Organization and control in the arginine biosynthetic pathway of Neurospora.

Eight enzymes involved in the conversion of acetylglutamate to arginine in Neurospora crassa were studied. The data indicate that of three enzymes early in the sequence, only the first, acetylglutamate kinase, is a nonorganellar enzyme. The next two, N-acetyl-gamma-glutamyl-phosphate reductase and acetylornithine aminotransferase, are in the mitochondrion, which was previously shown to contain the subsequent enzymes: acetylornithine-glutamate acetyltransferase, ornithine carbamyltransferase, and carbamyl-phosphate synthetase A (arginine specific). The last two enzymes of the pathway, argininosuccinate synthetase and argininosuccinate lyase, were previously shown to be cytosolic. All enzymes but one have low amplitudes or repression. Their levels respond little to arginine excess and are about twofold elevated (threefold for ornithine carbamyltransferase) as a result of arginine limitation in the arg-12-8 strain. No restriction of the incorporation of mitochondrial enzymes into mitochondria could be detected when the levels of these enzymes were elevated. Two enzymes, acetylglutamate kinase and carbamyl-phosphate synthetase A, which initiate the synthesis of the ornithine and guanidino moieties of arginine, respectively, show the lowest specific activities in crude extract. These enzymes display special regulatroy features. Acetylglutamate kinase, which has a typically low amplitude of repression, is subject to feedback inhibition. Carbamyl-phosphate synthetase A is wholly insensitive to arginine or citrulline in vitro or in vivo, but displays a very large amplitude of repression (about 60-fold). It is unique in that it can be almost completely repressed by growth of mycelia in excess arginine. These data suggest that mitochondrial localization may be incompatible with a mechanism of feedback inhibition by a cytosolic effector, arginine. Further, they suggest that the high repressibility of carbamyl-phosphate synthetase A compensates for its feedback insensitivity.     

N-acetyl-L-glutamate synthase of Neurospora crassa. Characteristics, localization, regulation, and genetic control

N-Acetylglutamate synthase, an early enzyme of the arginine pathway, provides acetylglutamate for ornithine synthesis in the so-called "acetylglutamate cycle." Because acetylglutamate is regenerated as ornithine is formed, the enzyme has only a catalytic or anaplerotic role in the pathway, maintaining "bound" acetyl groups during growth. We have detected this enzyme in crude extracts of Neurospora crassa and have localized it to the mitochondria along with other ornithine biosynthetic enzymes. The enzyme is bound to the mitochondrial membrane. The enzyme has a pH optimum of 9.0 and Km values for glutamate and CoASAc of 6.3 and 1.6 mM, respectively. It is feedback-inhibited by L-arginine (I0.5 = 0.16 mM), and its specific activity is augmented 2-3-fold by arginine starvation of the mycelium. Mutants of the newly recognized arg-14 locus lack activity for the enzyme. Because these mutants are complete auxotrophs, we conclude that N-acetylglutamate synthase is an indispensible enzyme of arginine biosynthesis in N. crassa. This work completes the assignment of enzymes of the arginine pathway of N. crassa to corresponding genetic loci. The membrane localization of the enzyme suggests a novel mechanism by which feedback inhibition might occur across a semipermeable membrane.     

Simultaneous purification of three mitochondrial enzymes. Acetylglutamate kinase, acetylglutamyl-phosphate reductase and carbamoyl-phosphate synthetase from Neurospora crassa

The early enzymes of arginine biosynthesis in Neurospora crassa are localized in the mitochondrion and catalyze the conversion of glutamate to citrulline. The final conversion of citrulline to arginine occurs via two enzymatic steps in the cytoplasm. We have devised a method for the isolation and purification of three of the mitochondrial arginine biosynthetic enzymes from a single extract. Acetylglutamate kinase and acetylglutamyl-phosphate reductase (both products of the complex arg-6 locus) were purified to homogeneity and near homogeneity, respectively. The large catalytic subunit of carbamoyl-phosphate synthetase was also purified to homogeneity. The three enzymes were resolved into separate fractions by chromatography on three dye-ligand affinity resins, which are specific for nucleotide binding enzymes and have a high protein binding capacity. High performance liquid chromatography was employed in the final stages of purification and was extremely effective in fractionating both acetylglutamate kinase and acetylglutamyl-phosphate reductase from proteins with very similar properties, which were not removed by other techniques. The purified proteins were used to raise specific antisera against these proteins. Acetylglutamate kinase and acetylglutamyl-phosphate reductase were shown to be immunologically unrelated. This finding suggests that the arg-6 locus encompasses two nonoverlapping cistrons. The antisera raised against carbamoyl-phosphate synthetase has been shown to cross-react with related enzymes in Saccharomyces cerevisiae, Escherichia coli, and rat liver (Ness, S. A., and Weiss, R. L. (1985) J. Biol. Chem. 260, 14355-14362). Acetylglutamate kinase is a regulatory enzyme and has been shown to be feedback-inhibited by arginine. We have determined the submitochondrial localization of acetylglutamate kinase and the second arg-6 product, acetylglutamyl-phosphate reductase. Both enzymes were shown to be soluble matrix enzymes. We discuss the relevance of this finding with respect to possible mechanisms for end product inhibition of a mitochondrial enzyme by a cytoplasmic effector.     

Arginine metabolism in Saccharomyces cerevisiae: subcellular localization of the enzymes.

Subcellular localization of enzymes of arginine metabolism in Saccharomyces cerevisiae was studied by partial fractionation and stepwise homogenization of spheroplast lysates. These enzymes could clearly be divided into two groups. The first group comprised the five enzymes of the acetylated compound cycle, i.e., acetylglutamate synthase, acetylglutamate kinase, acetylglutamyl-phosphate reductase, acetylornithine aminotransferase, and acetylornithine-glutamate acetyltransferase. These enzymes were exclusively particulate. Comparison with citrate synthase and cytochrome oxidase, and results from isopycnic gradient analysis, suggested that these enzymes were associated with the mitochondria. By contrast, enzymatic activities going from ornithine to arginine, i.e., arginine pathway-specific carbamoylphosphate synthetase, ornithine carbamoyltransferase, argininosuccinate synthetase, and argininosuccinate lyase, and the two first catabolic enzymes, arginase and ornithine aminotransferase, were in the "soluble" fraction of the cell.     

Effect of level of dietary protein on arginine-stimulated citrulline synthesis. Correlation with mitochondrial N-acetylglutamate concentrations.

Increases in dietary protein have been reported to increase the rate of citrulline synthesis and the level of N-acetylglutamate in liver. We have confirmed this effect of diet on citrulline synthesis in rat liver mitochondria and show parallel increases in N-acetylglutamate concentration. The magnitude of the effect of arginine in the suspending medium on citrulline synthesis was also dependent on dietary protein content. Mitochondria from rats fed on a protein-free diet initially contained low levels of N-acetylglutamate, and addition of arginine increased the rate of its synthesis. Citrulline synthesis and acetylglutamate content in these mitochondria increased more than 5-fold when 1 mM-arginine was added. A diet high in protein results in mitochondria with increased N-acetylglutamate and a high rate of citrulline synthesis; 1 mM-arginine increased citrulline synthesis in such mitochondria by only 36%. The concentration of arginine in portal blood was 47 microM in rats fed on a diet lacking protein, and 182 microM in rats fed on a diet containing 60% protein, suggesting that arginine may be a regulatory signal to the liver concerning the dietary protein intake. The rates of citrulline synthesis were proportional to the mitochondrial content of acetylglutamate in mitochondria obtained from rats fed on diets containing 0, 24, or 60% protein, whether incubated in the absence or presence of arginine. Although the effector concentrations are higher than the Ka for the enzymes, these results support the view that concentrations of both arginine and acetylglutamate are important in the regulation of synthesis of citrulline and urea. Additionally, the effects of dietary protein level (and of arginine) are exerted in large part by way of modulation of the concentration of acetylglutamate.     

Stimulatory effect of arginine on acetylglutamate synthesis in isolated mitochondria of mouse and rat liver.

N-Acetyl-L-glutamate synthetase (EC 2.3.1.1) catalyses the synthesis of N-acetyl-L-glutamate, an allosteric activator of carbamoyl-phosphate synthetase I in the liver of ureotelic animals, and the first enzyme is activated specifically by arginine. We have proposed that arginine can stimulate acetylglutamine synthetase in vivo and thereby increase the mitochondrial content of acetylglutamate. The effects of arginine on acetylglutamate synthesis in isolated mitochondria were investigated in detail in the present work. When rat liver mitochondria were isolated and incubated with [14C]glutamate and unlabelled acetate as substrates, acetyl[14C]glutamate synthesis in the mitochondria was more extensive in the presence than in the absence of L-arginine. There was no significant difference between the specific radioactivities of intramitochondrial [14C]glutamate in the presence and absence of arginine. When rat liver mitochondria were incubated with [14C]acetate and unlabelled glutamate as substrates, arginine also stimulated acetyl[14C]glutamate synthesis in the isolated mitochondria. L-Lysine or L-homoarginine, which does not activate acetylglutamate synthetase, had no effect on acetylglutamate synthesis, in the isolated mitochondria. The arginine concentration giving half-maximal synthesis of acetylglutamate in isolated mitochondria was about 50 microM, which is in the range of physiological concentrations of arginine in the liver. As we previously reported [Kawamoto, Ishida, Mori & Tatibana (1982) Eur. J. Biochem. 123, 637-641], the sensitivity of acetylglutamate synthetase to arginine activation undergoes marked changes after food ingestion. The extent of arginine activation of acetylglutamate synthesis in isolated mitochondria correlated well with the sensitivity of acetylglutamate synthetase extracted from the mitochondria to arginine activation. These data lend further support to the idea that arginine itself activates the mitochondrial synthesis of acetylglutamate.     

Utilization of arginine by Klebsiella aerogenes.

Klebsiella aerogenes utilized arginine as the sole source of carbon or nitrogen for growth. Arginine was degraded to 2-ketoglutarate and not to succinate, since a citrate synthaseless mutant grows on arginine as the only nitrogen source. When glucose was the energy source, all four nitrogen atoms of arginine were utilized. Three of them apparently did not pass through ammonia but were transferred by transamination, since a mutant unable to produce glutamate by glutamate synthase or glutamate dehydrogenase utilized three of four nitrogen atoms of arginine. Urea was not involved as intermediate, since a unreaseless mutant did not accumulate urea and grew on arginine as efficiently as the wild-type strain. Ornithine appeared to be an intermediate, because cells grown either on glucose and arginine or arginine alone could convert arginine in the presence of hydroxylamine to ornithine. This indicates that an amidinotransferase is the initiating enzyme of arginine breakdown. In addition, the cells contained a transaminase specific for ornithine. In contrast to the hydroxylamine-dependent reaction, this activity could be demonstrated in extracts. The arginine-utilizing system (aut) is apparently controlled like the enzymes responsible for the degradation of histidine (hut) through induction, catabolite repression, and activation by glutamine synthetase.     

Amino acid-specific ADP-ribosylation: structural characterization and chemical differentiation of ADP-ribose-cysteine adducts formed nonenzymatically and in a pertussis toxin-catalyzed reaction.

ADP-ribosylation is a posttranslational modification of proteins by amino acid-specific ADP-ribosyltransferases. Both pertussis toxin and eukaryotic enzymes ADP-ribosylate cysteine residues in proteins and also, it has been suggested, free cysteine. Analysis of the reaction mechanisms of cysteine-specific ADP-ribosyltransferases revealed that free ADP-ribose combined nonenzymatically with cysteine. L- and D-cysteine, L-cysteine methyl ester, and cysteamine reacted with ADP-ribose, but alanine, serine, lysine, arginine, N-acetyl-L-cysteine, 2-mercaptoethanol, dithiothreitol, and glutathione did not. The 1H NMR spectrum of the product, along with the requirement for both free sulfhydryl and amino groups of cysteine, suggested that the reaction produced a thiazolidine linkage. ADP-ribosylthiazolidine was labile to hydroxylamine and mercuric ion, unlike the ADP-ribosylcysteine formed by pertussis toxin and NAD in guanine nucleotide-binding (G-) proteins, which is labile to mercuric ion but stable in hydroxylamine. In the absence of G-proteins but in the presence of NAD and cysteine, pertussis toxin generated a hydroxylamine-sensitive product, suggesting that a free ADP-ribose intermediate, expected to be formed by the NADase activity of the toxin, reacted with cysteine. Chemical analysis, or the use of alternative thiol acceptors lacking a free amine, is necessary to distinguish the enzymatic formation of ADP-ribosylcysteine from nonenzymatic formation of ADP-ribosylthiazolidine, thereby differentiating putative NAD:cysteine ADP-ribosyltransferases from NAD glycohydrolases.     

A eukaryote without catalase-containing microbodies: Neurospora crassa exhibits a unique cellular distribution of its four catalases

Microbodies usually house catalase to decompose hydrogen peroxide generated within the organelle by the action of various oxidases. Here we have analyzed whether peroxisomes (i.e., catalase-containing microbodies) exist in Neurospora crassa. Three distinct catalase isoforms were identified by native catalase activity gels under various peroxisome-inducing conditions. Subcellular fractionation by density gradient centrifugation revealed that most of the spectrophotometrically measured activity was present in the light upper fractions, with an additional small peak coinciding with the peak fractions of HEX-1, the marker protein for Woronin bodies, a compartment related to the microbody family. However, neither in-gel assays nor monospecific antibodies generated against the three purified catalases detected the enzymes in any dense organellar fraction. Furthermore, staining of an N. crassa wild-type strain with 3,3'-diaminobenzidine and H(2)O(2) did not lead to catalase-dependent reaction products within microbodies. Nonetheless, N. crassa does possess a gene (cat-4) whose product is most similar to the peroxisomal type of monofunctional catalases. This novel protein indeed exhibited catalase activity, but was not localized to microbodies either. We conclude that N. crassa lacks catalase-containing peroxisomes, a characteristic that is probably restricted to a few filamentous fungi that produce little hydrogen peroxide within microbodies.     

A new yeast metabolon involving at least the two first enzymes of arginine biosynthesis: acetylglutamate synthase activity requires complex formation with acetylglutamate kinase.

Open reading frame YJL071W of Saccharomyces cerevisiae was shown to be ARG2 and identified as the structural gene for acetylglutamate synthase, first step in arginine biosynthesis. The three Ascomycete acetylglutamate synthases characterized to date appear homologous, but unlike the other enzymes of the yeast arginine biosynthesis pathway, they showed no significant similarity to their prokaryotic equivalents. The measured synthase activity did not increase with the number of ARG2 gene copies unless the number of ARG5,6 gene copies was increased similarly. ARG5,6 encodes a precursor that is maturated in the mitochondria into acetylglutamate kinase and acetylglutamyl-phosphate reductase, catalyzing the second and third steps in the pathway. The results imply that the synthase must interact stoichiometrically in vivo with the kinase, the reductase, or both to be active. Results obtained with synthetic ARG5 and ARG6 genes suggested that both the kinase and the reductase could be needed. This situation, which has completely escaped notice in yeast until now, is reminiscent of the observation in Neurospora crassa that nonsense arg-6 kinase/reductase mutants lack synthase activity (Hinde, R. W., Jacobson, J. A., Weiss, R. L., and Davis, R. H. (1986) J. Biol. Chem. 261, 5848-5852). In immunoprecipitation experiments, hemagglutinin-tagged synthase coprecipitated with a protein proven by microsequencing to be the kinase. Western blot analyses showed that the synthase has reduced stability in the absence of the kinase/reductase. Our data demonstrate the existence of a new yeast arginine metabolon involving at least the first two, and possibly the first three, enzymes of the pathway. Hypotheses regarding the biological significance of this interaction are discussed.     

Acetyl coenzyme a-glutamate acetyltransferase and N-acetylornithine-glutamate acetyltransferase of chlorella

The enzymic formation of acetylglutamate has been studied in Chlorella vulgaris extracts. Acetyl CoA and N(2)-acetyl-l-ornithine served as substrates for glutamate acetylation whereas acetylphosphate, N(5)-acetyl-l-ornithine, and N(2)-acetyl-2,4-diamino butyrate were ineffective. Acetyl CoA-glutamate transacetylase and acetylornithine-glutamate transacetylase activities have been purified over 180-fold with no indication of any separation of activities. The acetyl CoA activity was more labile than acetylornithine activity so that preparations having acetylornithine-glutamate transacetylase activity but no acetyl CoA-glutamate transacetylase activity were obtained. The two acetylating activities appear to be properties of one enzyme with one portion more easily denatured.Both acetylating activities had pH optima between 8 and 8.5. The Km value for glutamate was 3 mm for both activities. The Km values were 0.2 mm for acetylornithine and 3.2 mm for acetyl CoA. Arginine inhibited acetyl CoA-glutamate transacetylase (Ki = 0.94 mm) and acetylglutamate phosphokinase (Ki = 0.5 mm) but had no effect on acetylornithine-glutamate transacetylase. The lack of an inhibitory effect of proline on any of the three enzymic activities indicates that acetylglutamate is not a normal intermediate in proline biosynthesis. Growth of Chlorella with arginine as a nitrogen source had no effect on enzyme levels, showing that end-product repression is not a control factor in arginine biosynthesis in Chlorella. In Chlorella, arginine controls its own biosynthesis by inhibiting acetylglutamate phosphokinase and controls the level of acetylated intermediates by inhibiting acetyl CoA-glutamate transacetylase.     

Amino acid-specific ADP-ribosylation

[adenine-U-14C]ADP-ribose-agmatine and [adenine-U-14C ))ADP-ribose-histone were synthesized by an NAD:arginine ADP-ribosyltransferase from [14C]NAD and agmatine and histone, respectively. The pseudo-first order rate constants for breakdown of the two components either in 0.4 N NaOH or in 0.4 M neutral hydroxylamine were identical. Hydroxylamine treatment of [14C]ADP-ribose-agmatine or [32P]ADP-ribose-histone yielded a single radioactive product which was separated by high pressure liquid chromatography and identified as ADP-ribose-hydroxamate by the formation of a ferric chloride complex. Hydrolysis of ADP-ribose-hydroxamate with snake venom phosphodiesterase resulted in the formation of 5'-AMP, consistent with the presence of a pyrophosphate bond. Incubation of ADP-ribose-[14C]agmatine, synthesized by the ADP-ribosyltransferase from NAD and [14C]agmatine, with 0.4 M neutral hydroxylamine resulted in the release of [14C]agmatine rather than phosphoribosyl[14C]agmatine. In addition, neither NAD nor ADP-ribose reacts with hydroxylamine; i.e. there was no evidence of nucleophilic attack by hydroxylamine at the pyrophosphate bond. The ADP-ribosyl-protein linkage formed by the NAD:arginine ADP-ribosyltransferase is considerably more stable to hydroxylamine than is the ADP-ribose-glutamate bond. The presence of ADP-ribose-arginine and ADP-ribose-glutamate synthesized by the ADP-ribosyltransferase and poly(ADP-ribose) synthetase, respectively, may be the chemical basis for the "hydroxylamine-stable" and "hydroxylamine-labile" bonds described by Hilz (Hilz, H. (1981) Hoppe-Seyler's Z. Physiol. Chem. 362, 1415-1425).     

A single precursor protein for two separable mitochondrial enzymes in Neurospora crassa

The arg-6 locus of Neurospora crassa encodes two early enzymes of the arginine biosynthetic pathway, acetylglutamate kinase and acetylglutamyl-phosphate reductase. Previous genetic and biochemical analyses of this locus and its products showed that: 1) strains carrying polar nonsense mutations in the acetylglutamate kinase gene lacked both enzyme activities (Davis, R.H., and Weiss, R.L. (1983) Mol. Gen. Genet. 192, 46-50), and 2) the proteins isolated from mitochondria were completely separable (Wandinger-Ness, A., Wolf, E.C., Weiss, R.L., and Davis, R.H. (1985) J. Biol. Chem. 260,5974-5978). These data suggested that the two enzymes were initially synthesized as a single precursor which was subsequently cleaved into two distinct polypeptides. We report here the identification of a high molecular weight protein, synthesized in vitro from isolated N. crassa RNA, that contains sequences corresponding to acetylglutamate kinase as well as acetylglutamyl-phosphate reductase. An analogous precursor was identified in vivo by pulse-labeling experiments. The precursor was similar to other mitochondrial precursors in that its uptake and processing in vivo was rapid and required an intact mitochondrial electrochemical gradient. This represents the first report of a bifunctional protein precursor which gives rise to two mitochondrial enzymes.     

Effect of guanine nucleotides on polyphosphoinositide synthesis in rat liver plasma membranes.

The subcellular distributions of endogenous ADP-ribosylation products in hearts from 1-day-old neonatal and adult rats were investigated. In adult rat heart a 52 kDa mono-ADP-ribosylation product was identified in the plasma membrane fraction. In contrast, in neonatal rat heart a 130 kDa poly-ADP-ribosylation product was present in the nuclear fraction. The monomeric and polymeric nature of the two ADP-ribosylation products was determined by their sensitivity to thymidine and by analysis of their snake venom phosphodiesterase products. NADP+ enhanced both the mono- and polymeric reactions. The ADP-ribose-protein linkage of the adult 52 kDa product was stable to 1 h of treatment with hydroxylamine (0.5 M) and mercury ions, but was sensitive to alkali and a 12 h treatment with hydroxylamine (1 M). This is suggestive of an arginine linkage. The 130 kDa poly-ADP-ribosylation product from the neonatal rat heart was alkalilabile but stable to both hydroxylamine and HgCl2. This implies the presence of an unusual linkage in the 130 kDa product. The presence of these different ADP-ribosylation products in adult and neonatal rat hearts suggests the possible importance of these proteins and their ADP-ribosylation during cardiac development.     

Arginine biosynthesis in Thermotoga maritima: characterization of the arginine-sensitive N-acetyl-L-glutamate kinase

To help clarify the control of arginine synthesis in Thermotoga maritima, the putative gene (argB) for N-acetyl-L-glutamate kinase (NAGK) from this microorganism was cloned and overexpressed, and the resulting protein was purified and shown to be a highly thermostable and specific NAGK that is potently and selectively inhibited by arginine. Therefore, NAGK is in T. maritima the feedback control point of arginine synthesis, a process that in this organism involves acetyl group recycling and appears not to involve classical acetylglutamate synthase. The inhibition of NAGK by arginine was found to be pH independent and to depend sigmoidally on the concentration of arginine, with a Hill coefficient (N) of approximately 4, and the 50% inhibitory arginine concentration (I0.5) was shown to increase with temperature, approaching above 65 degrees C the I0.50 observed at 37 degrees C with the mesophilic NAGK of Pseudomonas aeruginosa (the best-studied arginine-inhibitable NAGK). At 75 degrees C, the inhibition by arginine of T. maritima NAGK was due to a large increase in the Km for acetylglutamate triggered by the inhibitor, but at 37 degrees C arginine also substantially decreased the Vmax of the enzyme. The NAGKs of T. maritima and P. aeruginosa behaved in gel filtration as hexamers, justifying the sigmoidicity and high Hill coefficient of arginine inhibition, and arginine or the substrates failed to disaggregate these enzymes. In contrast, Escherichia coli NAGK is not inhibited by arginine and is dimeric, and thus the hexameric architecture may be an important determinant of arginine sensitivity. Potential thermostability determinants of T. maritima NAGK are also discussed.     

Modulation of the activity of rat liver acetylglutamate synthase by pH and arginine concentration

Acetylglutamate is known to modulate the activity of carbamyl phosphate synthetase, and thus probably to participate in regulation of the urea cycle. Therefore factors that regulate the activity of acetylglutamate synthase are relevant to control of urea synthesis and of systemic pH. An increase in the concentration of arginine increases both Vmax and S0.5 for glutamate of acetylglutamate synthase from rat liver. An increase in pH causes S0.5 for glutamate to decrease and does not affect Vmax. As a consequence of these effects, a rapid rate of synthesis of acetylglutamate requires a concentration of arginine of about 25 microM or higher and either relatively high glutamate concentrations or relatively high pH.     

Enzymatic conversion of glutamate to delta-aminolevulinate in soluble extracts of the unicellular green alga, Chlorella vulgaris

Cell-free preparations from the unicellular green alga, Chlorella vulgaris, catalyze the conversion of glutamate to delta-aminolevulinate, which is the first committed step in heme and chlorophyll biosynthesis. Most activity remains in the supernatant fraction after centrifugation at 264,000g. Additional activity can be solubilized from the high-speed pellet by treatment with 0.5 M NaCl. After gel filtration through Sephadex G-25, the reaction catalyzed by the high-speed supernatant requires glutamate, ATP, Mg2+, and NADPH. Boiled extract is inactive. The pH optimum is between 7.8 and 7.9 and the temperature optimum is 30 degrees C. Concentrations required for half-maximal activity are 0.05 mM glutamate, 0.4 mM ATP, 6 mM MgCl2, and 0.4 mM NADPH or 0.7 mM NADH. The reaction requires no additional amino donor. Involvement of pyridoxal phosphate in the catalytic mechanism is suggested by sensitivity to pyridoxal antagonists; 50% inhibition is achieved with 5 microM gabaculine or 0.4 mM aminooxyacetate. Involvement of two or more enzymes is suggested by the nonlinear reaction rate dependence on protein concentration. Evidence for the involvement of an activated glutamate intermediate was obtained by product formation after sequential addition and removal of substrates, and by inhibition (80%) with 1 mM hydroxylamine. Protoheme inhibits the activity by 50% at 1.2 microM. Preincubation of the extract with ATP causes stimulation and/or stabilization of the activity compared to preincubation without ATP or no preincubation. In preparations obtained from C. vulgaris strain C-10, which requires light for greening, dark-grown cells yield one-third as much activity as 4-h-greened cells.     

Control of the ornithine cycle in Neurospora crassa by the mitochondrial membrane.

In Neurospora crassa, the mitochondrial membrane separates ornithine used in arginine biosynthesis from ornithine used in the arginine degradative pathway in the cytosol. Ornithine easily exchanges across the mitochondrial membrane under conditions appropriate for synthesis of the immediate biosynthetic product, citrulline. Neither of the two mitochondrial enzymes required for the ornithine-to-citrulline conversion is feedback inhibitable in vitro. Nevertheless, when arginine is added to cells and cytosolic ornithine increases as arginine degradation begins, the rate of citrulline synthesis drops immediately to about 20% of normal (B. J. Bowman and R. H. Davis, Bacteriol. 130:285-291, 1977). We have studied this phenomenon in citrulline-accumulating strains carrying the arg-1 mutation. Citrulline accumulation is blocked when arginine is added to an arg-1 strain but not to an arg-1 strain carrying a mutation conferring insensitivity of intramitochondrial ornithine synthesis to arginine. Thus, ornithine is evidently unable to enter mitochondria in normal (feedback-sensitive) cells. Other experiments show that cytosolic ornithine enters mitochondria readily except when arginine or other basic amino acids are present at high levels in the cells. We conclude that in N. crassa, the mitochondrial membrane has evolved as a secondary site of feedback inhibition in arginine synthesis and that this prevents a wasteful cycling of catabolic ornithine back through the anabolic pathway. This is compared to the quite different mechanism by which the yeast Saccharomyces cerevisiae prevents a futile ornithine cycle.     

Lysosomal and cytosolic sialidases in rabbit alveolar macrophages: demonstration of increased lysosomal activity after in vivo activation with bacillus Calmette-Guerin

Sialidase activity was assayed in homogenized rabbit alveolar macrophages using a fluorogenic substrate: sodium 4-methylumbelliferyl-alpha-D-neuraminate. After differential centrifugation one acid-active enzyme (optimum pH 4.2) was detected in the 16,000 X g pellet that contained lysosomes, mitochondria and peroxisomes. A second activity, with an optimum pH of 5.4, was found in the cytosolic fraction. The acid-active sialidase accounted for more than 95% of the total sialidase activity in crude homogenate. When alveolar macrophages were collected from rabbits stimulated with bacillus Calmette-Guerin (BCG), the acid-active sialidase specific activity was increased 2.5-fold whereas other lysosomal enzymes such as N-acetylglucosaminidase and beta-galactosidase were stable. The cytosolic sialidase activity did not change.