Intact ribonucleic acid (RNA) has been prepared from tissues rich in ribonuclease such as the rat pancreas by efficient homogenization in a 4 M solution of the potent protein denaturant guanidinium thiocyanate plus 0.1 M 2-mercaptoethanol to break protein disulfide bonds. The RNA was isolated free of protein by ethanol precipitation or by sedimentation through cesium chloride. Rat pancreas RNA obtained by these means has been used as a source for the purification of alpha-amylase messenger ribonucleic acid.
Hydrogenases that are composed of two dissimilar subunits have been identified as beterodimeric (NiFe) or (NiFeSe) hydrogenases. Hydrogenases having more than two subunits are designated as multimeric (NiFe) or (NiFeSe) hydrogenases. The multimeric hydrogenases can be further subdivided on the basis of the involvement of the unique electron acceptors, F420 and NAD + as the F420-(NiFe) hydzogenases and the NAD+-(NiFe) hydrogenase. This connotation reflects the molecular relationships within the gene family and accommodates a number of biochemical realities. NICKEL HYDROOENASE FAMILY
The genes encoding the two structural subunits of Escherichia coli hydrogenase 2 (HYD2) have been cloned and sequenced. They occur in an operon (hyb) which contains seven open reading frames. An hyb deletion mutant (strain AP3) failed to grow on dihydrogen-fumarate medium and also produced very low levels of HIYD1. All seven open reading frames are required for restoration of wild-type levels of active HYD2 in AP3.The hyb operon was mapped at 65 min on the E. coli chromosome.Under anaerobic growth conditions, Escherichia coli produces three different nickel-containing hydrogenases (3, 39). Hydrogenase 3 (HYD3) is part of the formate hydrogenlyase (FHL) complex and is responsible for formate-dependent dihydrogen (H2) evolution. The operon encoding HYD3 and other accessory electron transport components of the FHL complex, hyc, has been identified and is located at 58 min on the E. coli chromosome (7). The highly oxygen-labile nature of HYD3 has precluded detailed biochemical characterization. HYD2 is involved in H2 uptake and can be differentially induced to high levels when cells are grown in medium containing H2 as an electron donor and fumarate as an electron acceptor (3,23,25,39). An active component of HYD2 has been purified and shown to be a heterodimeric enzyme with a 58-kDa large subunit and a 30-kDa small subunit (4). Although mutants defective in H2 uptake have been described (23,25), detailed analysis of the operon encoding HYD2 has not been carried out. HYDl has also been purified and shown to consist of a large (60 kDa) subunit and a small (30 kDa) subunit (16,40). An active form of HYD1 containing only the large subunit has also been purified and characterized (1, 16). The operon encoding the two structural subunits of HYD1 (hya) contains a total of six genes and has been mapped at 22 min on the E. coli chromosome (30,31). The function of HYD1 is not understood, but it is believed to have a role in hydrogen cycling during fermentative growth. In addition to the operons coding for the structural components of the three hydrogenases, a fourth operon, hyp, located at 58 min, is essential for activity of all three hydrogenases (20,26,38). At least one of the genes in this operon (hypB) is involved in nickel metabolism, most probably via nickel insertion into apoenzyme (27).In this paper, we present the DNA sequence of the operon encoding HYD2 (hyb), which contains seven open reading frames (ORFs). Cassette mutagenesis of the hyb operon on the chromosome resulted in a total loss of HYD2 expression and activity, as well as in significant reduction in HYD1 activity. MATERIALS AND METHODSBacterial strains. All bacterial strains used were E. coli K-12 derivatives and are listed in Table 1 [pH 7.0]), resuspended in the same buffer to an optical density of 0.5 at 600 nm, and used for whole-cell enzyme assays. Cell extracts were prepared by sonicating cell suspensions on ice with a model W385 sonicator (Heat Systems) for 20 5-s bursts. Triton X-100 was added to a final concentration of 2% (vol/vol), when req...
Human cathepsin G is a serine proteinase with chymotrypsin-like specificity found in both polymorphonuclear leukocytes (neutrophils) and the U937 leukemic cell line. Utilizing RNA from the latter, we have constructed a cDNA library in lambda gt11 and isolated a clone which apparently codes for the complete amino acid sequence of this enzyme. Analysis of the sequence reveals homology with rat mast cell proteinase II (47%) but a greater degree of identity (56%) with a product of activated mouse cytotoxic T lymphocytes. The close relationship between the three proteins indicates similarities in substrate specificity and in biosynthesis which we predict involves removal of a two amino acid activation peptide during or just before packaging into their respective storage granules.
Serial analysis of gene expression was used to profile transcript levels in Arabidopsis roots and assess their responses to 2,4,6-trinitrotoluene (TNT) exposure. SAGE libraries representing control and TNT-exposed seedling root transcripts were constructed, and each was sequenced to a depth of roughly 32,000 tags. More than 19,000 unique tags were identified overall. The second most highly induced tag (27-fold increase) represented a glutathione S-transferase. Cytochrome P450 enzymes, as well as an ABC transporter and a probable nitroreductase, were highly induced by TNT exposure. Analyses also revealed an oxidative stress response upon TNT exposure. Although some increases were anticipated in light of current models for xenobiotic metabolism in plants, evidence for unsuspected conjugation pathways was also noted. Identifying transcriptome-level responses to TNT exposure will better define the metabolic pathways plants use to detoxify this xenobiotic compound, which should help improve phytoremediation strategies directed at TNT and other nitroaromatic compounds.
Deletion mutants of Escherichia coli specific for hydrogenase isoenzyme 1 (HYD1) have been constructed and characterized. The hya operon, which contains genes for the two HYD1 structural subunits and four additional genes, was mapped at 22 min on the E. coli chromosome. The total hydrogenase activities of the HYD1-negative mutant and wild-type strains were similar. However, the formate dehydrogenase activity associated with the formate hydrogen lyase pathway was lower in the mutant. The hya mutant (strain AP1), complemented with only the hydrogenase structural genes (hyaAB), produced antigenically identifiable but inactive HYD1 protein.The first five genes of hya (hyaA to hyaE) were required for the synthesis of active HYD1, but wild-type levels of HYDl activity were restored only when mutant cells were transformed with all six genes of the operon. When AP1 was complemented with hya carried on a high-copy-number plasmid, the HYD1 structural subunits were overexpressed, but the excess protein was unprocessed and localized in the soluble fraction of the cell. The products of hyaDEF are postulated to be involved in the processing of nascent structural subunits (HYAA and HYAB). This processing takes place only after the subunits are inserted into the cell membrane. It is concluded that the biosynthesis of active HYD1 is a complex biochemical process involving the cellular localization and processing of nascent structural subunits, which are in turn dependent on the insertion of nickel into the nascent HYD1 large subunit.Hydrogen metabolism in Escherichia coli is tightly regulated by parameters of growth (2, 27) and involves three discrete nickel-containing hydrogenases: two electrophoretically stable, membrane-bound heterodimeric enzymes, hydrogenase 1 (HYD1) (28) and hydrogenase 2 (HYD2) (3), and a labile hydrogen-evolving hydrogenase, hydrogenase 3, which is as yet uncharacterized (27). HYD1 has been purified from anaerobically grown cells and biochemically characterized (28). It has a molecular mass of 200 kDa, is composed of two large (60-kDa) and two small (32-kDa) subunits, and contains 11 nonheme iron atoms and 1 g-atom of nickel per mol of enzyme (28 (16,24,25,30,33); and (iii) mutants unable to utilize hydrogen in the presence of electron acceptors (16,32). None of the mutants, however, have been shown to specifically impair HYD1 activity, indicating that the mutations are not in the hya operon. In this paper, we report the construction, biochemical characterization, and genetic analysis of HYD1-specific deletion mutants. MATERIALS AND METHODSBacterial strains and culture conditions. All bacterial strains used in this study are derivatives of E. coli K-12 and are listed in Table 1. Bacteria were cultured in Luria broth with 0.4% glucose as the carbon source (LBG). Antibiotics were added at final concentrations of 50 jig/ml (kanamycin), 100 jig/ml (ampicillin), and 20 ,ug/ml (chloramphenicol). For studying the incorporation of nickel into HYD1, cells were grown anaerobically in LBG in the presence of 1.2 ,iM...
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