Stimulation of intralysosomal proteolysis by cysteinyl-glycine,a product of the action of γ-glutamyl transpeptidase on glutathione

The mechanism of the stimulatory effect of glutathione on proteolysis in mouse kidney lysosomes and a lack of an effect in lysomes from the liver was investigated. The stimulation in kidney lysosomes was inhibited by serine plus borate, a reversible inhibitor of γ-glutamyl transpeptidase. Treatment of mouse kidney lysosome suspensions with $\text{l}\text{-(αS,5S)-α-}\text{amino}\text{-3-}\text{chloro}\text{-4,5-}\text{dihydro}\text{-5-}\text{isoxazoleacetic}$ acid (acivicin), an irreversible inhibitor of the transpeptidase, also inhibited the effect of glutathione, but this inhibition was completely relieved by washing and addition of freshly prepated kidney membranes or purified γ-glutamyl transpeptidase to the incubation mixtures. Cysteinyl-glycine, a product of the action of γ-glutamyl transpeptidase, stimulated proteolysis in acivicin-inhibited kidney lysosome preparations similarly to glutathione, and cysteine had no effect at equivalent concentrations. Glutathione also stimulated proteolysis in liver lysosomes in the presence of washed kidney membranes or γ-glutamyl transpeptidase, but the effect was similar to that produced by equivalent concentrations of cysteine. These results suggest that the stimulatory effect of glutathione was mediated by the action of γ-glutamyl transpeptidase present in contaminating cell membrane fragments in the lysosome preparations, and that glutathione does not take part in intralysosomal proteolysis. However, the possibility that cysteinyl-glycine is a physiological intralysosomal disulfide reductant in kidney lysosomes has not been excluded.     

IN VIVO INHIBITION OF γ-GLUTAMYLCYSTEINE SYNTHETASE BY l-METHIONINE-RS-SULFOXIMINE; INFLUENCE ON INTERMEDIATES OF THE γ-GLUTAMYL CYCLE

—The inhibition of γ-glutamylcysteine synthetase and its influence on the concentration of intermediates associated with the metabolism of glutathione was studied in mice receiving methionine sulfoximine, a convulsant agent. The activity of the enzyme decreased significantly in the liver and kidney 1-4 h after administration of methionine sulfoximine; the activity of the enzyme in the brain was unchanged after 1 and 2 h but decreased significantly after 4 h. There was a rapid and sharp decrease in the concentration of glutathione in the kidney and a slower decrease in the liver. Brain glutathione concentrations were unaffected. Methionine sulfoximine in vivo, inhibited the synthesis of l -γ-glutamyl-l -α-aminobutyrate after administration of l -α-aminobutyrate, a reaction catalyzed by γ-glutamylcysteine synthetase. The inhibitor also lowered the concentration of pyrrolidone carboxylate in mouse tissues and prevented the accumulation of this intermediate after administration of l -α-aminobutyrate. The results show that methionine sulfoximine in vivo affects the metabolism of glutathione and that this action may contribute to its convulsive properties.     

Role of hippurate in acidosis induced adaptation in renal gamma-glutamyltransferase

Metabolic acidosis results in an adaptation in renal γ-glutamyltransferase (γ-GT) and a doubling of hippurate excretion. The greater rate of γ-glutamohydroxamate, γ-GHA, formation from L-glutamine, but not from glutathione, by acidotic kidney homogenates suggest an increased γ-glutamyl-enzyme complex formation and a preference for glutamine as the γ-glutamyl donor in acidosis. Hippurate added $\text{in}$$\text{vitro}$ to cortical homogenates or microsomes mimics the affect of acidosis upon γ-GHA formation from glutamine. Acid extracts of urine stimulated ammonia formation from glutamine using cortical microsomes in agreement with the measured hippurate levels. Administering an exogenous hippurate load to fasting nonacidotic rats doubled ammonia excretion and the rate of γ-GHA formation by cortical homogenates. These results are consistent with the acidosis induced adaptation in renal γ-GT governed by hippurate.     

gamma-Glutamyl transpeptidase in Hydra littoralis.

$\text{Hydra}$$\text{littoralis}$ exhibits high γ-glutamyl transpeptidase activity, i.e., about 12% of the activity (determined with glutathione) of rat kidney. Histochemical studies show that the enzyme is located mainly in the gastric and sub-hypostome regions; the enzyme is also present in the tentacles and basal disc. These results and the presence of other enzymes of the γ-glutamyl cycle suggest that the cycle plays a role in the metabolism of glutathione in hydras and that γ-glutamyl transpeptidase may function in their digestive and absorptive processes and possibly also in the behavioral response to glutathione.     

S-Adenosylmethionine synthetase isozyme patterns from rat hepatoma induced by N-2-fluorenylacetamide

Isozyme patterns of $\text{S}$-adenosylmethionine synthetase have been measured with and without dimethylsulfoxide in hepatoma of rats induced by $\text{N}$-2-fluorenylacetamide. The isozymes of α- and β-types existing in normal rat liver gradually decreased with the progress of hepatocarcinoma, and the kidney type γ-enzyme appears along with disappearance of both α- and β-enzymes. The liver from rat fetus contains a greater part of γ-type enzyme.     

Alterations in the metabolomics of sulfur-containing substances in rat kidney by betaine

Earlier studies have shown that betaine administration may modulate the metabolism of sulfur amino acids in the liver. In this study, we determined the changes in the metabolomics of sulfur-containing substances induced by betaine in the kidney, the other major organ actively involved in the transsulfuration reactions. Male rats received betaine (1 %) in drinking water for 2 weeks before killing. Betaine intake did not affect betaine–homocysteine methyltransferase activity or its protein expression in the renal tissue. Expression of methionine synthase was also unchanged. However, methionine levels were increased significantly both in plasma and kidney. Renal methionine adenosyltransferase activity and S-adenosylmethionine concentrations were increased, but there were no changes in S-adenosylhomocysteine, homocysteine, cysteine levels or cystathionine β-synthase expression. γ-Glutamylcysteine synthetase expression or glutathione levels were not altered, but cysteine dioxygenase and taurine levels were decreased significantly. In contrast, betaine administration induced cysteine sulfinate decarboxylase and its metabolic product, hypotaurine. These results indicate that the metabolomics of sulfur-containing substances in the kidney is altered extensively by betaine, although the renal capacity for methionine synthesis is unresponsive to this substance unlike that of the liver. It is suggested that the increased methionine availability due to an enhancement of its uptake from plasma may account for the alterations in the metabolomics of sulfur-containing substances in the kidney. Further studies need to be conducted to clarify the physiological/pharmacological significance of these findings.     

Carnitine synthesis in rat tissue slices

The ability of rat liver, kidney, muscle, heart and testis tissue to carry out the $\text{in vitro}$ synthesis of carnitine via ε-N-trimethyllysine and γ-butyrobetaine was studied. All tissues formed γ-butyrobetaine from trimethyllysine, but liver and testis also formed carnitine in about 7% and 1% yield respectively. Liver slices formed trimethyllysine from lysine in about 6% yield. These $\text{in vitro}$ studies thus establish that liver has all the enzymes of the carnitine biosynthetic pathway. This tissue appears to be the primary site of carnitine synthesis in the rat as implied from whole animal studies in this and other laboratories.     

Effect of methylglyoxal bis (guanylhydrazone) (MGBG) in vivo on the decarboxylation of s-adenosylmethionine and synthesis of spermidine in the rat and guinea pig.

The rates of decarboxylation of $\text{S}$-adenosylmethionine and synthesis of spermidine have been measured in extracts of liver, kidney and brain of the rat and guinea pig after intraperitoneal injection of MGBG, both before and after dialysis. The rate of decarboxylation of $\text{S}$-adenosylmethionine paralleled that of spermidine synthesis in all of the tissues investigated, even when spermidine synthesis was measured using preformed decarboxylated $\text{S}$-adenosylmethionine as substrate instead of $\text{S}$-adenosylmethionine itself. MGBG inhibited CO₂ production and spermidine synthesis to a similar extent in extracts of liver and kidney of both the rat and the guinea pig. After dialysis, a similar increase in both CO₂ production and spermidine synthesis was noted in these extracts. No effects on CO₂ production or spermidine synthesis were noted on extracts of brain of the rat or guinea pig, either before or after dialysis. When MGBG was injected intracisternally, CO₂ production and spermidine synthesis by extracts of brain were inhibited to the same extent, and after dialysis a similar increase in CO₂ production and spermidine synthesis was observed. These results indicate that the effects of MGBG are essentially the same in brain as they are in liver and kidney, and the MGBG injected intraperitoneally does not pass into the brain.     

Increased acridine orange uptake and lysosomal enzyme levels in rat liver after steroid administration

A steroid which stabilizes lysosomes $\text{in vitro}$ and a pyrogenic steroid which labilizes lysosomes $\text{in vitro}$ were compared with respect to their ability to modify lysosomal uptake and lysosomal enzyme levels $\text{in vivo}$. Cortisone acetate increased the uptake of acridine orange by rat liver lysosomes when the dye was administered by intrathoracic injection. The steroid increased and accelerated the uptake of acridine orange so that, in liver lysosomes from treated rats, the maximum uptake was double that of controls and was reached at 2h, whereas in controls the maximum uptake was at 4h after the injection of the dye. This large elevation of uptake is specific to the lysosomal fraction and is not seen in other subcellular fractions of rat liver. The specific activities of a lysosomal enzyme β-N-acetylglucosaminidase were increased in lysosomal fractions from cortisone acetate-treated rats. Etiocholanolone, a steroid which labilizes lysosome $\text{in vitro}$, similarly accelerated and increased acridine orange uptake by lysosomes but had little effect on lysosomal β-N-acetylglucosaminidase levels. Thus the ability of steroids to stabilize or labilize lysosomes $\text{in vitro}$ does not correlate with their effect on lysosomal uptake of injected substances $\text{in vivo}$, or with their ability to induce increased specific activities of lysosomal enzymes.     

Inhibition of protein kinase activity and amino acid and α-methyl-d-glucoside transport by diamide

Dizene dicarboxylic acid $\text{bis}\text{-(N,N-}\text{dimethylamide}\text{)}$, commonly called diamide, is known to oxidize stoichiometrically intracellular pools of reduced glutathione and inhibit the accumulation of sugars and amino acids by rat kidney slices. Incubation of rat renal cortical slices in diamide also leads to a significant decrease in the level of endogenous protein kinase activity. The inhibition of sugar and amino acid transport and protein kinase activity by diamide is partially reversible by the addition of exogenous glutathione or other thiols. A comparison of protein kinase activity with amino acid and sugar transport at various concentrations of diamide indicates that there is a high degree of correlation between these two processes.     

Properties of carnitine transport in rat kidney cortex slices

The properties of carnitine transport were studied in rat kidney cortex slices. Tissue: medium concentration gradients of 7.9 for L-[methyl-¹⁴C]carnitine were attained after 60-min incubation at 37°C in 40 μM substrate. L- and D-carnitine uptake showed saturability. The concentration curves appeared to consist of (1) a high-affinity component, and (2) a lower affinity site. When corrected for the latter components, the estimated K_m for L-carnitine was 90 μM and $\text{V = 22}\text{nmol/min}$ per ml intracellular fluid; for D-carnitine, $\text{K}{}_{\mathrm{<mtext>m</mtext>}}\text{= 166}\text{μM}$ and $\text{V = 15}\text{nmol/min}$ per ml intracellular fluid. The system was stereospecific for L-carnitine. The uptake of L-carnitine was inhibited by (1) D-carnitine, γ-butyrobetaine, and (2) acetyl-L-carnitine. γ-Butyrobetaine and acetyl-L-carnitine were competitive inhibitors of L-carnitine uptake. Carnitine transport was not significantly reduced by choline, betaine, lysine or γ-aminobutyric acid. Carnitine uptake was inhibited by 2,4-dinitrophenol, carbonyl cyanide $\text{m-}\text{chlorophenylhydrazone}$, N₂ atmosphere, KCN, $\text{N-}\text{ethylmaleimide}$, low temperature (4°C) and ouabain. Complete replacement of Na⁺ in the medium by Li⁺ reduced L- and D-carnitine uptake by 75 and 60%, respectively. Complete replacement of K⁺ or Ca²⁺ in the medium also significantly reduces carnitine uptake. Two roles for the carnitine transport system in kidney are proposed: (1) a renal tubule reabsorption system for the steady-state maintenance of plasma carnitine; and (2) maintenance of normal carnitine levels in kidney cells, which is required for fatty acid oxidation.     

Nitrogen fixation in cultured cowpea Rhizobia: inhibition and regulation of nitrogenase activity.

Nitrogenase activity in agar cultures of cowpea rhizobia, strain 32H1, was rapidly inhibited by $\text{NH}{}_4{}^{\mathrm{+}}$ but this was relieved by increased O₂ tension. Inhibition was more rapid than that caused by inhibitors of protein synthesis and was not relieved by methionine sulfoximine or methionine sulfone. Under conditions were nitrogenase activity was inhibited by $\text{NH}{}_4{}^{\mathrm{+}}$, glutamine synthetase and glutamate synthase were substantially unaffected. Glutamate dehydrogenase was undetected in either nitrogenase active or $\text{NH}{}_4{}^{\mathrm{+}}$ inhibited cultures. These results indicate that $\text{NH}{}_4{}^{\mathrm{+}}$ inhibition of nitrogenase activity in strain 32H1 is not effected through glutamine synthetase regulation of nitrogenase synthesis.     

Partial purification and characterization of citrate synthase from Dictyostelium discoideum.

The effect of thyroidectomy on oxidative metabolism of rat liver, kidney, and brain mitochondria has been examined. The respiration in liver, kidney, and brain mitochondria was affected differentially after thyroidectomy, the common effect in all the tissues being the impairment in state 3 as well as state 4 rates of succinate oxidation. Thyroidectomy did not have any effect on $\text{ADP}\text{O}$ ratios; however, compared to normal, respiratory control indexes were, in general, somewhat higher. Thyroidectomy also did not alter total ATPase activity of liver, kidney, and brain mitochondria, although the basal ATPase activity had decreased significantly under these conditions. The cytochrome content of the mitochondria also showed tissue-specific changes after thyroidectomy; however, no significant changes in the absorption characteristics of the cytochromes were seen. The succinate and glutamate dehydrogenase activities of mitochondria from liver, kidney, and brain were not affected by thyroidectomy, thereby ruling out the possibility that the decrease in substrate oxidation may be due to alterations in the primary dehydrogenase levels. It is concluded that thyroid hormone(s) may have a tissue-specific role in regulating the metabolic functions of mitochondria.     

Expression of ligandin and glutathione S-transferase activities by cells in tissue culture.

A wide distribution of glutathione S-transferase activity towards 1-chloro-2,4-dinitrobenzene and 1,2-dichloro-4-dinitrobenzene has been detected in a range of non-transformed, transformed and hybrid cell lines. The levels of transferase activity are lower in these $\text{in vitro}$ cell lines than are corresponding $\text{in vivo}$ levels. A majority of the cell lines tested contain proteins that are antigenically related to rat liver glutathione S-transferase B (ligandin).     

The uptake of labelled sulphur by the proteins of human liver slices incubated with L-(35S)-methionine or (35S)-sulphate

Transfer of labelled sulphur from methionine into protein-bound cysteine was observed in human foetal liver $\text{in}$$\text{vitro}$. Inorganic sulphate could not be utilized as sulphur donor for cystein synthesis in human foetal liver.     

Glutathione peroxidase activity of glutathione-S-transferases purified from rat liver

Gel filtration chromatography demonstrated the presence of two peaks of glutathione peroxidase activity assayed with cumene hydroperoxide in the soluble fraction of rat liver, brain, kidney, and testis. The peak with an approximate molecular weight of 45,000 (GSH-Px II) was purified from rat liver labeled $\text{in vivo}$ with Na₂⁷⁵SeO₃. Chromatography on DEAE-cellulose, Sephadex G-150, DEAE-cellulose, and CM-cellulose resulted in the co-purification of glutathione-S-transferase activity measured with 1-chloro-2,4-dinitrobenzene and glutathione peroxidase activity assayed with cumene hydroperoxide, and in the removal of all detectable ⁷⁵Se. Studies on GSH-Px II indicated that the apparent K_m for both cumene and t-butyl hydroperoxides was considerably higher than that for purified seleno-glutathione peroxidase. The V_max estimated with cumene hydroperoxide was only $\text{1}\text{300}$ of that determined for the selenoenzyme at pH 7.5 and with 1 mM GSH.     

Grafting of different glycosides on the surface of liposomes and its effect on the tissue distribution of 125I-labelled γ-globulin encapsulated in liposomes

Different glycosides were grafted on the surface of liposomes containing ¹²⁵I-labelled γ-globulin by two ways: (1) by using glycolipid and (2) by covalent coupling of $\text{p-}\text{aminophenyl-}\text{d}\text{-glycosides}$ to phosphatidylethanolamine liposomes using glutaraldehyde. The distribution of ¹²⁵I-labelled γ-globulin was determined in mouse tissues from 5–60 min after a single injection of these liposomes. The liver uptake of encapsulated ¹²⁵I-labelled γ-globulin was highest from liposomes having galactose and mannose on the surface. Competition experiments and cross-inhibition studies indicate that this uptake are mediated by specific recognition of the surface galactose and mannose residues of liposomes by the receptors present on the plasma membrane of liver cells. Stearylamine-containing liposomes were found to be more efficient in mediating the uptake of ¹²⁵I-labelled γ-globulin by the lung, whereas in the case of spleen, phosphatidylethanolamine liposomes were more efficient. The extent of uptake of ¹²⁵I-labelled γ-globulin from all types of liposome decreases as the amount of given liposomes increases. The uptake of ¹²⁵I-labelled γ-globulin from liposomes containing asialogangliosides depends upon the phospholipid/ glycolipid ratio. These experiments clearly demonstrate that enhanced liposome uptake by liver cells could be achieved by grafting galactose and mannose on the liposomal surface.     

The location of glutamine synthetase within the rat and rabbit nephron.

Glutamine synthetase (EC 6.3.1.2) was measured in seven different parts of the nephron in the rat and five in the rabbit, dissected from freeze-dried microtome slices. In the rat the enzyme is essentially confined to the proximal straight tubule. Acidosis did not change the activity; methionine sulfoximine abolished it. In the rabbit the enzyme is high in both proximal convoluted and straight tubules. Assays were made with a new method which measures glutamine formation $\text{per se}$. One of the products, NADH, is amplified by enzymatic cycling to provide sufficient sensitivity (2–10 pmol of glutamine).     

Appearance of a kidney-specific ribosomal protein during mouse embryonic development

Ribosomes were prepared from adult mouse liver and kidney and the protein components examined by SDS polyacrylamide gel electrophoresis. A kidney specific protein was identified and was found to be associated with the large ribosomal subunit. $\text{In}$$\text{vitro}$ labelling of 11- and 14-day embryonic kidneys and subsequent analysis of the ribosomal proteins indicated a change in the ribosomal population during development. The kidney specific protein was synthesized during the first four days of kidney organogenesis.