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.     

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).     

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).     

Development of the cation-induced stacking capacity during the biogenesis of higher plant thylakoids

We studied the capacity of the thylakoid membrane to form grana stacks in the presence of cations, monovalent or divalent, added to N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine “low-salt” disorganized plastids during their greening. Grana stacking was monitored by the yield of heavy subchloroplast fractions separated by differential centrifugation after digitonin disruption of plastids (J. H. Argyroudi-Akoyunoglou, 1976, Arch. Biochem. Biophys., 176, 267–274). Primary thylakoids of the agranal protochloroplasts formed in periodic light do not show the cation-induced stacking capacity of the mature green chloroplast thylakoids. Similarly, the cation effect saturates at lower cation concentrations in mature chloroplasts than in plastids of the early stages of greening. The capacity for cation-induced stacking and for saturation of the effect at low cation concentrations appears gradually after exposure to continuous light and parallel to the appearance of chlorophyll b and the polypeptides of the 25,000–30,000 molecular weight range of lipid-free thylakoids, probably derived from the chlorophyll b-rich chlorophyll protein Complex II. The thylakoid peripheral stroma proteins ribulosediphosphate carboxylase and the coupling factor protein are not involved in the cation-induced stacking, since their removal (H. Strotmann, H. Hesse, and K. Edelmann, 1973, Biochim. Biophys. Acta, 314, 202–210) does not affect the thylakoid aggregation.     

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.     

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.     

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.     

Triton X-114 phase fractionation of membrane proteins of the cyanobacterium Anacystis nidulans R2

The thylakoid polypeptides of the cyanobacterium Anacystis nidulans R2 were analyzed by Triton X-114 phase fractionation [C. Bordier (1981) J. Biol. Chem.256, 1604–1607, as adapted for photosynthetic membranes by T. M. Bricker and L. A. Sherman (1982) FEBS Lett.149, 197–202]. In this procedure, polypeptides with extensive hydrophobic regions (i.e., intrinsic proteins) form mixed micelles with Triton X-114, and are separated from extrinsic proteins by temperature-mediated precipitation of the mixed Triton X-114-intrinsic protein micelles. The polypeptide pattern after phase fractionation was highly complementary, with 62 of the observed 110 polypeptide components partitioning into the Triton X-114-enriched fraction. Identified polypeptides fractionating into the Triton X-114 phase included the apoproteins for Photosystems I and II, cytochromes f and b₆, and the herbicide-binding protein. Identified polypeptides fractioning into the Triton X-114-depleted (aqueous) phase included the large and small subunits of RuBp carboxylase, cytochromes c₅₅₀ and c₅₅₄, and ferredoxin. Enzymatic radioiodination of the photosynthetic membranes followed by Triton X-114 phase fractionation allowed direct identification of intrinsic polypeptide components which possess surface-exposed regions susceptible to radioiodination. The most prominent of these polypeptides was a 34-kDa component which was associated with photosystem II. This phase partitioning procedure has been particularly helpful in the clarification of the identity of the membrane-associated cytochromes, and of photosystem II components. When coupled with surface-probing techniques, this procedure is very useful in identifying intrinsic proteins which possess surface-exposed domains. Phase fractionation, in conjunction with the isolation of specific membrane components and complexes, has allowed the identification of many of the important intrinsic thylakoid membrane proteins of A. nidulans R2.     

Kinship and covariance

Price's (1970) covariance theorem can be used to derive an expression for gene frequency change in kin selection models in which the fitness effect of an act is independent of the genotype of the recipient. This expression defines a coefficient of relatedness which subsumes r(Wright, 1922), b(Hamilton, 1972), ρ (Orlove &; Wood, 1978), and R(Michod &; Hamilton, 1980). The new coefficient extends the domain of Hamilton's rule to models in which the average gene frequency of actors differs from that of recipients.     

Vanadate affects glucose metabolism of human erythrocytes

Vanadate causes a rapid breakdown of 2,3-bisphosphoglycerate in intact erythrocytes. This metabolite is nearly stoichiometrically transformed into pyruvate, which changes the cell redox state and enhances the glycolytic flux. The results show that the vanadate effect on 2,3-bisphosphoglycerate, also evident in hemolysates, is attributable to the stimulation of a phosphatase activity of the phosphoglycerate mutase. In agreement with others (J. Carreras, F. Climent, R. Bartrons and G. Pons (1982) Biochim. Biophys. Acta705, 238–242), vanadate is thought to destabilize the phosphoryl form of this enzyme which shows competitive inhibition between the ion and 2,3-bisphosphoglycerate in the mutase reaction. A competitive inhibition between vanadate and glucose 1,6-bisphosphate is also found for phosphoglucomutase, without evidence for phosphatase activity toward the bisphosphate cofactor.     

A mechanism for the hydrolysis of MgATP by actomyosin of skeletal muscle.

Based on a model of the active site of myosin (Ramirez, Shukla &; Levy, 1978), a chemical mechanism for MgATPase and intermediate oxygen exchange is presented. In this mechanism, oxygen exchange takes place via an oxyphosphorane intermediate that undergoes double turnstile rotation (Ugi, Ramirez, Marquarding, Klusacek &; Gillespie, 1971; Ramirez &; Ugi, 1974. During hydrolysis by native skeletal muscle myosin, only three [¹⁸O] atoms from labelled water are rapidly incorporated into the phosphorus that is finally released to the medium as P_i; whereas, during hydrolysis by subfragment 1 (S1), which is the head of myosin, four oxygens are labelled rapidly. To explain this difference, we postulate that cleavage of the (S1)-(S2) hinge in the preparation of S1 modifies the interaction of the oxyphosphorane intermediate at the active site. This enables a normally non-exchangeable oxygen to enter the exchange process. This is consistent with our earlier interpretation to the effect that the active site and the hinge in myosin are relatively close to each other Shukla &; Levy, 1977b; Shukla &; Levy, 1978. We postulate that the major elements of the active site are situated on a 92 amino acid fragment, p₁₀, isolated by Elzinga &; Collins, 1977 from myosin. P₁₀ is now known to be situated in the region that connects the head to the body of a myosin heavy chain (Lu, Sosinki, Balint &; Streter, 1978). An examination of the p₁₀ fragment for a possible point of proteolytic attack in the region of the hinge which will generate S1 revealed lysine 82. Breaking the protein chain at a point so close to the active site pocket could explain the effect of hinge cleavage on oxygen exchange. Two additional features of the present mechanism are: (1) the protonation of P_γ of a MgP_α,P_γ complex of ATP, which depresses monomeric metaphosphate mediated hydrolysis, and enhances oxyphosphorane formation by addition of water to P_γ; (2) the coordination of N^τ-methylhistidinet² of actin with Mg at the active site, which activates the release of the products of hydrolysis.     

A kinetic study of pig liver glucose dehydrogenase.

Utilizing a temperature-sensitive mutant of Escherichia coli K-12 defective in the coupling of metabolic energy to active transport, we have demonstrated that the uptake systems for arabinose, galactose, valine, histidine, and glutamine, which are sensitive to the osmotic shock treatment of L. A. Heppel (1965) (J. Biol. Chem.240, 3685), are all totally defective at the nonpermissive temperature (42 °C) whereas the intracellular ATP levels increase twofold. Phosphate bond energy alone is therefore not sufficient to energize the transport of these substrates. We have confirmed the findings of E. A., Berger and L. A. Heppel (1974) (J. Biol. Chem. 249, 7747) regarding a severe arsenate I inhibition of the uptake of substrates belonging to osmotic shock-sensitive transport systems and therefore conclude that both ATP and a functional ecf gene product are required for the coupling of energy to the transport of these solutes.     

An assay specific for the active form of liver phosphorylase kinase

An assay specific for the active form of liver phosphorylase kinase (EC 2.7.1.38) has been developed utilizing inhibition of the inactive form of phosphorylase kinase by β-glycerophos, phate and ethylene glycol bis(β-aminoethyl ether) N,N′-tetraacetic acid. Following in vitro activation the results compared favorably with those obtained using a less specific assay previously available. (J. R. Vandenheede, S. Keppens, and H. DeWulf, 1977, Biochim. Biophys. Acta.481, 463–470;D. D. Doorneweerd, A. W. H. Tan, and F. Q. Nuttall, 1978, Diabetes27, 474). The in vitro activation of phosphorylase kinase was not associated with the formation of a small-molecular-weight form of the enzyme. The utility of the assay in monitoring in vivo interconversion reactions in response to various physiological stimuli was demonstrated.     

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.     

A note on the sampling theory for infinite alleles and infinite sites models

This note considers sampling theory for a selectively neutral locus where it is supposed that the data provide nucleotide sequences for the genes sampled. It thus anticipates that technical advances will soon provide data of this form in volume approaching that currently obtained from electrophoresis. The assumption made on the nature of the data will require us to use, in the terminology ofKimura (Theor. Pop. Biol.2, 174–208 (1971)), the “infinite sites” model of Karlin and McGregor (Proc. Fifth Berkeley Symp. Math. Statist. Prob.4, 415–438 (1967)) rather that the “infinite alleles” model of Kimura and Crow (Genetics49, 174–738 (1964)). We emphasize that these two models refer not to two different real-world circumstances, but rather to two different assumptions concerning our capacity to investigate the real world. We compare our results where appropriate with corresponding sampling theory of Ewens (Theor. Pop. Biol.3, 87–112 (1972)) for the “infinite alleles” model. Note finally that some of our results depend on an assumption of independence of behavior at individual sites; a parallel paper byWatterson (submitted for publication (1974)) assumes no recombination between sites. Real-world behavior will lie between these two assumptions, closer to the situation assumed by Watterson than in this note. Our analysis provides upper bounds for increased efficiency in using complete nucleotide sequences.     

Involvement of a dithiol protein in mitochondrial energy-linked functions and its relation to coupling factor B.

The coupling factor protein isolated previously in pure form with a molecular weight of 11–12 × 10³ (K.-S. You and Y. Hatefi, 1976, Biochim. Biophys. Acta423, 398–412) has been shown to restore ATP-induced NAD reduction by succinate, transhydrogenation from NADH to NADP, and ATP-³³P_i exchange to submitochondrial particles rendered deficient by extraction with 1 m NH₄OH. The factor also stimulated the oxidative phosphorylation activity of the extracted particles 2.5- to >3-fold. The stimulatory effect of the factor was inhibited by mercurials, Cd²⁺, phenylarsine oxide, and diamide, indicating that it contains an essential dithiol. Dithiothreitol and dihydrolipoate did not replace the protein factor in stimulating the deficient particles. The purified dithiol-containing protein was precipitated and inhibited by antibody raised against coupling factor B. Since this antibody also inhibits coupling factor F₂, it is concluded that the active principle of coupling factors B and F₂ is the purified dithiol-containing protein of molecular weight 11–12 × 10³ referred to above.     

Cell surface glycosyltransferase activities during normal and mutant (TT) mesenchyme migration

Migrating cells possess surface glycosyltransferase activity toward extracellular substrates, and the appearance of enzyme activity coincides with the onset of cellular migration (Shur, 1977a, Shur, 1977b, Develop. Biol.58, 23–39, 40–55; E. A. Turley and S. Roth, 1979, Cell17, 109–115). In this paper, surface glycosyltransferases were examined during normal and $\text{T}\text{T}$ mutant mesenchyme migration. Of six glycosyltransferases that were assayed, only galactosyltransferase was present at significant levels on the cell surface, despite the presence of a variety of intracellular glycosyltransferases. All controls have been performed to show clearly the enzyme activity was cell surface localized. In both normal and $\text{T}\text{T}$ embryos, surface galactosyltransferase activity was localized, by autoradiography, primarily to migrating mesenchymal cells, and to a lesser degree, to presumptive neural epithelium. During primitive streak formation, putative $\text{T}\text{T}$ embryos were devoid of surface galactosyltransferase activity. However, as development progressed, the $\text{T}\text{T}$ level of activity eventually exceeded wild-type levels by two- to sixfold and was evident in $\text{T}\text{T}$ tissues prior to the onset of microscopic pathology. Other surface enzymes assayed did not show any $\text{T}\text{T}\text{-}\text{dependent}$ increase in activity. The extracellular galactosyl acceptors were not chloroform:methanol soluble, and glycopeptides prepared by exhaustive Pronase digestion were excluded from Sephadex G-50. This large galactosylated glycoconjugate was readily digestable with endo-β-galactosidase, and, therefore, is similar to the poly-N-acetyllactosamine chains previously identified on early embryonic tissues (A. Kapadia, T. Feizi, and M. J. Evans, 1981, Exp. Cell. Res.131, 185–195; T. Muramatsu, G. Gachelin, M. Damonneville, C. Delarbre, and F. Jacob, 1979, Cell18, 183–191; A. Heifetz, W. J. Lennarz, B. Libbus, and Y. -C. Hsu, 1980, Develop. Biol.80, 398–408). These results support an involvement of surface galactosyltransferases in mesenchyme formation and during migration on poly-N-acetyllactosamine substrates.     

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.     

Fusion of chick embryo skeletal myoblasts: interactions of prostaglandin E1, adenosine 3':5' monophosphate, and calcium influx

In the accompanying paper (J. D. David, W. M. See, and C.-A. Higginbotham, 1981, Develop. Biol.82, 297–307) we demonstrated that a net calcium influx into fusion-competent myoblasts is a requisite step in membrane fusion. Zalin and Montague, 1974, Zalin, 1977 has shown that a prostaglandin E₁ (PGE₁)-dependent transient rise in cAMP occurs 5–6 hr prior to myoblast fusion. In this communication we show that (1) the increase in intracellular cAMP precedes, and/or is independent of, the calcium influx; (2) the calcium influx is either directly or indirectly dependent on PGE₁ activity as well as PGE₁ synthesis; and (3) although the cAMP increase may be essential for fusion, it is not sufficient in the absence of calcium influx. Our experiments define fusion competency, at a minimum, as (1) the accumulation of extracellular PGE₁ receptors; (2) the accumulation of intracellular cAMP receptors; and (3) the ability to respond to a calcium influx.