Insertion of (dA-dT)n sequences into the regulatory region of the pho5 gene inhibits its expression

We have studied the effect of some regular sequences namely (dA-dT)n, (dA)n and (dG-dC)n on the Saccharomyces cerevisiae PHO5 gene expression. These sequences were inserted into the ClaI site, located between two phosphate-responsible upstream activating sequences (UAS's). A modified PHO5 gene cloned in vector plasmids was used to transform the pho3, pho5 yeast strain and the level of acid phosphatase expression in various conditions was measured. We show that the insertion of (dA-dT)n blocks, but not (dA)n or (dG-dC)n, leads to the dramatic decrease of PHO5 gene expression in a derepressed state. (dA-dT)n inserts also inhibit the expression of PHO5 gene which was put under the control of heterologous UASgal.     

Cloning, sequencing, and characterization of the principal acid phosphatase, the phoC+ product, from Zymomonas mobilis.

The Zymomonas mobilis gene encoding acid phosphatase, phoC, has been cloned and sequenced. The gene spans 792 base pairs and encodes an Mr 28,988 polypeptide. This protein was identified as the principal acid phosphatase activity in Z. mobilis by using zymograms and was more active with magnesium ions than with zinc ions. Its promoter region was similar to the -35 "pho box" region of the Escherichia coli pho genes as well as the regulatory sequences for Saccharomyces cerevisiae acid phosphatase (PHO5). A comparison of the gene structure of phoC with that of highly expressed Z. mobilis genes revealed that promoters for all genes were similar in degree of conservation of spacing and identity with the proposed Z. mobilis consensus sequence in the -10 region. The phoC gene contained a 5' transcribed terminus which was AT rich, a weak ribosome-binding site, and less biased codon usage than the highly expressed Z. mobilis genes.     

The two positively acting regulatory proteins PHO2 and PHO4 physically interact with PHO5 upstream activation regions.

The repressible acid phosphatase gene PHO5 of Saccharomyces cerevisiae requires the two positively acting regulatory proteins PHO2 and PHO4 for expression. pho2 or pho4 mutants are not able to derepress the PHO5 gene under low-Pi conditions. Here we show that both PHO2 and PHO4 bind specifically to the PHO5 promoter in vitro. Gel retardation assays using promoter deletions revealed two regions involved in PHO4 binding. Further characterization by DNase I footprinting showed two protected areas, one located at -347 to -373 (relative to the ATG initiator codon) (UASp1) and the other located at -239 to -262 (UASp2). Exonuclease III footprint experiments revealed stops at -349 and -368 (UASp1) as well as at -245 and -260 (UASp2). Gel retardation assays with the PHO2 protein revealed a binding region that lay between the two PHO4-binding sites. DNase I footprint analysis suggested a PHO2-binding site covering the region between -277 and -296.     

Negative regulators of the PHO system in Saccharomyces cerevisiae: isolation and structural characterization of PHO85.

One of the negative regulators of the PHO system of Saccharomyces cerevisiae, PHO85, has been isolated by transformation and complementation of a pho85 strain. The complementing activity was delimited within a 1258 bp DNA segment and this region has been sequenced. The largest open reading frame found in this region can encode a protein of 302 amino acid residues. A pho85 mutant resulted from disruption of the chromosomal counterpart of the open reading frame described above. Therefore, we concluded that the gene we have cloned is PHO85. This result also indicates that PHO85 is nonessential. Northern analysis revealed that the size of the PHO85 message is 1.1 kb. No similarity was found between the putative amino acid sequences of two negative regulators, the PHO80 and PHO85 proteins.     

Nucleotide sequences of Caenorhabditis elegans core histone genes. Genes for different histone classes share common flanking sequence elements

We have determined the nucleotide sequence of core histone genes and flanking regions from two of approximately 11 different genomic histone clusters of the nematode Caenorhabditis elegans. Four histone genes from one cluster (H3, H4, H2B, H2A) and two histone genes from another (H4 and H2A) were analyzed. The predicted amino acid sequences of the two H4 and H2A proteins from the two clusters are identical, whereas the nucleotide sequences of the genes have diverged 9% (H2A) and 12% (H4). Flanking sequences, which are mostly not similar, were compared to identify putative regulatory elements. A conserved sequence of 34 base-pairs is present 19 to 42 nucleotides 3' of the termination codon of all the genes. Within the conserved sequence is a 16-base dyad sequence homologous to the one typically found at the 3' end of histone genes from higher eukaryotes. The C. elegans core histone genes are organized as divergently transcribed pairs of H3-H4 and H2A-H2B and contain 5' conserved sequence elements in the shared spacer regions. One of the sequence elements, 5' CTCCNCCTNCCCACCNCANA 3', is located immediately upstream from the canonical TATA homology of each gene. Another sequence element, 5' CTGCGGGGACACATNT 3', is present in the spacer of each heterotypic pair. These two 5' conserved sequences are not present in the promoter region of histone genes from other organisms, where 5' conserved sequences are usually different for each histone class. They are also not found in non-histone genes of C. elegans. These putative regulatory sequences of C. elegans core histone genes are similar to the regulatory elements of both higher and lower eukaryotes. The coding regions of the genes and the 3' regulatory sequences are similar to those of higher eukaryotes, whereas the presence of common 5' sequence elements upstream from genes of different histone classes is similar to histone promoter elements in yeast.     

Role of trans-activating proteins in the generation of active chromatin at the PHO5 promoter in S. cerevisiae.

Induction of the PHO5 gene in Saccharomyces cerevisiae by phosphate starvation was previously shown to be accompanied by the removal of four positioned nucleosomes from the promoter. We have now investigated the role of two trans-activating proteins, encoded by PHO2 and PHO4, which bind to the PHO5 promoter. Both proteins are absolutely required for the chromatin transition to occur as shown by analysis of null mutants of the two genes. Transformation of these mutant strains with plasmids containing the respective genes restores the wild type chromatin response. Increasing the gene dosage of PHO2 and of PHO4 makes it possible to differentiate functionally between the two proteins. From over-expressing PHO4 in a wild type and also in a pho2 null mutant strain and complementary experiments with PHO2, it is concluded that the PHO4 protein is the primary trigger for the chromatin transition, consistent with one of its two binding sites being located between positioned nucleosomes in repressed chromatin and thereby accessible. PHO2, the binding site of which is located within a nucleosome under conditions of PHO5 repression, contributes to the chromatin transition either by destabilizing histone-DNA interactions or by under-going interactions with PHO4.     

The Saccharomyces cerevisiae ADE1 gene: structure, overexpression and possible regulation by general amino acid control.

The ADE1 gene of the yeast Saccharomyces cerevisiae has been cloned by complementation of the ade1 mutation. The nucleotide sequence has been determined for the 918-bp coding region, 240-bp 5'-noncoding region and 292-bp 3'-noncoding region. The sequenced region includes a single large open reading frame coding for a protein of 306 amino acid (aa) residues. The promoter of the ADE1 gene contains a copy of the 5'-TGACTC hexanucleotide, a feature characteristic of promoters under general aa control. Subsequent search of other published purine biosynthesis gene sequences revealed that all of them also contain general aa control signals in their promoter regions. An expression plasmid containing the ADE1 coding region under control of the PHO5 promoter produced N-succinyl-5-aminoimidazole-4-carboxamide ribotide (SAICAR) synthetase in yeast cells at a level of 40% of total cellular protein. One-step purification resulted in an almost homogeneous preparation of SAICAR synthetase.     

Evolutionary changes in the structural and regulatory regions of aminoglycoside-3'-phosphotransferase type I gene of E. coli

To investigate the evolutionary relationships between the aph(3') genes from different plasmids, the nucleotide sequence of the aph(3') gene from the E. coli R plasmid was determined and compared with the known aph(3') genes of Tn903 and Tn4352. Three point mutations in the structural part of the cloned aph(3') gene caused amino acid changes in the enzyme molecule at positions 19, 27 and 48 beginning from the start codon. The structural part of the gene was followed by two stop codons and a long DNA region containing no nucleotide sequences homologous to the sequences of Tn903 or Tn4352. Both the cloned aph(3') gene and Tn4352 were limited on the left by the spacer sequence and the insertion sequence IS176. Twenty one base pairs deletion abolished the -35 sequence of the promoter suggested for the aph(3') gene of Tn4352 and resulted in formation of a fusion promoter utilizing the -35 box of IS176 and the -10 box of the aph(3') gene. The distance between the -35 and -10 sequences changed from 18 to 17 bp. Changes in the cloned aph(3') gene and the flanking DNA regions resulted in formation of a new promoter and loss of the right IS176 element.