Cell attachment to collagen: The ionic requirements

This study is concerned with three aspects of the ionic requirements for cell attachment to collagen; namely (a) the divalent, (b) monovalent cation specificities and (c) pH optima for cell interaction with collagen. The divalent cation requirement for cell attachment to collagen can be sufficed by Ca²⁺, Mg²⁺ and certain transition group metals; whereas Ba²⁺, Sr²⁺, and polyamines are inactive. The pH optimum for cell attachment in this system occurs in the physiological range. The monovalent cation requirement for cell attachment to collagen is satisfied by isotonic NaCl, KCl, LiCl, NH₄Cl, sucrose, and glucose. Pronounced inhibition of cell attachment occurs under both hypertonic and hypotonic conditions.     

Pectate hydrolases of parsley (Petroselinum crispum) roots

The presence of various enzyme forms with terminal action pattern on pectate was evaluated in a protein mixture obtained from parsley roots. Enzymes found in the soluble fraction of roots (juice) were purified to homogeneity according to SDS-PAGE, partially separated by preparative isoelectric focusing and characterized. Three forms with pH optima 3.6, 4.2 and 4.6 clearly preferred substrates with a lower degree of polymerization (oligogalacturonates) while the form with pH optimum 5.2 was a typical exopolygalacturonase [EC 3. 2.1.67] with relatively fast cleavage of polymeric substrate. The forms with pH optima 3.6, 4.2 and 5.2 were released from the pulp, too. The form from the pulp with pH optimum 4.6 preferred higher oligogalacturonates and was not described in plants previously. The production of individual forms in roots was compared with that produced by root cells cultivated on solid medium and in liquid one.     

CHANGE OF ACID AGGLUTINATION OPTIMUM AS INDEX OF BACTERIAL MUTATION

A distinct difference in acid agglutination optimum for Type D (bacillus of rabbit septicemia) and its mutant form, Type G, has been observed. The optimum for Type D lies between pH 3.5 and pH 3.0. This changes during mutation, the resulting Type G mutants having in general an optimum lying between pH 4.7 and pH 3.8. The constancy of the optimum for Type D is very strict, while that for Type G is slightly less so. The variation is never so great as to cause an overlapping of optima and consequent failure of differentiation. These acid agglutination optima are in the nature of physical constants for the two types and would imply a fundamental difference in the chemical constitution of the organisms. Animal passage, far from causing a reversion of the mutant Type G to the primordial Type D form, brings about a still greater instability in the presence of H ions.     

Antioxidant Enzymatic Activity of Coelomocytes of the Far East Sea Cucumber Eupentacta fraudatrix

The basal activity of superoxide dismutase (SOD), glutathione reductase (GR), and catalase in a pool of coelomocytes as well as in the fraction of amoebocytes and the mixed fraction of amoebocytes and morula-like cells of the sea cucumber Eupentacta fraudatrix is studied. For SOD and catalase, pH optima are in the range of values of pH optimum for tissues of mammals, the pH optimum for GR is shifted to a more acidic region in comparison with the latter enzymes. Temperature optima for all studied enzymes are higher than the usual temperature values of the sea cucumber habitation. A pronounced temperature dependence of all three enzymes is revealed. In coelomocytes, the activities of SOD and catalase, but not of GR, are lower than in the fraction of amoebocytes, but higher than in the mixed fraction of amoebocytes and morula-like cells. The rate of production of active forms of oxygen (AFO) is three times higher in amoebocytes than in the fraction relatively enriched in morula-like cells. Apparently, the main part of the SOD and catalase activities, as well as AFO production in coelomocytes is located in amoebocytes, which confirms the existence of cytophagic function in the latter cells as well as argues in favor of functional differentiation between individual types of coelomocytes.     

Comparison of collagen gels and mammary extracellular matrix as substrata for study of terminal differentiation in rabbit mammary epithelial cells

Mammary epithelial cells were prepared by collagenase digestion of tissue from mid-pregnant rabbits and cultured for up to 6 days on either collagen gels or an extracellular matrix prepared from the same tissue. The behaviour of the cells in serum-supplemented medium containing combinations of insulin, prolactin, hydrocortisone, estradiol and progesterone were monitored by measuring rates of casein synthesis, lactose synthesis, DNA synthesis and protein degradation. After 6 days, epithelial cells on floating collagen gels showed substantial increases in casein synthesis and DNA synthesis over freshly-prepared cells, following a decline during the first 3 days when the collagen gels are contracting. The optimum hormone combination for casein synthesis was insulin + prolactin + hydrocortisone, whereas for optimum DNA synthesis the additional presence of estradiol and progesterone was required. Cells on extracellular matrix showed increased rates of both casein synthesis and DNA synthesis by day 6 in the presence of insulin + prolactin + hydrocortisone, with additional estradiol + progesterone having an inhibitory effect. Whereas on day 2 rates of intracellular protein degradation were generally lower in cells on extracellular matrix, by day 6 rates of protein degradation were lowest in cells cultured on collagen gels with insulin + prolactin + hydrocortisone. In all cases, rates of lactose synthesis fell to low levels as the culture proceeded. Pulse-chase labelling of freshly-prepared cells with [32P]orthophosphate in medium containing serum and insulin + prolactin + hydrocortisone demonstrated that newly-synthesized casein was degraded during its passage through the epithelial cell. The influences of the collagen gels and extracellular matrix and of the hormone combinations on epithelial cell differentiation and secretory activity are discussed.     

Proteolytic and transhydrogenolytic activities in isolated pancreatic islets of rats.

In homogenates and subcellular fractions of pancreatic islets of Wistar rats we could demonstrate three groups of protein degrading enzymes. The proteinases of group 1 are characterized by both trypsin-like and carboxypeptidase B-like specificities with slightly acid pH optima (pH 5.5-6.5) and seem to play important roles in the conversion of proinsulin into insulin. The properties suggest that these enzymes localized in the secretion granule/mitochondria fraction are related to the tissue cathepsins. Group 2 enzymes are thiol-depending proteinases with a pH optimum at 7.0 occuring mainly in the cytosol and to a lesser extent in the fraction of nuclei and cell debris. Group 3 represents the thiol protein oxidoreductase with a pH optimum of 7.0. This enzyme degrading disulfide bonds could also be important in the formation of the disulfide bonds during protein folding after synthesis.     

Phospholipase activities of the P388D1 macrophage-like cell line

The murine macrophage (M phi) cell line, P388D1, was employed as a source of M phi phospholipases in order to characterize the enzymatic properties and subcellular localization of these enzymes because of their importance for prostaglandin biosynthesis. Phospholipase activity was assessed with dipalmitoylphosphatidylcholine (DPPC) as substrate. Phospholipases were characterized with respect to divalent cation dependence, pH optima, and localization in subcellular compartments using linear sucrose gradients. By these criteria a number of different phospholipases were identified. Most importantly, a single Ca2+-dependent activity with a pH optimum of 8.8 was identified in membrane-rich fractions (plasma membrane, mitochondria, and endoplasmic reticulum) and could be clearly separated from the remaining activities, which are Ca2+ independent and exhibit pH optima of 7.5, 5.1, and 4.2. The phospholipases with acidic pH optima may be associated with subcellular components containing lysosomal enzymes and both phospholipase A1 and phospholipase A2 activities are observed. In contrast, the phospholipase activity with a pH optimum of 7.5 sediments with the cytosolic proteins and is inhibited by 5 mM Ca2+. No significant phospholipase C activity was detected in assays performed with or without added Ca2+ at pH's 4.2, 5.1, 7.5, or 8.8 using DPPC as substrate. However, the P388D1 cells do contain a lysophospholipase that is at least 20 times more active than the phospholipase A activities identified. Its presence must be taken into account in evaluating the positional specificities and properties of the macrophage phospholipases.     

Diversity of cellulolytic bacteria in landfill

Nine of 37 cellulolytic bacterial isolates obtained from landfill waste could be easily differentiated on the basis of gross morphological characteristics. Four isolates were selected for further characterization and on the basis of initial results appear to be previously unidentified cellulolytic species of bacteria. An aerotolerant anaerobic, cellulolytic Clostridium and three obligately anaerobic cellulolytic Eubacterium isolates are described. The Clostridium has an unusually high pH optimum for growth of 7.7. The optimum temperature for growth is 50°C. The pH growth optimum of each of the Eubacterium isolates is around pH 7.0 while temperature optima are 37° 45° and 50°C for LFI, LF4 and LF5 respectively. Most isolates had growth optima in the thermophilic range. The ease with which apparently previously unidentified species could be isolated is a reflection of the unique and highly variable, heterogeneous environment within landfill waste.     

Phosphatases ofAcinetobacter lwoffi. Localization and regulation of synthesis by orthophosphate

Several phosphomonoesterases and diesterases with various pH optima have been observed inAcinetobacter lwofi JW11. The osmotic shock fluids contained only those with an alkaline pH optimum. The synthesis of these phosphatases was regulated by external Pi concentrations. The shock fluids were fractionated by chromatography, yielding three fractions, two of which had hydrophobic properties. One of these contained an alkaline phosphatase that specifically required Ca²⁺ for activity. The diesterases required various divalent cations for their function. Mutants that lack phosphomonoesterase or both phosphomonoesterase and phosphodiesterase activities were isolated.     

Cellulase and cell differentiation in Acer pseudoplatanus

Summary Homogenates of differentiating xylem and phloem tissue have higher cellulase activities than cambial samples; the highest activity is always found in phloem. Callus tissue, in which no vascular differentiation occurs, contains only low cellulase activity. The results suggest that cellulase is involved in vascular differentiation. Different pH optima of cellulase activity were found: in cambium, xylem and phloem tissue, cellulase activity with an optimum at about pH 5.9 is predominantly membrane-bound; it is sedimentable at 100,000 g and releasable by Triton X-100. The same may be true of activity with an optimum at pH 5.3. Phloem tissue also contains a soluble, cytoplasmic cellulase of high activity at pH 7.1, and xylem tissue contains cytoplasmic cellulase with an optimum at pH 6.5. Low cellulase activity with a pH optimum similar to that of xylem homogenates was found in xylem sap. Cellulase activity in abscission zones increases greatly just before leaf abscission. Abscission zone cellulase has two pH optima, et 5.3 and 5.9; both activities are increased by Triton treatment of homogenates. The possible existence of several different cellulases forming part of a cellulase complex, and the rôle of the enzymes in hydrolysing wall material during cell differentiation are discussed.     

The major excreted protein of transformed fibroblasts is an activable acid-protease

Malignant transformation of mouse cells by a variety of agents or treatment with the tumor promoter 12-O-tetradecanoylphorbol 13-acetate or platelet-derived growth factor results in increased synthesis and secretion of a 39,000-dalton protein termed major excreted protein (MEP). We report here that secreted MEP is an acid-activable protease. The secreted precursor form of the protease is auto-activated at low pH and is able to digest a variety of proteins, including the extracellular matrix proteins fibronectin, collagen, and laminin. MEP protease activity has pH optimum of 3.3-3.6 and is temperature- and concentration-dependent. The activity is inhibited by sulfhydryl protease inhibitors such as leupeptin and iodoacetic acid and not by metallo-, seryl-, or carboxyprotease inhibitors. The MEP-derived protease has characteristics distinct from the cathepsins previously reported and thus may be a new acid-protease of mouse cells.     

Plasmid specifying total degradation of 3-chlorobenzoate by a modified ortho pathway.

We purified lipoamide dehydrogenase from cells of Pseudomonas putida PpG2 grown on glucose (LPD-glu) and lipoamide dehydrogenase from cells grown on valine (LPD-val), which contained branched-chain keto acid dehydrogenase. LPD-glu had a molecular weight of 56,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and LPD-val had a molecular weight of 49,000. The pH optimum for LPD-glu for reduced nicotinamide adenine dinucleotide oxidation was 7.4, compared with pH 6.5 for LPD-val. When oxidized nicotinamide adenine dinucleotide was included in the assay mixture, the pH optima were 7.1 and 5.7, respectively. There was also a difference in pH optima between the two enzymes for oxidized nicotinamide adenine dinucleotide reduction, but the Michaelis constants and maximum velocities were similar. A purified preparation of branched-chain keto acid dehydrogenase, which was deficient in lipoamide dehydrogenase, was stimulated 10-fold by LPD-val but not by LPD-glu, which suggested that the branched-chain keto acid dehydrogenase of P. putida has a specific requirement for LPD-val. In contrast, a partially purified preparation of 2-ketoglutarate dehydrogenase that was deficient in lipoamide dehydrogenase was stimulated by LPD-glu but not by LPD-val, indicating that this complex has a specific requirement of LPD-glu.     

Antifungal properties of haem peroxidase from Acorus calamus

BACKGROUND AND AIMS: Plants have evolved a number of inducible defence mechanisms against pathogen attack, including synthesis of pathogenesis-related proteins. The aim of the study was to purify and characterize antifungal protein from leaves of Acorus calamus. METHODS: Leaf proteins from A. calamus were fractionated by cation exchange chromatography and gel filtration and the fraction inhibiting the hyphal extension of phytopathogens was characterized. The temperature stability and pH optima of the protein were determined and its presence was localized in the leaf tissues. KEY RESULTS: The purified protein was identified as a class III haem peroxidase with a molecular weight of approx. 32 kDa and pI of 7.93. The temperature stability of the enzyme was observed from 5 degrees C to 60 degrees C with a temperature optimum of 36 degrees C. Maximum enzyme activity was registered at pH 5.5. The pH and temperature optima were corroborated with the antifungal activity of the enzyme. The enzyme was localized in the leaf epidermal cells and lumen tissues of xylem, characteristic of class III peroxidases. The toxic nature of the enzyme which inhibited hyphal growth was demonstrated against phytopathogens such as Macrophomina phaseolina, Fusarium moniliforme and Trichosporium vesiculosum. Microscopic observations revealed distortion in the hyphal structure with stunted growth, increased volume and extensive hyphal branching. CONCLUSIONS: This study indicates that peroxidases may have a role to play in host defence by inhibiting the hyphal extension of invading pathogens.     

Invertases of pollen of Haemanthus albiflos

Soluble and insoluble invertase occurs in dormant pollen of Haemanthus albiflos, with pH optima of 5·7 and 5·5 respectively. At their pH optima the activity of the soluble enzyme is 3·5-fold higher. After 2 hr germination the pH optimum of the insoluble invertase is increased to 6·0 and the activity is increased 2-fold while the activity of the soluble invertase is decreased by 26%.     

Variation in pH Optima of Hydrolytic Enzyme Activities in Tropical Rain Forest Soils

Extracellular enzymes synthesized by soil microbes play a central role in the biogeochemical cycling of nutrients in the environment. The pH optima of eight hydrolytic enzymes involved in the cycles of carbon, nitrogen, phosphorus, and sulfur, were assessed in a series of tropical forest soils of contrasting pH values from the Republic of Panama. Assays were conducted using 4-methylumbelliferone-linked fluorogenic substrates in modified universal buffer. Optimum pH values differed markedly among enzymes and soils. Enzymes were grouped into three classes based on their pH optima: (i) enzymes with acidic pH optima that were consistent among soils (cellobiohydrolase, β-xylanase, and arylsulfatase), (ii) enzymes with acidic pH optima that varied systematically with soil pH, with the most acidic pH optima in the most acidic soils (α-glucosidase, β-glucosidase, and N-acetyl-β-glucosaminidase), and (iii) enzymes with an optimum pH in either the acid range or the alkaline range depending on soil pH (phosphomonoesterase and phosphodiesterase). The optimum pH values of phosphomonoesterase were consistent among soils, being 4 to 5 for acid phosphomonoesterase and 10 to 11 for alkaline phosphomonoesterase. In contrast, the optimum pH for phosphodiesterase activity varied systematically with soil pH, with the most acidic pH optima (3.0) in the most acidic soils and the most alkaline pH optima (pH 10) in near-neutral soils. Arylsulfatase activity had a very acidic optimum pH in all soils (pH ≤3.0) irrespective of soil pH. The differences in pH optima may be linked to the origins of the enzymes and/or the degree of stabilization on solid surfaces. The results have important implications for the interpretation of hydrolytic enzyme assays using fluorogenic substrates.Measurements of the activities of extracellular enzymes involved in the turnover of nutrients from organic compounds provide important information on biogeochemical cycles in tropical soils (13, 59, 63). In particular, they are the primary mechanism by which microbes decompose organic matter and can provide key information on the nutrient status of the ecosystem (45, 60). For example, changes in the activities of phosphatase and N-acetyl-β-glucosaminidase in soil chronosequences reflect long-term changes in nitrogen and phosphorus availability during pedogenesis in both tropical and temperate rain forests (3, 34).The pH of the soil solution exerts a strong control on enzyme activity, because it influences the conformation of the enzyme, its adsorption on solid surfaces, and the ionization and solubility of substrates and cofactors (38, 51). Although some studies have determined enzyme activity at the soil pH (e.g., references 19 and 63), assays are usually conducted at the optimum pH for the enzyme, which yields a measure of its maximum potential activity at a given temperature (7, 27). For example, the assay of acid phosphomonoesterase activity using the chromogenic substrate para-nitrophenyl phosphate is typically performed at pH 6.5 (51), based on the determination of the pH optima of this enzyme in a series of temperate agricultural soils (15, 21, 50).Once the optimum pH for a given enzyme has been determined, it is usually assumed that this will apply broadly to other soils, allowing the recommendation of a single buffer pH in standardized procedures (44, 51). However, the pH optima of some enzymes can vary markedly among soils. For example, Niemi and Vepsäläinen (33) reported soil-specific pH optima for three hydrolytic enzymes (acid phosphomonoesterase, phosphodiesterase, and N-acetyl-β-glucosaminidase) in six soils under contrasting land uses in Finland. Such soil-specific pH optima led Malcolm (27) to recommend, in a critique of soil enzyme assays, that the pH optimum of the enzyme under study should be determined for each soil.Differences among soils in relation to the pH optima of an individual enzyme might be due to a variety of factors, including the composition of the soil microbial community (i.e., if isoenzymes originating from different organisms have different pH optima) and the location of the enzyme in the soil matrix (e.g., intracellular, free in solution, or adsorbed on solid surfaces, etc.) (4). For example, the sorption of an enzyme on a clay surface can increase its optimum pH by one or two pH units relative to that of the same enzyme in solution (31, 40). This is due to “unfolding” of enzymes on solid surfaces, which is most likely to occur at soil pH values below the isoelectric point of the enzyme (26, 38).Information on the optimum pH of enzyme activity is of particular importance for studies that use fluorogenic substrates in multiwell plates to assay several enzymes simultaneously. Such studies are usually simplified by assaying all enzymes in a single buffer, such as acetate at pH 5.5 (57) or 2-(N-morpholino)ethanesulfonic acid (MES) at pH 6.1 (30). However, this may not coincide with the pH optima of all the enzymes involved, especially if the optimum pH for a given enzyme varies among soils. Further, most studies of the pH optima of hydrolytic enzymes have been conducted using chromogenic substrates linked to para-nitrophenol, and it is not clear whether the values correspond to the pH optima for fluorogenic substrates linked to 4-methylumbelliferone.Here I report the pH optima for eight hydrolytic enzymes involved in the cycles of carbon, nitrogen, phosphorus, and sulfur in a series of soils under a lowland tropical rain forest in the Republic of Panama. The aim was to determine the extent to which the pH optima of activity varied among enzymes and soils, in order to develop a method suitable for the measurement of enzyme activities in a broad range of tropical rain forest soils.     

Yeast mitochondria (Saccharomyces cerevisiae) contain Ca(2+)-independent phospholipase A1 and A2 activities: effect of respiratory state

We demonstrate that both phospholipase A1 and phospholipase A2 are associated with isolated yeast mitochondria (Saccharomyces cerevisiae). Activity assays indicate that, unlike most other mitochondrial phospholipases A, the yeast enzymes are Ca(2+)-independent with acidic (pH 4-5) as well as alkaline (pH 8-9) pH optima. Data obtained with mitochondria isolated from either fermenting or respiring cells, and initial observations with a petite strain, strongly suggest that a phospholipase A2 with an acidic pH optimum functions in the in vivo adaptation and maintenance of mitochondrial membranes required for respiration.     

Reduction in cell entry of Eimeria tenella (Coccidia) sporozoites by protease inhibitors, and partial characterization of proteolytic activity associated with intact sporozoites and merozoites

The role of proteases in the invasion of host cells by Eimeria tenella (Wisconsin strain) was studied in vitro. Protease inhibitors were used to treat sporozoites before inoculation or were applied to cultured chicken kidney cells before infection. The inhibitors antipain, leupeptin, aprotinin, L-1-tosylamide-2-phenyl-ethyl chloromethyl ketone (TPCK), or N-alpha-p-tosyl-L-lysine chloromethyl ketone (TLCK) reduced parasite invasion to 16-66% of control after treatment of cultured cells or sporozoites with 5- or 50-micrograms/ml concentrations of inhibitors in the culture medium. Phenylmethylsulfonyl fluoride (PMSF) reduced invasion to 32-57.7% at concentrations of 1-4 mM. The optimum pH for hydrolysis of azocasein by intact sporozoites or merozoites was determined over a range of pH 5.0 to pH 9.0. Sporozoites were highly active over a broad range from pH 5.5 to pH 9.0, with an apparent optimum at pH 8.0. Merozoites had a much lower specific activity with pH optima at 7.0 and 8.5. The protease activity of sporozoites or merozoites could be inhibited completely by the addition of 50 micrograms/ml of leupeptin, TPCK, or TLCK or of 4 mM PMSF. Antipain inhibited proteases of sporozoites but not of merozoites. Pepstatin had little effect on either sporozoites or merozoites. The results suggest that parasite proteases of Eimeria may be necessary for invasion of host cells.     

Activation and stabilization of diaphragm-associated acetylcholinesterase by monovalent (Na+, Li+) cations

Acetylcholinesterase (AChE) activity was determined at varied pH values between 6 and 11 in rat homogenated diaphragm and in eel E. electricus soluble AChE, in the presence or absence of 115 mM NaCl or LiCl. It was observed that by using homogenated diaphragm Li+ stimulated AChE at physiological pH (7-7.4). In control (no cations) a pH "optimum" of 8.6-9 was found, while in presence of NaCl or LiCl "optima" of 9.5 and 10.2 were observed respectively. At optimum pH, AChE activity was about 2 times higher with NaCl, while with LiCl 5 times higher than the control. Preincubation of the enzyme or the homogenate in cations presence at pH 5.5 or pH 12.8 had no effect on the activity, when it was measured at pH "optima". However, without cations only 76% of the activity in optimum pH after preincubation at pH 5.5 was found. These results suggest that: (a) Li+ may neutralize negative charges of AChE more successfully than Na+, resulting in better enzyme activation and stabilization; (b) a possible enzyme desensitization induced by pH changes can be avoided by increasing Na+ concentrations and especially Li+.     

Invertase and maltase in the free space of the maize scutellum

When maize scutellum slices were incubated in solutions of sucrose or maltose, there was a release of glucose into the bathing solution. The pH optima for glucose release were 2.5 for sucrose and 3.5 for maltose. From measurement of rates of glucose uptake into slices in the presence or absence of sucrose, it is calculated that glucose uptake will introduce errors of 3–9%, depending on the sucrose concentration, in estimates of free-space sucrose-hydrolase activity at pH 2.5. At their respective pH optima, maltose was hydrolysed at a rate 2.5 times that of sucrose. When frozen-thawed slices were used the same pH optima were obtained, but rates of hydrolysis were increased. Raffinose and melezitose also were hydrolysed with pH optima of 2.5 and 3.5, respectively. α-Methyl glucose was not hydrolysed. A 60-min HCl treatment (pH 2) of scutellum slices destroyed 69% of the sucrose-hydrolase activity and 100% of the maltose-hydrolase activity. In contrast, sucrose uptake and sucrose synthesis from exogenous fructose were not affected by HCl treatment. It is concluded that there are two hydrolases, acid invertase and maltase; that they are either on or outside the plasmalemma (in the free space); and that they are not necessary to the disaccharide uptake processes either by supplying exogenous hexose or by acting as transporters.     

Regulation,purification and partial characterization of glutamine synthetase fromStreptomyces aureofaciens

The activity of glutamine synthetase (GS) fromStreptomyces aureofaciens was regulated by the availability of the nitrogen source. Rich nitrogen sources repressed GS synthesis and increased GS adenylylation. The enzyme was purified 270-fold to virtual homogeneity with 37% recovery. The molar mass of the native enzyme and its subunits was determined to be 620 and 55 kDa, respectively, indicating that GS is composed of 12 identical subunits. The enzyme has a hexagonal-bilayered structure as observed by electron microscopy. The isoelectric point of the purified GS was at pH 4.2. The enzyme was stable for 1 h at 50°C but lost activity rapidly when incubated at 65 and 70°C. Mg²⁺ supported relative synthetic activity of 100 and 72%, respectively, with the corresponding pH optima of 7.3 and 7.0. Mn²⁺ ions activated transferase activity at a pH optimum of 7.0. The temperature optimum for all GS activities was 50°C. Intermediates of the citric acid cycle exerted insignificant effects on the synthetic activities. There was no SH-group essential for the GS activity.