Escherichia coli GlpE is a prototype sulfurtransferase for the single-domain rhodanese homology superfamily.

BACKGROUND: Rhodanese domains are structural modules occurring in the three major evolutionary phyla. They are found as single-domain proteins, as tandemly repeated modules in which the C-terminal domain only bears the properly structured active site, or as members of multidomain proteins. Although in vitro assays show sulfurtransferase or phosphatase activity associated with rhodanese or rhodanese-like domains, specific biological roles for most members of this homology superfamily have not been established. RESULTS: Eight ORFs coding for proteins consisting of (or containing) a rhodanese domain bearing the potentially catalytic Cys have been identified in the Escherichia coli K-12 genome. One of these codes for the 12-kDa protein GlpE, a member of the sn-glycerol 3-phosphate (glp) regulon. The crystal structure of GlpE, reported here at 1.06 A resolution, displays alpha/beta topology based on five beta strands and five alpha helices. The GlpE catalytic Cys residue is persulfurated and enclosed in a structurally conserved 5-residue loop in a region of positive electrostatic field. CONCLUSIONS: Relative to the two-domain rhodanese enzymes of known three-dimensional structure, GlpE displays substantial shortening of loops connecting alpha helices and beta sheets, resulting in radical conformational changes surrounding the active site. As a consequence, GlpE is structurally more similar to Cdc25 phosphatases than to bovine or Azotobacter vinelandii rhodaneses. Sequence searches through completed genomes indicate that GlpE can be considered to be the prototype structure for the ubiquitous single-domain rhodanese module.

Multiple promoters are responsible for transcription of the glpEGR operon of Escherichia coli K-12.

The transcriptional organization of the glpEGR genes of Escherichia coli was studied. Besides a promoter located upstream of the glpE start codon, three internal glpGR promoters were identified that express glpG and/or glpR (glp repressor). One promoter was located just upstream of the glpG start codon and two others (separated by several hundred base pairs) were located within glpG upstream of the glpR start codon. The transcriptional start points of these promoters were identified by primer extension analysis. The strengths of the individual promoters were compared by analysis of their expression when fused to a pormoter-probe vector. Analysis of the transcriptional expression of the glpEGR sequence with different combinations of the glpEGR promoters revealed no internal transcriptional terminators within the entire operon. Thus, the glpEGR genes are co-transcribed and form a single complex operon. The presence of multiple promoters may provide for differential expression of glpE, glpG and glpR. Potential regulation of the operon promoters by GlpR, catabolite repression, anaerobiosis or by FIS was studied. The glpE promoter was apparently controlled by the cAMP-CRP complex, but none of the promoters was responsive to specific repression by GlpR, to anaerobiosis or to FIS. Specific repression exerted by GlpR was characterized in vivo using glpD-lacZ and glpK-lacZ fusions. The degree of repression was correlated with the level of GlpR expression, and was inefficient when the glpD-encoded glycerol-P dehydrogenase was absent, presumably due to accumulation of the inducer, glycerol-P. This is in contrast to the previous conclusion that gpsA-encoded glycerol-P synthase tightly controls the cellular level of glycerol-P by end product inhibition.

A new vector-host system for construction of lacZ transcriptional fusions where only low-level gene expression is desirable.

We improved a multicopy vector, pRS415 [Simons et al., Gene 53 (1987) 85-96], for use in operon fusion constructions by introducing a new multiple cloning site (MCS) containing eight unique restriction sites upstream from the promoterless reporter gene lacZ. In order to reduce plasmid copy number, a new Escherichia coli strain SP2 (pcnB, delta lac, recA) was constructed. This strain permits analysis of fusions in cases where high gene dosage may be detrimental.

Lipid biosynthetic genes and a ribosomal protein gene are cotranscribed.

By using insertional mutagenesis we demonstrated that the rpmF gene encoding ribosomal protein L32, the plsX gene encoding a protein involved in membrane lipid synthesis and several fatty acid biosynthetic genes (fabH, fabD and fabG) are cotranscribed. Organization of these genes into an operon may play a role in the coordinate regulation of the synthesis of ribosomes and the cell membranes.

Cloning and nucleotide sequence of the fabD gene encoding malonyl coenzyme A-acyl carrier protein transacylase of Escherichia coli.

We report the cloning and nucleotide sequence of the gene encoding malonyl coenzyme A-acyl carrier protein transacylase of Escherichia coli. Malonyl transacylase has been overexpressed 155-fold compared to a wild-type strain. Overexpression of this enzyme alters the fatty acid composition of a wild-type E. coli strain; increased amounts of cis-vaccenate are incorporated into the membrane phospholipids.

Identification of the rpmF-plsX-fabH genes of Rhodobacter capsulatus.

The rpmF-plsX-fabH gene cluster of Rhodobacter capsulatus homologous to that of Escherichia coli was identified. rpmF encodes ribosomal protein L32, plsX plays an undefined role in membrane lipid synthesis, and fabH encodes beta-ketoacyl-acyl carrier protein synthase III. The R. capsulatus plsX gene complemented a defect in an E. coli strain with the plsX50 mutation. Overproduction of the fabH gene product of R. capsulatus in E. coli resulted in dramatically increased beta-ketoacyl-acyl carrier protein synthase III activity. These results indicate that plsX and fabH apparently function the same in R. capsulatus as in E. coli.

Resuscitating and transforming hospice volunteer services.

This article is designed for hospice leaders and volunteers to explore creative ways to deal with the stagnancy that can occur in volunteer programs. Specific strategies, such as nurturing caregivers, transitioning into a gift-based program, and integrating spirituality and creativity into volunteer efforts, provide the focus of the article.

Nucleotide sequence of the glpD gene encoding aerobic sn-glycerol 3-phosphate dehydrogenase of Escherichia coli K-12.

Aerobic sn-glycerol 3-phosphate dehydrogenase, encoded by the glpD gene of Escherichia coli, is a cytoplasmic membrane-associated respiratory enzyme. The nucleotide sequence of glpD was determined. An open reading frame of 501 codons was preceded by a consensus Shine-Dalgarno sequence. The proposed translational start and reading frame of glpD were confirmed by determining the nucleotide sequence across the fusion joint of a glpD-lacZ translational fusion. The predicted molecular weight, 56,750, corresponds well with the reported value of 58,000 for purified sn-glycerol 3-phosphate dehydrogenase. The flavin-binding domain, located at the amino terminus, was identified by comparison with the amino acid sequences of other flavoproteins from E. coli. Repetitive extragenic palindromic sequences were identified downstream of the glpD coding region. The site for transcription termination was located between 87 and 216 bp downstream of the translation stop codon.

Cloning and characterization of the aerobic sn-glycerol-3-phosphate dehydrogenase structural gene glpD of Escherichia coli K-12.

The glpD gene encoding aerobic sn-glycerol-3-phosphate dehydrogenase of Escherichia coli K-12 was cloned into pACYC177 from a lambda glpD transducing phage. The recombinant plasmid, designated pSH55, carried a 7.4-kilobase-pair HindIII fragment containing the glpD and glpR genes. The glpD gene was subcloned into pACYC177 on a 4.4-kilobase-pair BamHI-HindIII fragment. Expression of the cloned glpD gene was regulated in the manner previously described for the chromosomal glpD gene. The position of glpD on this plasmid was determined by Tn1000 insertional inactivation experiments. The glpD gene product, a polypeptide of Mr 55,000, was detected in a maxicell system. Truncated polypeptides replaced the 55,000-molecular-weight polypeptide when plasmid derivatives harboring Tn1000 insertions that inactivate glpD were used as templates. The sizes of these polypeptides confirmed the previously determined direction of transcription and allowed estimation of the translation start site. Determination of the apparent Mr of a hybrid protein encoded by a glpD'-'lacZ fusion provided additional evidence for the position of the glpD control region. The amino-terminal 30 to 60 amino acids of this hybrid protein (provided by glpD) were sufficient for efficient membrane localization of glpD'-'lacZ-encoded beta-galactosidase activity. The glpD3 mutation was mapped within the glpD gene, providing additional evidence that glpD is the structural gene for aerobic sn-glycerol-3-phosphate dehydrogenase.

Structures of the promoter and operator of the glpD gene encoding aerobic sn-glycerol-3-phosphate dehydrogenase of Escherichia coli K-12.

The nucleotide sequence of a 690-base-pair DNA segment containing the control region for the glpD gene encoding aerobic sn-glycerol-3-phosphate dehydrogenase was determined. An ATG translation initiation codon with an adjacent ribosome-binding site was found which preceded an open reading frame continuing 61 codons to the end of the DNA that was sequenced. The start site for transcription, identified by using primer extension analysis, was located 42 base pairs upstream from the proposed Met start codon. The transcription start site was preceded by a region containing typical -10 and -35 sequences found in bacterial promoters. A binding site for the cyclic AMP-cyclic AMP receptor protein complex (identified by comparison with the consensus-binding sequence and verified by using DNase I footprinting) was located just upstream from the -35 sequence, centered at position -63. The interaction site for the glp repressor was identified by using DNase I footprinting. It consisted of a 49-base-pair region which started at the -10 sequence and continued to position +38. This region contained two directly repeated sequences, each possessing hyphenated dyad symmetry, which suggests that the operator is tandemly repeated. The presence of two adjacent operators may explain why expression of the glpD gene is the most sensitive to repressor when compared with expression of the other operons that are members of the glp regulon.

Action at a distance for negative control of transcription of the glpD gene encoding sn-glycerol 3-phosphate dehydrogenase of Escherichia coli K-12.

Aerobic sn-glycerol 3-phosphate dehydrogenase is a cytoplasmic membrane-associated respiratory enzyme encoded by the glpD gene of Escherichia coli. The glpD operon is tightly controlled by cooperative binding of the glp repressor to tandem operators (O(D)1 and O(D)2) that cover the -10 promoter element and 30 bp downstream of the transcription start site. In this work, two additional operators were identified within the glpD structural gene at positions 568 to 587 (0(D)3) and 609 to 628 (0(D)4). The two internal operators bound the glp repressor in the presence or absence of the tandem operators (O(D)1 and O(D)2) in vitro, as shown by DNase I footprinting. To assess a potential regulatory role for the two internal operators in vivo, a glpD-lacZ transcriptional fusion containing all four operators was constructed. The response of this fusion to the glp repressor was compared with those of fusion constructs in which O(D)3 and O(D)4 were inactivated by either deletion or site-directed mutagenesis. It was found that the repression conferred by binding of the glp repressor to O(D)1 and O(D)2 was increased five- to sevenfold upon introduction of the internal operators. A regulatory role for HU was suggested when it was found that repressor-mediated control of glpD transcription was increased fourfold in strains containing HU compared with that of strains deficient in HU. The effect of HU was apparent only in the presence of all four glpD operators. The results suggest that glpD is controlled by formation of a repression loop between the tandem and internal operators. HU may assist repression by bending the DNA to facilitate loop formation.

Ribosomal-associated phosphatidylserine synthetase from Escherichia coli: purification by substrate-specific elution from phosphocellulose using cytidine 5'-diphospho-1,2-diacyl-sn-glycerol.

Cytidine 5'-diphospho-1,2-diacyl-sn-glycerol (CDPdiglyceride):L-serine O-phosphatidyltransferase (EC 2.7.8.8, phosphatidylserine synthetase) is bound tightly to the ribosomes in crude extracts of Escherichia coli. After separation of the enzyme from the ribosomes by the method of Raetz and Kennedy (Raetz, C.R.H., and Kennedy, E.P. (1974), J. Biol. Chem. 249, 5038), we have purified the enzyme to 97% of homogenekty. The major portion of the overall 5500-fold purification was attained by substrate-specific elution from phosphocellulose using CDP-diglyceride in the presence of detergent. The purified enzyme migrated as a single band with an apparent minimum molecular weight of 54 000 when subjected to electrophoresis on polyacrylamide disc gels containing sodium dodecyl sulfate. The purified enzyme catalyzed exchange reactions between cytidine 5'- monophosphate (CMP) and CDP-diglyceride and between serine and phosphatidylserine. The enzyme also catalyzed the hydrolysis of CDP-diglyceride to form CMP and phosphatidic acid. dCDP-diglyceride was equivalent to CDP-diglyceride in all reactions catalyzed by the enzyme. In addition, the purified enzyme catalyzed the formation of phosphatidylglycerol or phosphatidylglycerophosphate at a very slow rate when serine was replaced as substrate by glycerol or sn-glycero-3-phosphate, respectively. These results suggest catalysis occurs via a ping-pong mechanism through the formation of a phosphatidyl-enzyme intermediate.

Identification of promoter and stringent regulation of transcription of the fabH, fabD and fabG genes encoding fatty acid biosynthetic enzymes of Escherichia coli.

In Escherichia coli, amino acid starvation results in the coordinate inhibition of a variety of metabolic activities, including fatty acid and phospholipid biosynthesis. By using primer extension analysis we identified the fabH promoter responsible for transcription of the fabH, fabD and fabG genes encoding fatty acid biosynthetic enzymes. The response of the fabH promoter to amino acid starvation was determined in vivo. Transcripts originating from the fabH promoter were quantified by employing a ribonuclease protection assay. The fabH promoter was subject to relA-dependent stringent control and was repressed approximately 4-fold upon amino acid starvation. The results suggest that inhibition of transcription initiation of lipid biosynthetic genes in starved cells contributes to the stringent control of lipid biosynthesis.