Transport and metabolism of N-δ-chloroacetyl-l-ornithine by Saccharomyces cerevisiae

The general amino acid transport system of Saccharomyces cerevisiae functions in the uptake of neutral, basic, and acidic amino acids (M. Grenson, C. Hou, and M. Crabeel, 1970,J. Bacteriol. 103, 770–777; J. Rytka, 1975,J. Bacteriol.121, 562–570; C. Darte and M. Grenson, 1975,Biochem. Biophys. Res. Commun.67, 1028–1033). We have previously demonstrated that this transport system can be inhibited by the amino acid, N-δ-chloroacetyl-l-ornithine (NCAO) (F. S., Larimore and R.J. Roon, 1978,Biochemistry17, 431–436). In the present study radiolabeled NCAO was synthesized and its transport and metabolism studied. Under initial rate conditions: (a) NCAO was transported by the general amino acid transport system with a K_m of 52 μm, a V of 32 nmol/min/mg cells, and a pH optimum of 5.0; (b) the V for NCAO transport in gap mutants, which lack the general amino acid transport system, was approximately 1% of that observed with wild-type cells; (c) the V for NCAO in cells deprived of glucose was less than 5% of that observed when glucose was present. NCAO was transiently concentrated more than 1000-fold by yeast cells when glucose served as an energy source. The internal pool of NCAO was metabolized by the yeast cells and the products were excreted. When 100 μm [¹⁴C]NCAO was incubated with a yeast cell suspension for 8 h, more than 95% of the compound was converted into two ninhydrin-negative excretory products. The effect of NCAO on the growth of yeast cells was determined. Wild-type strains did not grow when 1 mm NCAO was present in the medium. The growth of gap mutants was not inhibited by 1 mm NCAO.     

Calmodulin-dependent protein kinase (kinase II) which is involved in the activation of tryptophan 5-monooxygenase catalyzes phosphorylation of tubulin

Tubulin was shown to be an endogenous substrate of the calmodulin-dependent protein kinase (kinase II), which is involved in the activation of tryptophan 5-monooxygenase [T. Yamauchi and H. Fujisawa (1983) Eur. J. Biochem.132, 15–21]. Serine and threonine were identified as the phosphate acceptor amino acids of tubulin. The V_max of the phosphorylation of tubulin and the apparent K_m value for tubulin of calmodulin-dependent protein kinase II were 89 nmol phosphate transferred min^?1 mg kinase II^?1 and 1.7 μm, respectively. The maximum ³²P incorporation into tubulin was 0.18 mol P_i/mol α-tubulin and 0.13 mol P_i/mol β-tubulin. The phosphorylation of tubulin was decreased by the denaturation of tubulin. The phosphorylation of tubulin by kinase II did not affect the assembly of microtubules.     

Trehalose-6-phosphate synthetase activity in extracts of Dictyostelium discoideum.

Trehalose-6-phosphate (T-6-P) synthetase activity in extracts of Dictyostelium discoideum has been reexamined in an effort to resolve discrepancies between the results of previous studies (R. Roth and M. Sussman (1966). Biochim. Biophys. Acta, 122, 225; K. A. Killick and B. E. Wright (1972). J. Biol. Chem., 247, 2967). We find that T-6-P synthetase is not cold sensitive as reported by Killick and Wright (1972), is not present in bacterial-grown vegetative cells (though subject to some modulation by other nutritional conditions), and is not in our hands unmasked or activated by ammonium sulfate fractionation. We conclude that the pattern of T-6-P synthetase accumulation and disappearance during fruiting body construction in D. discoideum is as originally described by R. Roth and M. Sussman (1968). J. Biol. Chem., 243, 5081) and confirmed elsewhere (P. C. Newell et al. (1972). J. Mol. Biol., 63, 373; R. W. Brackenbury et al. (1974). J. Mol. Biol., 90, 529; B. D. Hames and J. M. Ashworth (1974). Biochem. J., 142, 301).     

Proteolysis in eucaryotic cells: Aminopeptidases and dipeptidyl aminopeptidases of yeast revisited

Using nine different l-aminoacyl-4-nitroanilides and four different dipeptidyl-4-nitroanilides, aminopeptidases and dipeptidyl aminopeptidases active at pH 7.5 and (or) pH 5.5 in logarithmically growing and stationary-phase cells of Saccharomyces cerevisiae were searched for. Ion-exchange chromatography was used to separate the proteins of the soluble cell extract. Besides the three already-characterized aminopeptidases—aminopeptidase I (P. Matile, A. Wiemken, and W. Guyer (1971) Planta (Berlin)96, 43–53; J. Frey and K. H. Röhm (1978) Biochim. Biophys. Acta527, 31–41), aminopeptidase II (J. Frey and K. H. Röhm (1978) Biochim. Biophys. Acta527, 31–41; J. Knüver (1982) Thesis, Fachbereich Chemie, Marburg, FRG), and aminopeptidase Co (T. Achstetter, C. Ehmann, and D. H. Wolf (1982) Biochem. Biophys. Res. Commun.109, 341–347)—12 additional aminopeptidase activities are found in soluble cell extracts eluting from the ion-exchange column. These activities differ from the characterized aminopeptidases in one or more of the parameters such as charge, size, substrate specificity, inhibition pattern, pH optimum for activity and regulation. Also, a particulate aminopeptidase, called aminopeptidase P, is found in the nonsoluble fraction of disintegrated cells. Besides the described particulate X-prolyl-dipeptidyl aminopeptidase (M. P. Suarez Rendueles, J. Schwencke, N. Garcia-Alvarez and S. Gascon (1981) FEBS Lett.131, 296–300), three additional dipeptidyl aminopeptidase activities of different substrate specificities are found in the soluble extract.     

Net uptake of adenine nucleotides by newborn rat liver mitochondria

In newborn rat liver, the adenine nucleotide content (ATP + ADP + AMP) of mitochondria increases severalfold within 2 to 3 h of birth. The net increase in mitochondrial adenines suggests a novel mechanism by which mitochondria are able to accumulate adenine nucleotides from the cytosol (J. R. Aprille and G. K. Asimakis, 1980, Arch. Biochem. Biophys.201, 564.). This was investigated further in vitro. Isolated newborn liver mitochondria incubated with 1 mM ATP for 10 min at 30 °C doubled their adenine nucleotide content with effects on respiratory functions similar to those observed in vivo: State 3 respiration and adenine translocase activity increased, but uncoupled respiration was unchanged. The mechanism for net uptake of adenine nucleotides was found to be specific for ATP or ADP, but not AMP. Uptake was concentration dependent and saturable. The apparent K_m′s for ATP and ADP were 0.85 ± 0.27 mM and 0.41 ± 0.20 mM, respectively, measured by net uptake of [¹⁴C]ATP or [¹⁴C]ADP. The specific activities of net ATP and ADP uptake averaged 0.332 ± 0.062 and 0.103 ± 0.002 nmol/min/mg protein, respectively. ADP was a competitive inhibitor of net ATP uptake. If P_i was omitted from the incubations, net uptake of ATP or ADP was reduced by 51%. Either mersalyl or N-ethylmaleimide severely inhibited the accumulation of adenine nucleotides. Net ATP uptake was stoichiometrically dependent on MgCl₂, suggesting that Mg²⁺ is accumulated along with ATP (or ADP). Uptake was energy dependent as indicated by the following results: Net AdN uptake (especially ADP uptake) was stimulated by the addition of an oxidizable substrate (glutamate) and inhibited by FCCP (an uncoupler). Antimycin A had no effect on net ATP uptake but inhibited net ADP uptake, suggesting that ATP was able to serve as an energy source for its own accumulation. If carboxyatractyloside was added to inhibit the exchange translocase, thereby preventing rapid access of exogenous ATP to the matrix, net ATP uptake was inhibited; carboxyatractyloside had no effect on ADP uptake. It was concluded that the net uptake of adenine nucleotides from the extramitochondrial space occurs by a specific transport process distinct from the classic adenine nucleotide exchange translocase. The accumulation of adenine nucleotides may regulate matrix reactions which are allosterically affected by adenines or which require adenines as a substrate.     

Iron-ethylenediaminetetraacetic acid (EDTA)-catalyzed superoxide dismutation revisited: An explanation of why the dismutase activity of Fe-EDTA cannot be detected in the cytochrome c/xanthine oxidase assay system

The recent assertion of J. Diguiseppi and I. Fridovich (1980, Arch. Biochem. Biophys., 203, 145–150) that Fe-EDTA does not catalyze superoxide dismutation is disputed. By directly observing superoxide generated during pulse radiolysis, we have confirmed the results of a previous study (G. J. McClune, J. A. Fee, G. A. McClusky, and J. T. Groves, 1977, J. Amer. Chem. Soc., 99, 5220–5222) which concluded that Fe-EDTA catalyzed superoxide dismutation. We also demonstrate that the reaction of Fe(II)-EDTA, formed during catalyzed superoxide dismutation, with cytochrome c, the probe molecule in the cytochrome c/xanthine oxidase/xanthine assay system for superoxide dismutase activity, is sufficiently rapid (H. L. Hodges, R. A. Holwerda, and H. B. Gray, 1974, J. Amer. Chem. Soc., 96, 3132–3137) to obscure the weak catalysis of superoxide dismutation by Fe-EDTA.     

Quantitative dependence of mitochondrial oxidative phosphorylation on oxygen concentration: a mathematical model.

The model of Wilson and co-workers (2., 3., Arch. Biochem. Biophys. 182, 749–762) for the regulation of mitochondrial oxidative phosphorylation has been extended to include the dependence on oxygen tension. The derived rate expression correctly describes the observed dependence of cellular energy metabolism on oxygen tension, including the oxygen dependence at “normoxic” physiological values. Experimental evidence is presented that oxidative phosphorylation by suspensions of isolated rat liver mitochondria is also dependent on oxygen concentration up to values of at least 100 μM.     

Enzymatic assays of L-ornithine and L-delta 1-pyrroline-5-carboxylate in tissues, and orniathine-load test in human subjects

The efficiencies of estimates obtained from the direct linear plot (A. Cornish-Bowden and R. Eisenthal, 1978, Biochem. Biophys, Acta, 523, 268) are shown to be dependent on the spacing of substrate concentrations. When substrate values are harmonically spaced, the direct linear plot should not be used. The nonparametric confidence limits based on the direct linear plot are accurate in their confidence coefficient, but their efficiencies are shown to be dependent on substrate spacing. Harmonic spacing is, in general, a more efficient experimental design for estimating K_m than arithmetic spacing when the appropriate estimation methods are used. If assumptions about the error structure cannot be made, the best procedure for estimating K_m is to have harmonic spacing of substrate values and use weighted least squares for estimation. The most accurate and precise estimation of enzyme kinetic parameters requires knowledge of the error structure and utilization of the appropriate nonlinear regression.     

Purification and properties of bovine myocardial phosphorylase phosphatase (protein phosphatase C).

Phosphorylase phosphatase was purified to homogeneity from bovine myocardium by the procedure of Brandt et al. (Brandt, H., Capulong, Z. L., and Lee, E. Y. C., (1975) J. Biol. Chem.250, 8038–8044). The purified enzyme consists of a single polypeptide chain of M_r, 34,800 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The K_m for phosphorylase a was 2.9 μm and at V_max, the enzyme had a turnover number of 11.7 mol phosphorylase a (dimer) converted/mol phosphatase/s. Phosphorylated histone and protamine were also substrates for this phosphatase. The K_m for histone was 46 μm (based on incorporated ³²P_i and at V_max a turnover number of 3.3 mol phosphate released/mol phosphatase/s was found. In general, the properties of the bovine phosphorylase phosphatase closely resemble those found for the rabbit liver enzyme.     

Further characterization and thiophosphorylation of smooth muscle myosin

(i) Myosin from chicken gizzards was purified by a modification of an earlier procedure (M. N. Malik, 1978,Biochemistry17, 27–32). When this myosin, as well as that prepared by the method of A. Sobieszek and R. D. Bremel (1975,Eur. J. Biochem.55, 49–60), was analyzed by gradient slab gel using the discontinuous buffer system of Neville (1971,J. Biol. Chem.246, 6328–6334), a closely spaced doublet in the heavy chain and four light chains were observed as opposed to one heavy chain and two light chains with the method of Weber and Osborn (1969, J. Biol. Chem.244, 4406–4412). These findings raise the possibility of the existence of myosin isoenzymes in smooth muscle. (ii) The purified gizzard myosin was found to be free of kinase and phosphatase. Phosphorylation or thiophosphorylation of myosin was observed only by exogenously adding kinase. A maximum of 1.2 mol of ³²P/mol of myosin and 2.3 mol of ³⁵S/mol of myosin were obtained. The actin-activated ATPase activity depended upon the extent of thiophosphorylation of myosin; a four- to fivefold increase in the activity was observed when myosin was fully thiophosphorylated. Thiophosphorylated myosin was found to be more stable than phosphorylated myosin.     

Pigeon liver malic enzyme: Involvement of an arginyl residue at the binding site for malate and its analogs

Treatment of malic enzyme with arginine-specific reagents phenylglyoxal or 2,3-butanedione results in pseudo-first-order loss of oxidative decarboxylase activity. Inactivation by phenylglyoxal is completely prevented by saturating concentrations of NADP⁺, Mn²⁺, and substrate analog hydroxymalonate. Double log plots of pseudo-first-order rate constant versus concentration yield straight lines with identical slopes of unity for both reagents, suggesting that reaction of one molecule of reagent per active site is associated with activity loss. In parallel experiments, complete inactivation is accompanied by the incorporation of four [¹⁴C]phenylglyoxal molecules, and the loss of two arginyl residues per enzyme subunit, as determined by the colorimetric method of Yamasaki et al (R. B. Yamasaki, D. A. Shimer, and R. E. Feeney (1981) Anal. Biochem., 14, 220–226). These results confirm a 2:1 ratio for the reaction between phenylglyoxal and arginine (K. Takahashi (1968) J. Biol. Chem., 243, 6171–6179) and yield a stoichiometry of two arginine residues reacted per subunit for complete inactivation, of which one is essential for enzyme activity as determined by the statistical method of Tsou (C. L. Tsou (1962) Acta Biochim. Biophys. Sinica, 2, 203–211) and the Ray and Koshland analysis (W. J. Ray and D. E. Koshland (1961) J. Biol. Chem., 236, 1973–1979). Amino acid analysis of butanedione-modified enzyme also shows loss of arginyl residues, without significant decrease in other amino acids. Modification by phenylglyoxal does not significantly affect the affinity of this enzyme for NADPH. Binding of l-malate and its dicarboxylic acid analogs oxalate and tartronate is abolished upon modification, as is binding of the monocarboxylic acid α-hydroxybutyrate. The latter result indicates binding of the C-1 carboxyl group of the substrate to an arginyl residue on the enzyme.     

Investigation of the pH dependence of proton uptake by porcine heart mitochondrial malate dehydrogenase upon binding of NADH

The pH dependence of proton uptake upon binding of NADH to porcine heart mitochondrial malate dehydrogenase (l-malate: NAD⁺ oxidoreductase, EC 1.1.1.37) has been investigated. The enzyme has been shown to exhibit a pH-dependent uptake of protons upon binding NADH at pH values from 6.0 to 8.5. Enzyme in which one histidine residue has been modified per subunit by the reagent iodoacetamide (E. M. Gregory, M. S. Rohrbach, and J. H. Harrison, 1971, Biochim. Biophys. Acta253, 489–497) was used to establish that this specific histidine residue was responsible for the uptake of a proton upon binding of NADH to the native enzyme. It has also been established that while there is no enhancement of the nucleotide fluorescence upon addition of NADH to the iodoacetamide-modified enzyme, NADH is nevertheless binding to the modified enzyme with the same stoichiometry as with native enzyme. The data are discussed in relation to the involvement of the essential histidine residue in the catalytic mechanism of “histidine dehydrogenases” recently proposed by Lodola et al. (A. Lodola, D. M. Parker, R. Jeck, and J. J. Holbrook, 1978, Biochem. J.173, 597–605) and the catalytic mechanism of “malate dehydrogenases” recently proposed by L. H. Bernstein and J. Everse (1978, J. Biol. Chem.253, 8702–8707).     

Cotranslational cleavage of immunoglobulin light chain precursors by plasmacytoma microsomes.

Murine plasmacytoma endoplasmic reticulum which has been freed of ribosomes by EDTA treatment is capable of the cotranslational proteolytic processing of representative λ₁,λ₂, and k immunoglobulin light chain precursors. Messenger RNA fractions from the MOPC-104E, MOPC-315, and MOPC-46B tumor lines were used to direct the synthesis of the light chain precursors in a cell-free system derived from Krebs II ascites cells. The precursor cleavage activity of the plasmacytoma membranes is comparable in activity and in characteristics to that of two well-defined membrane preparations: Krebs II ascites intracellular membranes (E. Szczesna and I. Boime, 1976, Proc. Nat. Acad. Sci. USA73, 1179–1183) and EDTA-treated rough endoplasmic reticulum from canine pancreas (34., 35., J. Cell Biol.67, 852–862). The efficiency of the cleavage reaction appears to be dependent upon the precursor being utilized as a substrate. An assay suitable for a preliminary characterization of the plasmacytoma membrane preparations is described.     

Does copper-d-penicillamine catalyze the dismutation of O2−?

It has been reported (M. Younes and U. Weser, 1977, Biochem. Biophys. Res. Commun.78, 1247–1253; E. Lengfelder and E. F. Elstner, 1978, Hoppe-Seyler's Z. Physiol. Chem.359, 751–757) that the complex [Cu(I)₈Cu(II)₆(D-penicillamine)₁₂Cl]^5?-efficiently catalyzes the dismutation of O₂^? and that this activity is resistant to both EDTA and CN^?. However, careful study has demonstrated that this complex is unable to catalyze the dismutation of O₂^?, but that it slowly decomposes to simpler copper complexes which are active. Moreover, the activity which is observed is suppressed by EDTA or by Chelex 100 treatment.     

S-adenosylhomocysteine hydrolase from hamster liver: Purification and kinetic properties

3-Deazaadenosine is both an inhibitor of and a substrate for S-adenosylhomocysteine hydrolase. Its administration to rats results in the accumulation of both S-adenosylhomocysteine and 3-deazaadenosylhomocysteine in the liver and other tissues. In hamsters, however, the administration of 3-deazaadenosine results only in the accumulation of 3-deazaadenosylhomocysteine (P. K. Chiang and G. L. Cantoni (1979) Biochem. Pharmacol. 28, 1897). In order to investigate the possible reasons for this difference, S-adenosylhomocysteine hydrolase from hamster liver has been purified to homogeneity and some of its kinetic and physical parameters have been determined. The molecular weight of the native enzyme is 200,000 with a subunit molecular weight of 48,000. The K_m's for adenosine and 3-deazaadenosine are about 1.0 μm, and the V_max's are also similar. The K_m for S-adenosylhomocysteine is 1.0 μm, or more than 10 times smaller than the K_m of the rat liver enzyme. This difference in K_m value may explain the differences in the response of rat and hamster liver to the administration of 3-deazaadenosine. S-Adenosylhomocysteine hydrolase from hamster liver exhibits an interesting kinetic property in that its activity can be affected bimodally by either adenosine or adenosine Anal.ogs. At very low concentrations of these analogs, the activity of S-adenosylhomocysteine hydrolase can be stimulated by 10–30%, and at higher concentrations these same analogs become competitive inhibitors.     

An approach to a physico-chemical model of olfactory stimulation in vertebrates by single compounds

During recent years, numerous attempts have been made to correlate both quantitative (Davies &; Taylor, 1959; Engen, 1962; Beck, 1964; Engen, Cain &; Rovee, 1968; Cain, 1969; Dravnieks &; Laffoit, 1970; Laffort, 1969a,b) and qualitative (Davies, 1965; Amoore &; Venstrom, 1965; Döving, 1966a,b; Wright &; Michels, 1964; Leveteau &; MacLeod, 1969) odorous properties of single compounds to their molecular properties. These attempts have been only partially successful.In the present paper we will try to explain the several odorous properties of single compounds on the basis of the non-specific properties of odorants involved in solubility.This model is a first approach, and although it gives statistically highly significant relations, it is not as accurate as those advanced with respect to the physical and sensory dimensions of stimuli in the fields of vision and audition.We will first give the present definitions of the most suitable physicochemical parameters, and then advance quantitative and qualitative models for single compounds. Quantitative odorous properties are: odour threshold, rate of change of odour intensity with odorant concentration in the suprathreshold region, and the somewhat controversial upper odour intensity. Qualitative properties refer to odour character.     

Citrulline synthesis: Regulation by alterations in the total mitochondrial adenine nucleotide content

The total adenine nucleotide content of rat liver mitochondria was varied in vitro over a wide range in order to investigate a possible relationship between net changes in the total matrix ATP + ADP + AMP content and the overall rate of citrulline synthesis. Isolated mitochondria were specifically depleted of matrix adenine nucleotides by incubating with inorganic pyrophosphate (G. K. Asimakis and J. R. Aprille, 1980, Arch. Biochem. Biophys.203, 307–316); alternatively, matrix adenine nucleotides were increased by incubating mitochondria with 1 mm ATP at 30 °C. No exogenous ATP or ADP was included in the subsequent incubations for the determination of citrulline synthesis. Rates varied from 0.1 to 1.6 μmol citrulline/mg protein/h as a linear function of total adenine nucleotide content in the range 2–15 nmol (ATP + ADP + AMP)/mg protein. Further increases in the matrix ATP + ADP + AMP content caused no further increase in citrulline synthesis rates. Changes in the total adenine nucleotide content were reflected in proportional changes in both the ATP and ADP content of the matrix. The $\text{ATP}\text{ADP}$ ratio did not change significantly. Therefore, the variations in citrulline synthesis were most simply explained as the effect of different concentrations of ATP on the activity of carbamoyl-phosphate synthetase. It was concluded that net changes in the total adenine nucleotide content can contribute to the control of citrulline synthesis. These findings are significant in the context of recent evidence which shows that the matrix adenine nucleotide pool size is under hormonal control.     

The steady-state actomyosin ATPase: a further note.

The simplest kinetic scheme capable of describing the MgATPase of actomyosin was proposed by Lymn &; Taylor (1971) as

Previously (Lymn, 1974) I discussed some steady-state properties which could be expected from this scheme, in particular the character of plots of [myosin]/velocity versus 1/[actin]. This note discusses plots of [actin]/velocity versus 1/[myosin] and shows why the two types of plot will not in general give the same value for the extrapolated V_max of actomyosin.     

Acetyl-coenzyme A carboxylase from the developing endosperm of Ricinus communis: II. A two-site kinetic mechanism

The reaction kinetics of acetyl-coenzyme A carboxylase purified from developing castor oil seeds have been examined. On the basis of the substrate interaction and product inhibition results, a hybrid ping-pong mechanism is proposed. This type of mechanism demands that the active site of the enzyme be separated into two functionally distinct catalytic sites. The carboxybiotin intermediate formed at one site by the hydrolysis of ATP swings to the second site where acetyl-CoA is carboxylated to form malonyl-CoA. This hybrid rapid-equilibrium random bi bi uni uni ping-pong mechanism which includes the formation of three abortive complexes, E · HCO₃^? · ADP, E · HCO₃^? · P_i and E · P_i · P_i, is analogous to the hybrid ping-pong mechanism previously described for methylmalonyl-CoA transcarboxylase (D. B. Northrop (1969) J. Biol. Chem., 244, 5808) and pyruvate carboxylase (R. E. Barden, C-H. Fung, M. F. Utter, and M. C. Scrutton (1972) J. Biol. Chem., 247, 1323).