The glucoamylase gene of Aspergillus niger, glaA, is expressed at high levels in the presence of starch. We have determined the nucleotide sequence of 1966 bp of the 5' flanking region of the glaA gene and have begun to identify sequences important for the control of glaA expression by deletion analysis. Constructs containing deletions extending into the glaA gene promoter were introduced into an A. niger host whose own glaA gene had been disrupted by a gene replacement event. Secreted levels of glucoamylase, expressed from each of the recombinant glaA genes, were measured by enzyme immunoassay. The effect of each deletion on the expression of glaA, when grown on differing carbon sources, was used to determine the limits of sequences upstream of glaA responsible for gene regulation. A region between -562 and -318 appears to direct high-level expression, whereas only 214 bp of 5' flanking sequence is required to initiate the start to transcription.
Cellulases belong to the large family of glycosyl hydrolases (GHs) and are produced by a variety of bacteria and fungi. These extracellular enzymes act as endoglucanases (EGs), cellobiohydrolases or beta-glucosidases. In this paper, we describe molecular screening for EGs from the GH family 12. Using three homologous sequence boxes deduced from five previously known members of the family, we analysed 22 cellulase-producing fungal strains obtained from a diverse area of the fungal kingdom. Polymerase chain reactions using degenerate primers designed to the homologous protein boxes were used to identify the family 12 homologues. Several fungi showed the presence of multiple versions of the gene, while amino acid sequence analysis showed diversity in 15 novel members of the family, ranging from 26% to 96% similarity. Our sequence analysis shows that the phylogenetic tree of family 12 EGs can be divided into four subfamilies: 12-1 (fungal group I), 12-2 (fungal group II), 12-3 ( Streptomyces group in which Rhodothermus marinus fits) and 12-4 ( Thermophiles group). Erwinia carotovora may form a new subgroup.
Synthetic oligonucleotide probes based on amino acid sequence data were used to identify and clone cDNA sequences encoding a catalase (catalase-R) of Aspergillus niger. One cDNA clone was subsequently used to isolate the corresponding genomic DNA sequences (designated catR). Nucleotide sequence analysis of both genomic and cDNA clones suggested that the catR coding region consists of five exons interrupted by four small introns. The deduced amino acid sequence of catalase-R spans 730 residues which show significant homology to both prokaryotic and eukaryotic catalases, particularly in regions involved in catalytic activity and binding of the haem prosthetic group. Increased expression of the catR gene was obtained by transformation of an A. niger host strain with an integrative vector carrying the cloned genomic DNA segment. Several of these transformants produced three- to fivefold higher levels of catalase than the untransformed parent strain. Hybridization analyses indicated that these strains contained multiple copies of catR integrated into the genome. A second expression vector was constructed in which the catR coding region was functionally joined to the promoter and terminator elements of the A. niger glucoamylase (glaA) gene. A. niger transformants containing this vector produced from three- to 10-fold higher levels of catalase-R than the untransformed parent strain.
During the last day of larval development, the Sgs‐4 glue gene of Drosophila melanogaster is expressed at high levels in a single tissue, the larval salivary glands. As shown by transformation experiments and by DNA sequence analysis of Sgs‐4 underproducing strains, an essential regulatory region for Sgs‐4 expression lies between 149 and 568 bp upstream from the transcribed part of the gene. This region shows the positional independence of a transcriptional enhancer and directs at least three regulatory activities: tissue specificity, developmental timing and high‐level expression. Here we use a transient transformation assay to identify three elements within this enhancer that are involved in tissue specificity. For at least this regulatory activity the enhancer is internally redundant. Any pairwise combination of the three elements is sufficient to direct salivary gland expression, although none of the three can act alone.
Pig-l and Sgs-4 are a pair of closely linked and divergently transcribed Drosophila melanogaster genes, which are both expressed in larval salivary glands but at different times during development. While Sgs-4 is expressed at high levels only at the end of the third instar, Pig-i exhibits a major peak of expression during late second and early third instar. Thus, Pig-] expression declines as Sgs-4 expression is induced. In this paper, we show that three adjacent elements located within the short region between these genes can account for the switch from Pig-i to Sgs-4 expression. A 170-bp segment acts as an enhancer to direct Sgs-4 expression in late-third-instar salivary glands. A 64-bp sequence located just upstream from the enhancer can modify its temporal specificity so that it works throughout the third instar. Expression induced at mid-third instar by a combination of these two elements can be repressed by a negative regulatory sequence located still further upstream. We present evidence suggesting that the changing interactions between these regulatory elements and the Sgs-4 and Pig-i promoters lead to the correct pattern of expression of the two genes.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.