting in the dispersion of genes and impaired gene expression. A 11 kb element disrupts thenifD gene in thenifH, D-K operon. It contains a 11 bp sequence (GGATTACTCCG) directly repeated at its ends and harbours a gene,xisA, which encodes a site-specific recombinase. A large 55 kb element interrupts thefdxN gene in thenifB fdxN-nifS-nifU operon. It contains two 5 bp direct repeats (TATTC) at its ends and accommodates at least one gene,xisF, which encodes another site-specific recombinase. During heterocyst differentiation both the discontinuities are precisely excised by two distinct site-specific recombination events. One of them is brought about by the XisA protein between the 11 bp direct repeats. The second one is caused by the XisF protein and occurs between the 5 bp direct repeats. As a consequence the 11kb and 55 kb elements are removed from the chromosome as circles and functionalnif Operons are created. Nitrogenase proteins are then expressed from the rearranged genes in heterocysts and aerobic nitrogen fixation ensues. How these elements intruded thenif genes and how and why are they maintained in heterocystous cyanobacteria are exciting puzzles engaging considerable research effort currently. The unique developmental regulation of these gene rearrangements in heterocystous cyanobacteria is discussed.     

Sequence variation at theSec-1 locus of rye,Secale cereale (Poaceae)

This paper describes the structure of a 9.2-kb repeat unit of DNA, which represents one-secalin gene and spacer sequence located at theSec-1 locus on the short arm of chromosome 1 of rye. The gene units at theSec-1 locus comprise 1.1 kb representing the gene and 8.1 kb of spacer sequence separating the genes. A sequence comparison of nine genes and their promoter regions from theSec-1 locus, reveals that there is greater variation within the coding sequence than there is within the promoter regions. The gene sequence variation is discussed in terms of the size variation seen for the-secalin proteins in rye species. The results include a comparison of promoter sequences from members of the Triticeae to examine the degree of conservation between other seed storage protein genes.     

Molecular cloning of thehom—thrC—thrB cluster fromBacillus sp. ULM1: Expression of thethrC gene inEscherichia coli and corynebacteria,and evolutionary relationships of the threonine genes

A 6.5 kb DNA fragment containing the gene (thrC) encoding threonine synthase, the last enzyme of the threonine biosynthetic pathway, has been cloned from the DNA ofBacillus sp. ULM1 by complementation ofEscherichia coli andBrevibacterium lactofermentum thrC auxotrophs. Complementation studies showed that thethrB gene (encoding homoserine kinase) is found downstream from thethrC gene, and analysis of nucleotide sequences indicated that thehom gene (encoding homoserine dehydrogenase) is located upstream of thethrC gene. The organization of this cluster of genes is similar to theBacillus subtilis threonine operon (hom—thrC—thrB). An 1.9 kbBclI, fragment from theBacillus sp. ULM1 DNA insert that complementedthrC mutations both inE. coli and in corynebacteria was sequenced, and an ORF encoding a protein of 351 amino acids was found corresponding to a protein of 37462 Da. ThethrC gene showed a low G+C content (39.4%) and the encoded threonine synthase is very similar to theB. subtilis enzyme. Expression of the 1.9 kbBclI DNA fragment inE. coli minicells resulted in the formation of a 37 kDa protein. The upstream region of this gene shows promoter activity inE. coli but not in corynebacteria. A peptide sequence, including a lysine that is known to bind the pyridoxal phosphate cofactor, is conserved in all threonine synthase sequences and also in the threonine and serine dehydratase genes. Amino acid comparison of nine threonine synthases revealed evolutionary relationships between different groups of bacteria. Dedicated to Dr. J. Spížek on the occasion of his 60th birthday     

Cloning and sequencing of mutantpsbB genes of the cyanobacteriumSynechocystis PCC 6803

Ten strains from a collection of mutants ofSynechocystis 6803 defective in Photosystem II (PS II) function were transformed with chromosomal DNA of wild-type and mutant cells. Cross hybridization data allowed to identify four groups of PS II-mutants. Highly efficient transformation was observed between different mutant groups, but not within the groups. Restoration of photosynthetic activity of the mutant cells was also achieved by transformation with different parts of a 5.6 kbBam HI fragment of wild typeSynechocystis DNA containing thepsbB gene. Each group of mutants was transformed to photoautotrophic growth by specific subfragments of thepsbB gene. DNA fragments of four selected mutant strains hybridizing with thepsbB gene were isolated and sequenced. The mutations were identified as a single nucleotide insertion or substitution leading to stop codon formation in two of the mutants, as a deletion of 12 nucleotides, or as a nucleotide substitution resulting in an amino acid substitution in the other two mutants. Deletion of 12 nucleotides in mutant strain PMB1 and stop codon formation in strain NF16 affect membrane-spanning regions of the gene product, the CP 47 protein.     

Heat shock-induced relaxation of restriction enzyme specificity inEscherichia coli

Methylated and hydroxymethylated cytosine containing DNA was restricted by proteins encoded by themcrBC (rglB) loci ofE. coli. In vivo, RglB proteins recognize and cleave hmCT2 and hmCT4 DNAs at 30°C and 42°C but hmCT6 DNA was unaffected at both temperatures, However, cells carrying therglB genes cloned on pBR322 (pDSS17) did not restrict hmCT6 at 30°C, but hmCT6 DNA was cleaved efficiently at 42°C. Heat shock treatment for five minutes was enough to induce this promiscuity in recognition specificity. We call this activity RglB star. A single copy ofrglB located on the chromosome or cloned on a low copy vector pMU575 failed to show RglB star activity.De novo protein synthesis was not required for the manifestation of RglB star activity.