Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.30.2 (endonuclease)
 18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Transfection has been found and characterized in pneumococcus. For replicating omega3 phage DNA extracted from infected cells, transfection was relatively efficient and rose linearly with DNA concentration and quadratically with time, according to T(T - 3.5) min(2). For mature DNA extracted from phage particles, transfection was hardly detectable below 1 mug/ml but increased about as the cube of the DNA concentration up to 100 mug/ml, and was still rising at concentrations over 200 mug/ml. The kinetics suggest a dependence on a mixed cubic function of the time of exposure of cells to mature DNA. Cell and phage DNAs competed with each other for transformation and transfection. Transfection was reduced much more strongly than transformation in cells that were deficient in the membrane-bound endonuclease required for conversion of donor duplex DNA to intracellular single strands; these data agree with the kinetic data in implying that independent entry of segments of two strands is necessary for transfection by replicating omega3 phage DNA and entry of at least three strands is necessary for transfection by mature DNA. To reconcile differing DNA concentration dependences of transfection and transformation with a common entry path, it was necessary to reexamine data on transformation and to recognize that this process continued to rise slowly through the concentration region usually described as "plateau." These results and the transfection data reflect multiple binding and nicking events that occurred on the cell surface before entry. Our conclusion is that transfection in pneumococcus occurs by association inside the cell of segments of single strands of phage DNA that have entered independently, creating gapped structures that need repair synthesis to create infective centers. Physical recombination is therefore automatically a prerequisite to transfection.
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PMID:Transfection in pneumococcus: single-strand intermediates in the formation of infective centers. 2 40

Programmed cell death or apoptosis occurs under physiological conditions as a result of physiological effectors. It is a relatively slower process and requires active participation of the cell in the suicidal mechanism. Apoptosis is controlled by precise intrinsic genetic programme and may be induced by almost all those stimuli causing necrosis. The role played by the intensity in determining the death process and the underlying mechanism is imperfectly understood. Morphologically apoptotic cells appear as small condensed body. The chromatin is dense and fragmented, packed into compact membrane-bound bodies together with randomly distributed cell organelles. The plasma membrane loses its characteristic architecture and shows extensive blebbing. It buds off projections so that the whole cell may split into several membrane-bound apoptotic bodies. Significant chemical changes take place in the plasma membrane. This helps in recognition of the apoptotic bodies by phagocytes. At this moment it is unclear if all cells can undergo apoptosis or it is a characteristic of only some tissues which are predisposed to apoptotic death being directly under the control of hormones or growth factors. Experimental studies aimed at comparison of induction of apoptosis in cells of different origin are warranted to elucidate this point. Biochemically a pre-commitment step for induction of death programmation through macromolecular synthesis is essential for most systems. The double-stranded linker DNA between nucleosomes is cleaved at regular inter-nucleosomal sites through the action of a Ca2+, Mg(2+)-sensitive neutral endonuclease. Zinc is a potent inhibitor of the enzyme. Calcium probably plays a key controlling role in activation of the enzyme since prevention of Ca2+ increase prevents endonuclease activation. It is becoming evident that signal transduction through appropriate receptors control the Ca2+ flux in the cells. Most apoptotic cells require synthesis of RNA and proteins. Delay or abrogation of apoptosis by inhibition of macromolecular synthesis is well known. The dying cells show high mRNA levels for several enzymes. Several degradative enzymes become active. Regulatory proteins maintain control over the apoptotic cascade. At the molecular level, search has been initiated for the mammalian equivalents of the cell death (ced) gene. Activation of several specific genes is indicated. Specific expression of cell death-associated gene products (e.g. TRPM-2/SGP-2) has been reported in several unrelated apoptotic cell systems. Sequential induction of c-fos, c-myc and 70 kDa heat shock protein is reported. Studies demonstrate that certain genes must remain in a transcriptionally active demethylated state during programmed cell death. Recent evidences clearly indicate that apoptosis may be positively or negatively modulated by certain genes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Programmed cell death: concept, mechanism and control. 142 Jul 28

Apoptosis is a process by which cells die in a controlled and programmed manner in response to specific stimuli, often following extrinsic and intrinsic signals which ultimately cause the "switching on" of cell death regulatory genes. Condensation of chromatin and cytoplasm, fragmentation of the cell and formation of membrane-bound bodies containing intact organelles (apoptotic bodies), and phagocytosis of these bodies by resident cells are the major structural changes associated with apoptosis. Biochemically, activation of a nonlysosomal endonuclease is a cardinal feature of this mode of cell death. Several genes have been implicated in the execution of apoptosis. A signal transduction mechanism is suspected to regulate the phenomenon. Although apoptosis is widely considered as an adaptive response to physiological or near physiological stimuli, several noxious agents can initiate the reaction and thus it is often a toxicological response.
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PMID:The biology and pathology of programmed cell death (apoptosis). 160 1

The two closely linked fdhD and fdhE genes of Escherichia coli are required for the formation of active membrane-bound phenazine methosulfate-linked formate dehydrogenase (FDH-PMS). Both genes were isolated from a cosmid library. Restriction endonuclease analysis associated with Mu dII1734 insertion mutagenesis indicated that the two genes were separated by at least 4 kilobases and transcribed in opposite orientations. Initial experiments indicate that the region between the two genes seems not to be essential to FDH-PMS activity. fdhD and fdhE were expressed either in maxicells or from the T7 promoter-polymerase system. They were shown to encode proteins with approximate Mr 30,500 and 32,000, respectively. Both proteins appeared in the soluble fraction and were not recognized by an FDH-PMS-specific antiserum. Therefore, neither fdhD nor fdhE plays a structural role in the formation of FDH-PMS. Expression of a phi(fdhD-lacZ) operon fusion was decreased about threefold by aerobiosis but was indifferent to other effectors tested. It was unaffected by pfl, chlA, selA, and fnr mutations. Expression of a phi(fdhE-lacZ) operon fusion was slightly induced by nitrate. This induction, requiring the presence of functional chl and fnr alleles, was mediated via nitrate metabolism. Transcription of phi(fdhE-lacZ) fusion was fully dependent on wild-type sel alleles. This might suggest the participation of fdhE in the synthesis of the selenopolypeptide of FDH-PMS.
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PMID:Identification and expression of the Escherichia coli fdhD and fdhE genes, which are involved in the formation of respiratory formate dehydrogenase. 217 Mar 40

DNA-protein complexes that are capable of RNA synthesis in vitro (transcriptionally active chromosomes) were isolated from both chloroplasts and etioplasts of mustard (Sinapis alba L.) seedlings. Analyses of the polypeptide pattern of these complexes indicate that they comprise a specific subset of plastid proteins, distinct from the overall pattern of either the soluble or membrane-bound plastic proteins. DNA-protein complexes from the two plastid types have polypeptides in common. However, at least several polypeptides are highly enriched in either the chloroplast or the etioplast DNA-protein complex. The EcoRI restriction endonuclease fragments of the DNA associated with the complexes from either plastid type are the same. They are identical with the fragments obtained from highly purified chloroplast DNA. The transcriptional activity of the chloroplast complex is more than ten times higher than the activity of the etioplast complex. However, the complexes from either plastid type are capable of transcribing DNA regions containing genes for both the plastid rRNAs and for plastid proteins. In vitro transcripts were found to hybridize not only to DNA regions for mature in vivo RNA but also to adjacent regions, indicating synthesis of precursor RNA sequences by the transcriptionally active chromosomes.
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PMID:Characterization of transcriptionally active DNA-protein complexes from chloroplasts and etioplasts of mustard (Sinapis alba L.). 258 Jul 5

The dimethyl sulfoxide (DMSO) reductase operon coding for a membrane-bound iron-sulfur, molybdoenzyme, which functions as a terminal reductase in Escherichia coli, has been isolated and cloned from an E. coli gene bank. Two clones, MV12(pLC19-36) and MV12(pLC43-43), overexpressed both DMSO and trimethylamine N-oxide (TMAO) reductase activities 13- to 15-fold compared with wild-type cells. Amplification was highest in cells grown anaerobically on fumarate, while cells grown on DMSO or TMAO displayed reduced levels of enzyme amplification. Growth on nitrate or aerobic growth repressed expression of the enzyme. A 6.5-kilobase-pair DNA restriction endonuclease fragment was subcloned from pLC19-36 into the vector pBR322, yielding a recombinant DMSO reductase plasmid, pDMS159. Two polypeptides were amplified and identified on sodium dodecyl sulfate-polyacrylamide gels of proteins from E. coli HB101 harboring pDMS159: a membrane-bound protein with molecular weight 82,600 and a soluble polypeptide with molecular weight 23,600. Three plasmid-encoded polypeptides with molecular weights of 87,500, 23,300, and 22,600 were detected by in vivo transcription/translation studies. The smallest subunit was poorly defined and not detectable by Coomassie blue staining. The DMSO reductase operon was localized to the 20.0-min position on the E. coli linkage map.
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PMID:Molecular cloning and expression of the Escherichia coli dimethyl sulfoxide reductase operon. 283 66

In an attempt to establish whether Escherichia coli B infected with N130 (an amber mutant defective in gene 46) is recombination-deficient, the postinfection fate of (14)C-labeled N130 parental deoxyribonucleic acid (DNA) was followed, its amount in complex with the host cell membrane being determined in sucrose gradients after mild lysis of the infected cells. The parental DNA was found to undergo gradual detachment from the membrane during infection. Pulse-chase experiments similarly showed that newly synthesized DNA is normally attached to the host cell membrane and is detached by endonucleolytic breakage at a late stage of infection. The conclusion is that only attached DNA molecules are replicated by membrane-bound replicase, whereas those detached by endonucleolytic breakage are not. It thus seems that the gene 46 product controls the activity of a nuclease whose main function is recombination of DNA nicked by endonuclease, thereby attaching it to the host cell membrane. The rate of T4 DNA synthesis is apparently governed by the efficiency of recombination. Supporting evidence was found in experiments with the double mutant N130 x N134 (genes 46, 33).
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PMID:Role of gene 46 in bacteriophage T4 deoxyribonucleic acid synthesis. 494 Feb 42

A membrane-bound endonuclease has been isolated from mitochondrial fractions of Saccharomyces cerevisiae. The enzyme is present in a stable complex and has an approximate molecular weight of 14 000. It requires Mg2+ or Mn2+ for activity, and has an optimum pH of 7.0. Its activity with native DNA is five times less than with denatured DNA in 0.05 M KCl and is very low in 0.2 M KCl. The activity with RNA is 40% of that with denatured DNA; the two substrates are competitive. Its mode of action is endonucleolitic, cuts both strands of native lambda DNA at the same or nearby sites. After mild digestion of DNA, analysis of 5'-end groups of the digestion products indicated a marked preference for deoxythymidylic and deoxyguanilic acid residues as the site of enzymatic cleavage. After exhaustive digestion of DNA, mononucleotides (2.4%), dinucleotides (70.5%) and trinucleotides (27%) ending in 5'-phosphate are produced.
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PMID:An endonuclease from yeast mitochondrial fractions. 616 38

Si+ hybrid ColE1 plasmids of the Clarke-Carbon collection (Clarke, C., and Carbon, J. (1976) Cell 9, 91-99) which eliminate the sn-glycerol 3-phosphate growth requirement of a mutant of Escherichia coli with a Km defect in sn-glycerol-3-phosphate acyltransferase (plsB) were identified. Marked overproduction of a plasmid-encoded sn-glycerol-3-phosphate acyltransferase with a wild type Km in a host plsB- background indicates that the hybrid plasmids carry a structural gene for this enzyme. In addition, all of these plasmids suppress the phenotype of a mutation in a second locus involved in phospholipid biosynthesis, dgk (diglyceride kinase), and one of them also bears the dnaB structural gene. Diglyceride kinase activity is also overproduced in these strains. The linkage of plsB, dgk and dnaB loci was confirmed by transduction analysis which demonstrated the clockwise gene order malB, dnaB, dgk, plsB, and uvrA near Minute 91 on the E. coli linkage map. This is in contrast to the previously reported co-transduction of plsB with dctA near Minute 78 (Cronan, J. E., Jr., and Bell, R. M. (1974) J. Bacteriol., 120, 227-233). Recloning of restriction endonuclease fragments and in vitro mutagenesis have localized the dgk, and plsB loci to a 2.2-megadalton DNA segment, and have demonstrated that diglyceride kinase and sn-glycerol-3-phosphate acyltransferase activities reside in separate polypeptides. Availability of these clones and mutationally altered derivatives has allowed the identification of a single polypeptide (Mr = 83,000) corresponding to the sn-glycerol-3-phosphate acyltransferase and purification of this membrane-bound enzyme to near homogeneity (Larson, T. J., Lightner, V. A., Green, P. R., Modrich, P., and Bell, R. M. (1980) J. Biol. Chem. 255, 9421-9426). The size of the plsB polypeptide indicates that a major fraction of the DNA segment to which this gene has been localized is involved in coding for the sn-glycerol-3-phosphate acyltransferase.
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PMID:Membrane phospholipid synthesis in Escherichia coli. Cloning of a structural gene (plsB) of the sn-glycerol-3-phosphate acyl/transferase. 625 Oct 87

Tightly membrane-bound polysomes were isolated from livers of rats administered trans-stilbene oxide. Epoxide hydratase mRNA was enriched from these polysomes using immunochemical techniques and oligo(dT)-cellulose chromatography. This resulted in an increase in message concentration over that found in noninduced membrane-bound cDNA, synthesized from enriched mRNA, was inserted into the ampicillin resistance gene of pBR322 using oligo(dG)-oligo(dC) tailing. Clones containing sequences complementary to epoxide hydratase mRNA were selected by differential colony hybridization using [32P]cDNA synthesized from immunoenriched mRNA and [32P]cDNA synthesized from nonenriched mRNA. Plasmids from four clones, which only annealed with the enriched probe, were isolated and shown to specifically hybridize with epoxide hydratase mRNA by hybrid selection-translation. A composite restriction endonuclease map of the plasmid inserts was constructed which spanned 1310 base pairs and represented approximately 80% of the message sequence. The 3'-5' orientation of this map relative to the epoxide hydratase mRNA was also determined.
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PMID:Cloning of epoxide hydratase complementary DNA. 626 98


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