UNIPROT:P06889 - FACTA Search

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Query: UNIPROT:P06889 (Mol)
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Purified bovine pituitary plasma membranes possess two specific LH-RH binding sites. The high affinity site (2.5 X 10(9) l/mol) has low capacity (9 X 10(-15) mol/mg membrane protein) while the low affinity site 6.1 X 10(5) l/mol) has a much higher capacity (1.1 X 10(-10) mol/mg). Specific LH-RH binding to plasma membranes is increased 8.5-fold during purification from homogenate whilst adenylate cyclase activity is enriched 7--8-fold. Distribution of specific LH-RH binding to sucrose density gradient interface fractions parallels that of adenylate cyclase activity. Mg2+ and Ca2+ inhibit specific [125I]LH-RH binding at micromolar concentrations. Synthetic LH-RH, up to 250 microgram/ml, failed to stimulate adenylase cyclase activity of the purified bovine membranes. Using a crude 10,800 g rat pituitary membrane preparation, LH-RH similarly failed to activate adenylate cyclase even in the presence of guanyl nucleotides. These data confirm the presence of LH-RH receptor sites on pituitary plasma membranes and suggest that LH-RH-induced gonadotrophin release may be mediated by mechanisms other than activation of adenylate cyclase.
Mol Cell Endocrinol 1978 Jun
PMID:LH-RH binding to purified pituitary plasma membranes: absence of adenylate cyclase activation. 21 61

The phosphorylation of proteins in the synaptic plasma membrane is a rather slow reaction taking several minutes to saturate all the phosphate acceptor sites. (The time for half the protein bound phosphate groups to turnover is about 1 min). A divalent cation is needed as a cofactor for the reaction. At high (0.5 mM) ATP concentrations Mg2+ is more effective than Mn2+ but at low (10 microM) ATP concentrations the reverse is the case. Zn2+ and Ca2+ support very little phosphorylation.
Mol Cell Biochem 1979 Oct 15
PMID:The time course of the phosphorylation of proteins in the synaptic plasma membrane and the effect of certain cations. 22 75

A large number of hormones and neurotransmitters activate adenylyl cyclase [ATP, pyrophosphate lyase (cyclizing; EC 4.6.1.1.)] catalyzing the formation of cAMP and PPi from ATP in the presence of Mg2+. The cAMP formed is in turn responsible for eliciting the physiological responses of these hormones and neurotransmitters. In addition to hormones and neurotransmitters, fluoride ion, cholera toxin and guanyl nucleotides (GTP and GTP analogs such as GTP gamma S and GMP-P(NH)P) also stimulate adenylyl cyclase activity (Perkins, 1974; Birnbaumer, 1977; Gill, 1977). It has become evident that hormonally-responsive adenylyl cyclase is a multi-component system consisting of at least 3 physically distinct units. The first is the hormone receptor containing a specific site for a given hormone. The second is the catalytic moiety (C component) of adenylyl cyclase bearing the site responsible for catalysis of the cyclizing reaction. The third is the guanyl nucleotide regulatory subunit (G component) which binds guanyl nucleotide. Recently, a GTPase activity has been found to be associated with the G component of adenylyl cyclase (Cassel and Selinger, 1976; Cassel et al., 1977a, b; Lambert et al., 1979). In this review we will present information on the regulation of hormonally-responsive adenylyl cyclases. This is not intended to be a comprehensive review of the literature. Rather, it represents our views on the current status of the regulation of cAMP formation.
Mol Cell Endocrinol 1979 Dec
PMID:Guanyl nucleotide regulation of hormonally-responsive adenylyl cyclases. 23 Jan 2

Some properties of an enzyme designated as a two component ribonucleotidyl transferase from E. coli are presented. The enzyme in the presence of magnesium ions catalyzes the synthesis of polyribonucleotide chains using all four nucleoside triphosphates as substrates. The enzyme consists of two components; component A in the presence of Mg2+ catalyzes the synthesis of homo- and heteropolymers using ATP, CTP and UTP but not GTP as substrates. Component B itself does not catalyze any synthesis at all, but its addition to component A affects this component in two ways: quantitatively- the activity of component A considerably increases, and qualitatively- both components together are capable of catalyzing the synthesis of polyribonucleotides consisting of all four ribonucleotides.
Mol Biol Rep 1975 Jul
PMID:A tw0-component ribonucleotidyl transferase from E. coli. 24 Jan 21

Measurements of association constants (Ka) of specific [14C]Phe-tRNAPhe with a 30S..poly(U) complex revealed that values of these constants vary from 0.5.10(7) up to 1.5.10(8) M--1 when different 30S subunit preparations were used at the same medium conditions (20 mM Mg2+, 200 mM NH4, 0 degrees C). Analysis of these data showed that the higher the rotor speeds were used during separation of 70S ribosomes into subunits, the less Ka values were measured. In special experiments on sedimentation of pure 30S subunits at different rotor speeds it was found that the decrease of Ka values was caused due to the additional reversible dissocation of ribosomal proteins from 30S subunits at high (the order of 100 000.g) centrifugal fields. As a possible mechanism of such dissociation we suggest the influence of high hydrostatic pressure on the association constants of S-proteins with 30S subunits. Data presented in this paper demonstrate that at least one of the reasons for the physical and functional heterogeneity of 30S subunits in vitro derives from the application of high centrifugal fields during isolation of ribosomal subunits.
Mol Biol (Mosk)
PMID:[Nature of the heterogeneity of 30S ribosomal subparticles in vitro. I. Effect of large centrifugal fields during 30S subparticle isolation on their capacity for codon-dependent tRNA binding]. 24 37

A medium was found in which manganese efficiently induces erythromycin-resistant mitochondrial mutations, and which is suitable for measuring Mn2+ uptake and the labelling of DNA (fig. 1). Mn2+ uptake is stimulated by glucose and slowed down by cycloheximide (Fig 2). Mg2+ competes with Mn2+ uptake much stronger than does Zn2+ (Fig. 3). All of the conditions which favour Mn2+ uptake also favour induction of erythromycin-resistant mutations (Tables 3, 4). Mn2+ strongly inhibits protein synthesis (Table 1). Nuclear DNA replication is also strongly inhibited by this cation, while mitochondrial DNA replication is only weakly inhibited during the first 3 h of labelling, but there is small if any increase of the label incorporation between the 3rd 6th h of labelling (Table 2). The relation between label incorporation into mitDNA and mutation induction by manganese is not straightforward (Table 5). From among 11 divalent cations tested, only Mn2+ was capable of inducing mitochondrial erythromycin-resistant mutations (Table 6).
Mol Gen Genet 1977 Feb 28
PMID:Manganese mutagenesis in yeast. VI. Mn2+ uptake, mitDNA replication and ER induction: comparison with other divalent cations. 32 69

The presumptive tof gene product of Coli phage 434 has been purified from cells carrying lambdaimm434cIdv plasmid known to contain only some of the "early" genes of phage 434 and lambda. It was detected and tentatively identified as tof protein primarily by its ability to specifically bind to phage 434 DNA. The protein has a molecular weight of about 11,000 and requires Mg2+ for specific DNA binding, unlike 434 cI-repressor.
Mol Gen Genet 1977 Nov 14
PMID:Purification and some properties of presumptive tof gene product of Coli phage 434. 34 Sep 2

Optical and fluorescent characteristics of fluorescein covalently attached to 3'-end of tRNAFhe and X-nucleotide in the extra arm of several species of tRNA from E. coli have been studied. The probe is shown to be a sensitive factor indicating the conformational change of tRNA induced by Mg2+ and Na+ ions. By measuring the extent of energy transfer the distances between the fluorescent probe attached to 3'-terminus and X-nucleotide of tRNA and specific binding site of ethidium bromide on tRNA were determined to be 40.5 A and 32.5 A, respectively. The distances measured are in good agreement with the NMR spectroscopy data showing that the specific binding site for ethidium bromide on tRNA is localised near the sixth base pair of the acceptor stem.
Mol Biol (Mosk)
PMID:[Study of the structure of tRNA by the energy migration method using fluorescent labels covalently bound to specific tRNA loci]. 34 62

We have investigated the nonspecific interactions of Escherichia coli RNA polymerase core and holoenzyme with double-stranded (ds) and single-stranded (ss) DNA. Binding constants for these interactions as functions of such solution variables as monovalent and/or divalent cation concentration, temperature, or pH were determined by the method of deHaseth et a. [deHaseth, P.L., Gross, C.A., Burgess, R.R. and Record, M.T. (1977), Biochemistry 16, 4777--4783] from analysis of the elution of the proteins from small columns containing immobilized DNA. This technique, although as yet empirical, has been demonstrated to yield accurate binding constants fot the nonspecific interation of lac repressor with ds DNA. We find that observed binding constants (Kobsd) are extraordinarily sensitive functions of the monovalent cation concentration for the interactions of both core and holoenzyme with ds DNA. In the absence of divalent cations, the derivatives --(d log Kobsd/d log [Na+]) are 11 +/- 2 for the holo--ds DNA interaction and 21 +/- 3 for the core--ds DNA interaction. Consequently, approximately 11 and 21 low-molecular-weight ions are released, iin the thermodynamic sense, in the formation of the holo--ds and core--ds complexes, respectively (Record, M.T., Jr., Lohman, T.M., and deHaseth, P.L. (1976), J. Mol. Biol. 107, 145--158; Record, M.T., Jr., Anderson, C.F., and Lohman, T.M. (1978), Q. Rev. Biophys., in press). Ion release is a thermodynamic driving force for these nonspecific interactions and causes the stability of the complexes to increase very substantially with a reduction in monovalent ion concnetration. Possible molecular models which account for the different salt sensitivities of the holo--ds and core--ds complexes are discussed. Effects of the competitive ligand Mg2+ on these interactions are also examined. Substantial ion release (approximately 18 monovalent ions) also accompanies the interaction of either holo or core polymerase with ss DNA. Over the range of ion concentrations investigated the holo--ss interaction is substantially stronger than the core--ss interaction; furthermore, we conclude that the interactions of polymerase with ss DNA are, in general, stronger than the nonspecific interations of the enzyme with ds DNA. It is likely that the nonspecific interactions of RNA polymerase with DNA have physiological relevance. Not only is it plausible to assume that the same regions of the protein are involved in both specific and nonspecific interactions, but in addition nonspecific interactions of RNA polymerase and DNA may play role in determining the availability of this protein, in both the thermodynamic and the kinetic sense, for promoter binding and RNA chain initiation [von Hippel. P.H., Revzin, A., Gross, C.A., and Wang, A.C. (1974), Proc. Natl. Acad. Sci U.S.A. 71, 4808--4812]. Consequently, the strong dependences of the nonspecific interactions of RNA polymerase on ionic conditions suggest the possibility of a modulating role of ion concentrations in the control of transcription.
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PMID:Nonspecific interactions of Escherichia coli RNA polymerase with native and denatured DNA: differences in the binding behavior of core and holoenzyme. 35 Feb 71

A heat sensitive mutant of E. coli has been analyzed. A shift to restrictive temperature leads to an accumulation of ppGpp and pppGpp in both the parental and the mutant strains (both are relA+). The pool of these compounds is shown to decrease with time after the temperature shift in the case of the parental strain, but remains at the same elevated level in the case of the mutant. The temperature shift of the mutant leads to an apparent reduction of stable RNA synthesis; this inhibition can be released by chloroamphenicol or tetracycline. Gross protein synthesis is more or less unaffected at restrictive temperature. In the parental strain little effect is seen on RNA and protein synthesis after the temperature shift. A relA derivative of the mutant does not show the same inhibition of RNA synthesis at high temperature. Sedimentation analysis suggests that mutant 70S ribosome are more stable, when exposed to a lowered Mg2+ concentration, than are 70S ribosomes from the parental strain. In addition, the relative amounts of the two forms of ribosomal protein S6, which can be obtained on DEAE chromatography (Held et al., 1973), are significantly changed in the mutant.
Mol Gen Genet 1978 Apr 25
PMID:The temperature sensitive mutant 72c. II. Accumulation at high temperature of ppGpp and pppGpp in the presence of protein synthesis. 35 96

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