Studies on guanine deaminase and its inhibitors in rat tissue

1. In kidney, but not in rat whole brain and liver, guanine-deaminase activity was localized almost exclusively in the 15000g supernatant fraction of iso-osmotic sucrose homogenates. However, as in brain and liver, the enzymic activity recovered in the supernatant was higher than that in the whole homogenate. The particulate fractions of kidney, especially the heavy mitochondria, brought about powerful inhibition of the supernatant guanine-deaminase activity. 2. In spleen, as in kidney, guanine-deaminase activity was localized in the 15000g supernatant fraction of iso-osmotic sucrose homogenates. However, the particulate fractions did not inhibit the activity of the supernatant. 3. Guanine-deaminase activity in rat brain was absent from the cerebellum and present only in the cerebral hemispheres. The inhibitor of guanine deaminase was located exclusively in the cerebellum, where it was associated with the particles sedimenting at 5000g from sucrose homogenates. 4. Homogenates of cerebral hemispheres, the separated cortex or the remaining portion of the hemispheres had significantly higher guanine-deaminase activity than homogenates of whole brain. The enzymic activity of the subcellular particulate fractions was nearly the same. 5. Guanine deaminase was purified from the 15000g supernatant of sucrose homogenates of whole brain. The enzyme separated as two distinct fractions, A and B, on DEAE-cellulose columns. 6. The guanine-deaminase activity of the light-mitochondrial fraction of whole brain was fully exposed and solubilized by treatment with Triton X-100, and partially purified. 7. Tested in the form of crude preparations, the inhibitor from kidney did not act on the brain and liver supernatant enzymes and the inhibitor from cerebellum did not act on kidney enzyme, but the inhibitor from liver acted on both brain and kidney enzyme. 8. The inhibitor of guanine deaminase was purified from the heavy mitochondria of whole brain and liver and the 5000g residue of cerebellum, isolated from iso-osmotic homogenates. The inhibitor appeared to be protein in nature and was heat-labile. The inhibition of the enzyme was non-competitive. 9. Kinetic, immunochemical and electrophoretic studies with the preparations purified from brain revealed that the enzyme from light mitochondria was distinct from enzyme B from the supernatant. A distinction between the two forms of supernatant enzyme was less certain. 10. Guanine deaminase isolated from light mitochondria of brain did not react with 8-azaguanine or with the inhibitor isolated from heavy mitochondria.     

The metabolism of sialic acids in isolated rat colonic mucosal cells.

The activities of ten enzymes involved in sialic acid metabolism were measured in colonic mucosal cells from rats and compared with those in liver. A methodology was devised that enabled all ten enzyme activities to be evaluated in a single rat colon preparation. Enzyme assays with radioactively labelled substrates were developed for maximum sensitivity, and the identification of substrates and products was carefully checked to assess the contribution of contaminants to enzyme reactions with low activity. The activities of most enzymes involved in the biosynthesis of N-acetyl-D-neuraminic acid (NeuAc) from UDP-N-acetyl-D-glucosamine were found to be more than 20-fold lower than those in liver. The activities of CMP-NeuAc synthase, N-acetyl-D-glucosamine 2-epimerase, N-acetyl-D-glucosamine kinase, sialyltransferase and sialidase were similar to or 2-4-fold lower than in liver. The biosynthesis of NeuAc via its 9-phosphate was demonstrated in the 100 000 g supernatant of colonic-cell homogenates by enzymic assay and precursor experiments with N-acetyl[14C]-mannosamine. No alternative route for NeuAc formation could be detected. The 100 000g supernatant fractions of liver, kidney and colonic mucosal cells utilized N-acetyl[14C]mannosamine with differing efficiencies. Radioactive products identified as sialic acid biosynthetic intermediates amounted to 49%, 0.04% and 5.6% of added precursor in liver, kidney and colon respectively. Catabolism of labelled precursor to non-hexosamine products was high in kidney and colonic mucosal-cell fractions.     

Association of prolyl hydroxylase activity with membranes

Addition of ionic and nonionic detergents to whole homogenates of liver, kidney and lung prepared by a mild homogenization technique resulted in a two- to three-fold increase of prolyl hydroxylase activity. After subcellular fractionation of whole homogenates of liver, particulate and supernatant fractions were incubated in the presence and absence of triton X-100 and assayed for prolyl hydroxylase activity. All particulate fractions tested were able to release significant amounts of prolyl hydroxylase activity in the presence of triton. The release of enzyme activity by triton was observed with the 1000 × g and 17,000 × g supernatants but not with the 105,000 × g supernatant; thus indicating that detergent does not activate soluble enzyme nor make the substrate more accessible to hydroxylation by the enzyme during incubation. Rigorous homogenization of the 17,000 × g particulate fraction with the Polytron ST system resulted in a substantial loss of the amount of prolyl hydroxylase activity released by treatment with triton. These data suggest that a significant amount of prolyl hydroxylase activity is associated with membranes under physiological conditions.     

Binding of parathyroid hormone to bovine kidney-cortex plasma membranes

1. Plasma membranes were purified from bovine kidney cortex, with a fourfold increase in specific activity of parathyroid hormone-sensitive adenylate cyclase over that in the crude homogenate. The membranes were characterized by enzyme studies. 2. Parathyroid hormone was labelled with (125)I by an enzymic method and the labelled hormone shown to bind to the plasma membranes and to be specifically displaced by unlabelled hormone. Parathyroid hormone labelled by the chloramine-t procedure showed no specific binding. (75)Se-labelled human parathyroid hormone, prepared in cell culture, also bound to the membranes. 3. Parathyroid hormone was shown to retain biological activity after iodination by the enzymic method, but no detectable activity remained after chloramine-t treatment. 4. High concentration of pig insulin inhibited binding of labelled parathyroid hormone to plasma membranes and partially inhibited the hormone-sensitive adenylate cyclase activity in a crude kidney-cortex preparation. 5. EDTA enhanced and Ca(2+) inhibited binding of labelled parathyroid hormone to plasma membranes. 6. Whereas rat kidney homogenates were capable of degrading labelled parathyroid hormone to trichloroacetic acid-soluble fragments, neither crude homogenates nor purified membranes from bovine kidney showed this property. 7. Binding of parathyroid hormone is discussed in relation to metabolism and initial events in hormone action.     

Effects of detergents on Ca2+-activated neural proteinase activity (calpain) in neural and non-neural tissue: A comparative study

Calcium activated neutral proteinase (mcalpain) activity was determined in brain and other tissue of rat. More than 60% of the brain mcalpain activity was present in the particulate fraction while only 30% was in cytosol. In contrast, particulate fractions of liver, kidney, muscle, and heart contained about 8–12% of tissue mcalpain activity while 88% was present in cytosol. Removal of the endogenous inhibitor calpastatin increased the tissue mcalpain activity severalfold. Triton X-100 and deoxycholate (DOC) stimulated the neural calpain activity by ten-fold while activity in non-neural tissue was unaffected. Incubation with other detergents, e.g. Triton N-57 and thioglucopyranoside, stimulated brain calpain activity five-fold while Brij-35 did not have any effect. Sodiumdodecylsulphate (SDS), on the other hand, inhibited the enzyme activity. Brain contained the lowest calpain activity compared to non-neural tissue. The calpain activity in muscle, kidney and heart was three-fold greater than liver. Immunoblot identification of the enzyme revealed that calpain was predominantly in the particulate fraction and less in cytosol of brain while it was present mainly in cytosol and less in the pellet fractions of non-neural tissue.     

Purification and properties of a 5'-nucleotidase from rat renal membranes

5'-Nucleotidase activity was solubilized from a particulate fraction of rat renal homogenates by Sulphobetaine 14. An 11,430-fold purification was achieved by a two-step chromatographic procedure using concanavalin-A Sepharose and ADP-agarose. SDS-PAGE of the purified material revealed a single polypeptide band with a Mr of 69,000. The enyzme exhibited absolute specificity for 5'-mononucleotides. Among 7 tested substrates, adenosine monophosphate (AMP) showed the highest value of V/Km. The Km for 5'-AMP is 5.1 mumol/l and V is 632 mumol/min/mg. The plot of activity versus pH shows a broad plateau between pH 6.8 and 8.0. The hydrolysis of 5'-AMP was competitively inhibited by adenosine 5'-triphosphate (ATP; Ki = 1.2 mumol/l), adenosine 5'-diphosphate (ADP; Ki = 0.032 mumol/l) and alpha, beta-methyleneadenosine 5'-diphosphate (AOPCP; Ki = 0.005 mumol/l). All of the 5 detergents tested activated the enzyme. Sulphobetaine 14 was the most potent and resulted in a 4-fold stimulation by increasing V without change of Km. Addition of exogenous divalent cations was not required for activity. However, the enzyme was inhibited by EDTA. This inhibition was overcome by the addition of Co2+, Mn2+ and to a lesser extent of Mg2+. Hg2+, Zn2+, Cu2+ and Pb2+ inhibited in the low micromolar range. The properties of this enzyme from the rat kidney are similar to those reported in the literature for ecto 5'-nucleotidases from other sources.     

Intramolecular group transfer is a characteristic of neurotoxic esterase and is independent of the tissue source of the enzyme. A comparison of the aging behaviour of di-isopropyl phosphorofluoridate-labelled proteins in brain, spinal cord, liver, kidney and spleen from hen and in human placenta

Neurotoxic esterase activity was measured in homogenates of human placenta and hen brain, spinal cord, liver, kidney and spleen. The activity in liver comprised less than 20% of the Paraoxon-resistant esterases, but in the other tissues neurotoxic esterase accounted for over 50%. The same tissues were labelled with [3H]di-isopropyl phosphorofluoridate, and any isopropyl group transferred on to protein during 'aging' of the labelled enzymes (alkali-volatilizable tritium) was measured. No Paraoxon-sensitive labelled sites were found to age in this way in any tissue. In brain, the Paraoxon-resistant alkali-volatilizable-tritium-labelled sites correlated with the number of neurotoxic esterase labelled sites, indicating that 'aging' and isopropyl group transfer were 100% efficient. The site receiving the transferred isopropyl group was characterized by analysing the distribution of radiolabelled proteins on gel-filtration chromatography in the presence of SDS. In particulate preparations from each tissue, the protein-bound alkali-volatilizable tritium (transferred isopropyl group) was attached to a polypeptide of Mr 178 000. This same polypeptide also bore the isopropyl-phosphoryl group of neurotoxic esterase, indicating that aging of neurotoxic esterase is an intramolecular group transfer. The apparent turnover number for the enzyme (average 1.6 X 10(5) min-1) was approximately the same in each hen tissue, confirming that closely similar enzymes were present in brain, spinal cord, liver and spleen. The apparent turnover for the human enzyme was 1.8-fold higher than that for the hen enzyme. The concentration of the neurotoxic esterase phosphorylated subunit in brain, spinal cord, spleen, placenta and liver was 14.6, 3.8, 7.4, 3.3 and 3.8 pmol/g of tissue. The evidence indicated that neurotoxic esterase is present in each tissue except kidney, and that isopropyl group transfer on 'aging' occurs on this enzyme only. This process is an intramolecular transfer of the group within the same polypeptide.     

Membrane-bound neuraminidases of rat liver. Neuraminidase activity in Golgi apparatus.

The bulk (60 to 65%) of the neuraminidase activity present in rat liver homogenates was found in the M + L (mitochondria plus lysosomes) fraction, The patterns of subcellular distribution were essentially identical whether disialogangliosides or neuramin-lactose (2 yields 3') were utilized as substrates. A new neuraminidase, which hydrolyzes sialyl trisaccharides but which does not act upon glycoproteins and gangliosides, was detected in Golgi apparatus. Unlike the other particulate neuraminidases of rat liver, the Golgi enzyme is stimulated by prior incubation and by the addition of Ca2+ or Zn2+ at 1 mM concentration. Although plasma membrane-rich fractions are often contaminated by Golgi membranes the marked differences in their enzymic properties allowed a clear distinction between the neuraminidases present in these two types of membranes.     

Methylation of nuclear proteins by dimethylnitrosamine and by methionine in the rat in vivo

1. The incorporation of methyl groups into histones from dimethylnitrosamine and from methionine was studied by injection of the labelled compounds, isolation of rat liver and kidney histones, and analysis of hydrolysates by column chromatography. 2. Labelled methionine gave rise to labelled in-N-methyl-lysine, di-in-N-methyl-lysine and an amino acid presumed to be omega-N-methyl-arginine. 3. Administration of labelled dimethylnitrosamine gave rise to labelled S-methylcysteine, 1-methylhistidine, 3-methylhistidine and in-N-methyl-lysine derived from the alkylating metabolite of dimethylnitrosamine. In addition, labelled formaldehyde released by metabolism of dimethylnitrosamine leads to the formation of labelled S-adenosylmethionine, and hence to labelling of in-N-methyl-lysine, di-in-N-methyl-lysine and omega-N-methylarginine by enzymic methylation. 4. The formation of in-N-methyl-lysine by alkylation of liver histones was confirmed by using doubly labelled dimethylnitrosamine to discriminate between direct chemical alkylation and enzymic methylation via S-adenosylmethionine. These experiments also suggested the possibility that methionine residues in the histones were alkylated to give methylmethionine sulphonium residues. 5. The extent of alkylation of liver histones was maximal at about 5h after dosing and declined between 5 and 24h. The methylated amino acids resulting from direct chemical alkylation were preferentially lost: this is ascribed to necrosis of the more highly alkylated cells. 6. Liver histones were about four times as alkylated as kidney histones; the extent of alkylation of liver histones was similar to that of liver total nuclear proteins. 7. Methyl methanesulphonate (120mg/kg) alkylated liver histones to a greater extent than did dimethylnitrosamine. Diethylnitrosamine also alkylated liver histones. 8. The results are discussed with regard to the possible effects of alkylation on histone function, and the possible role of histone alkylation in carcinogenesis by the three compounds.     

Phorbol ester-stimulated phosphorylation of keratinocyte transglutaminase in the membrane anchorage region.

The membrane-bound transglutaminase of cultured keratinocytes became radioactively labelled upon addition of [32P]Pi to the medium. Transglutaminase phosphorylation was also demonstrable using particulate material isolated from cell homogenates. Compatible with mediation of the labelling by protein kinase C, the degree of phosphorylation in intact cells was stimulated approx. 5-fold in 4 h on treatment with the tumour-promoting phorbol ester phorbol 12-myristate 13-acetate, but not by phorbol. The extent of labelling was virtually unaffected by cycloheximide inhibition of protein synthesis, indicating that it arose primarily through turnover of phosphate in the membrane-bound enzyme. Phosphoamino acid analysis detected labelling only of serine residues. Most of the label was removed by trypsin release of the enzyme from the particulate fraction of cell homogenates, which deletes a membrane anchorage region of approximately 10 kDa. Upon trypsin treatment of the enzyme after immunoprecipitation, the phosphate label was recovered in soluble peptide material with a size of several thousand Da or less. Indicative of fragmentation of the membrane anchorage region, this material was separable by h.p.l.c. into two equally labelled peptides. Moreover, when the enzyme was labelled with [3H]palmitate or [3H]myristate, the fatty-acid-labelled peptide material required non-ionic detergent for solubilization and was separable from the phosphate-labelled material by gel filtration. Phorbol ester treatment of cultured keratinocytes in high- or low- Ca2(+)-containing medium was not accompanied by an appreciable protein-synthesis-independent change in transglutaminase activity. Independent of possible alteration of the intrinsic catalytic activity of the enzyme, phosphorylation may well modulate its interaction with substrate proteins, a potential site for physiological regulation.     

Radioimmunoassay for pig angiotensin I converting enzyme: a comparison of immunologic with enzymatic activity.

Angiotensin I converting enzyme in body fluids and extracts of various pig tissues was measured by radioimmunoassay and by enzymic assay. Based on the ratios of enzymic to immunologic activity, the extracts could be separated into two groups. One group, with ratios around 4 U/mg, included urine and extracts from the adrenal, choroid plexus, epididymis, gall bladder, heart, liver, retina, spleen, and testis. The other group, with ratios around 12 U/mg, contained serum and extracts from lung and kidney. Explanations are offered for why one group had a lower enzymic to immunologic ratio than the other.     

Compartmentalization of adenosine 3':5'-monophosphate and adenosine 3':5'-monophosphate-dependent protein kinase in heart tissue.

In rabbit heart homogenates about 50% of the cAMP-dependent protein kinase activity was associated with the low speed particulate fraction. In homogenates of rat or beef heart this fraction represented approximately 30% of the activity. The percentage of the enzyme in the particulate fraction was not appreciably affected either by preparing more dilute homogenates or by aging homogenates for up to 2 h before centrifugation. The particulate enzyme was not solubilized at physiological ionic strength or by the presence of exogenous proteins during homogenization. However, the holoenzyme or regulatory subunit could be solubilized either by Triton X-100, high pH, or trypsin treatment. In hearts of all species studied, the particulate-bound protein kinase was mainly or entirely the type II isozyme, suggesting isozyme compartmentalization. In rabbit hearts perfused in the absence of hormones and homogenized in the presence of 0.25 M NaCl, at least 50% of the cAMP in homogenates was associated with the particulate fraction. Omitting NaCl reduced the amount of particulate-bound cAMP. Most of the particulate-bound cAMP was probably associated with the regulatory subunit in this fraction since approximately 70% of the bound nucleotide was solubilized by addition of homogeneous catalytic subunit to the particulate fraction. The amount of cAMP in the particulate fraction (0.16 nmol/g of tissue) was approximately one-half the amount of the regulatory subunit monomer (0.31 nmol/g of tissue) in this fraction. The calculated amount of catalytic subunit in the particulate fraction was 0.18 nmol/g of tissue. Either epinephrine alone or epinephrine plus 1-methyl-3-isobutylxanthine increased the cAMP content of the particulate and supernatant fractions. The cAMP level was increased more in the supernatant fraction, possibly because the cAMP level became saturating for the regulatory subunit in the particulate fraction. The increase in cAMP was associated with translocation of a large percentage of the catalytic subunit activity from the particulate to the supernatant fraction. The distribution of the regulatory subunit of the enzyme was not significantly affected by this treatment. The catalytic subunit translocation could be mimicked by addition of cAMP to homogenates before centrifugation. The data suggest that the regulatory subunit of the protein kinase, at least that of isozyme II, is bound to particulate material, and theactive catalytic subunit is released by formation of the regulatory subunit-cAMP complex when the tissue cAMP concentration is elevated. A model for compartmentalized hormonal control is presented.     

Human N-acetylgalactosamine-4-sulphate sulphatase. Purification, monoclonal antibody production and native and subunit Mr values.

Initial purification of N-acetylgalactosamine-4-sulphate sulphatase from human liver homogenates containing approx. 1 mg of enzyme in 26 g of soluble proteins was achieved by a six-column chromatography procedure and yielded approx. 40 micrograms of a single major protein species. Enzyme thus prepared was used to produce N-acetylgalactosamine-4-sulphate sulphatase-specific monoclonal antibodies. The use of a monoclonal antibody linked to a solid support facilitated the purification of approx. 0.5 mg of N-acetylgalactosamine-4-sulphate sulphatase from a similar liver homogenate. Moreover the enzyme isolated contained a single protein species, shown by SDS/polyacrylamide-gel electrophoresis to have an Mr of 57,000, which dissociated into subunits of Mr 43,000 and 13,000 in the presence of reducing agents. Essentially identical enzyme preparations were isolated from homogenates of human kidney and lung and from concentrated human urine. The native protein Mr of enzyme from human liver and kidney was assessed by gel-permeation chromatography to be 43,000 on Ultrogel AcA and Bio-Gel P-150. The liver N-acetylgalactosamine-4-sulphate sulphatase was shown to have pH optima of approx. 4 and 5.5 with the oligosaccharide substrate (GalNAc4S-GlcA-GalitolNAc4S) and fluorogenic substrate (methylumbelliferyl sulphate) respectively. Km values of 60 microM and 4 mM and Vmax. values of 2 and 20 mumol/min per mg were determined with the oligosaccharide and fluorogenic substrates respectively.     

Regulation of CTP: phosphocholine cytidylyltransferase activity in type II pneumonocytes.

Phosphatidylcholine synthesis by rat type II pneumonocytes was altered either by depleting the cells of choline or by exposing the cells to extracellular lung surfactant. Effects of these experimental treatments on the activity of a regulatory enzyme, CTP:phosphocholine cytidylyltransferase, were investigated. Although choline depletion of type II pneumonocytes resulted in inhibition of phosphatidylcholine synthesis, cytidylyltransferase activity (measured in cell homogenates in either the absence or presence of added lipids) was greatly increased. Activation of cytidylyltransferase in choline-depleted cells was rapid and specific, and was quickly and completely reversed when choline-depleted cells were exposed to choline (but not ethanolamine). Choline-dependent changes in enzymic activity were apparently not a result of direct actions of choline on cytidylyltransferase and they were largely unaffected by cyclic AMP analogues, oleic acid, linoleic acid or cycloheximide. The Km value of cytidylyltransferase for CTP (but not phosphocholine) was lower in choline-depleted cells than in choline-repleted cells. Subcellular redistribution of cytidylyltransferase also was associated with activation of the enzyme in choline-depleted cells. When measured in the presence of added lipids, 66.5 +/- 5.0% of recovered cytidylyltransferase activity was particulate in choline-depleted cells but only 34.1 +/- 4.5% was particulate in choline-repleted cells. An increase in particulate cytidylyltransferase also occurred in type II pneumonocytes that were exposed to extracellular surfactant. This latter subcellular redistribution, however, was not accompanied by a change in cytidylyltransferase activity even though incorporation of [3H]choline into phosphatidylcholine was inhibited by approx. 50%. Subcellular redistribution of cytidylyltransferase, therefore, is associated with changes in enzymic activity under some conditions, but can also occur without a resultant alteration in enzymic activity.     

Thermometric enzyme linked immunosorbent assay: TELISA.

A new method, thermometric enzyme linked immunosorbent assay (TELISA), for the assay of endogenous and exogenous compounds in biological fluids is described. It is based on the previously described enzyme linked immunosorbent assay technique, ELISA, but utilizes enzymic heat formation which is measured in an enzyme thermistor unit. In the model system studied determination of human serum albumin down to a concentration of 10(-10) M (5 ng/ml) was achieved, with both normal and catalase labelled human serum albumin competing for the binding sites on the immunosorbent, which was rabbit antihuman serum albumin immobilized onto Sepharose CL-4B.     

THE ENZYMIC HYDROLYSIS OF PHOSPHATIDYL INOSITOL BY GUINEA PIG BRAIN:

Abstract—

• 1 Phosphatidylinositol hydrolase activity of homogenates of guinea pig brain was studied by using [2-³H]inositol labelled substrate and measuring the release of radioactivity into the acid soluble fraction.
• 2 Inositol phosphate and diglyceride were found to be the main hydrolysis products. The principal enzyme involved, therefore, is a phosphatidylinositol inositolphosphohydrolase.
• 3 Most of the enzymic activity (61 per cent) was found in the soluble fraction. Osmotic shock of the high speed particulate fraction resulted in release of an additional 23 1 per cent into the soluble fraction. However, as contrasted to lactate dehydrogenase, significant activity remained particulate bound.

     

Delta-aminolevulinic acid synthetase assay in chicken liver homogenates and particulate fractions.

Various assays for δ-aminolevulinic acid synthetase in chicken liver homogenates and particulate fractions were studied. The assay methods fall into two groups, those using exogenous succinyl-CoA generating systems and those depending on endogenous succinyl-CoA formation. In the former, the native samples showed low activity and a poor relationship between protein concentration and activity. Sonication of the samples was required to obtain higher activity and a linear relationship between protein concentration and activity. The primary factor limiting the full expression of the enzyme activity in these samples was thought to be the permeability barrier of mitochondrial membranes. In the sonicated samples the assay is limited to low protein concentrations. The addition of 100 mm sodium or potassium fluoride to the assay made possible the use of higher protein concentrations. Fluoride probably exerts its effect by preventing the rapid destruction of ATP by ATPase and providing enough ATP for the succinyl-CoA generating system. This fluoride effect was observed in the sonicated homogenates and particulate fractions of chick embryo, chick and adult chicken livers and cultured chick embryo liver cells. In those assays depending on the endogenous formation of succinyl-CoA the native homogenates and particulate fractions had relatively low δ-aminolevulinic acid synthetase activity and sonication or the addition of fluoride had no enhancing effect.     

Peroxisomal oxidases and catalase in liver and kidney homogenates of normal and di(ethylhexyl)phthalate-fed rats.

1. Activities of peroxisomal oxidases and catalase were assayed at neutral and alkaline pH in liver and kidney homogenates from male rats fed a diet with or without 2% di(2-ethylhexyl)phthalate (DEHP) for 12 days. 2. All enzyme activities were higher at alkaline than at neutral pH in both groups. 3. The effect of the DEHP-diet on the peroxisomal enzymes was different in kidney and liver. Acyl-CoA oxidase activity was raised three- and sixfold in kidney and liver homogenates, respectively. The activity of D-amino acid oxidase decrease in liver, but increased in kidney homogenates. In liver homogenates, urate oxidase activity was not affected by the DEHP diet. The catalase activity was twofold induced in liver, but not in kidney. 4. The differences suggest that the changes of peroxisomal enzyme activities by DEHP treatment are not directly related to peroxisome proliferation. 5. DEHP treatment caused a marked increase of total and peroxisomal fatty acid oxidation in rat liver homogenates. 6. In the control group the rate of peroxisomal fatty acid oxidation was higher at alkaline pH than at neutral pH. 7. This rate was equal at both pH values in the DEHP-fed group, in contrast to the acyl-CoA oxidase activity. These results indicate that after DEHP treatment other parameters than acyl-CoA oxidase activity become limiting for peroxisomal beta-oxidation.     

Activity of proteolytic enzymes in the kidney and blood serum of rabbits during implantation of different polyurethanes

It is shown that the activity of neutral proteinase both in homogenate and in blood serum increases by the 14th day the D-1 sample being implanted. In the subsequent periods after implantation the enzyme activity in homogenate is the same. Three and six months after implantation the neutral proteinase activity in blood serum decreases as compared to the norm. The activity of acid proteinase in rabbit kidney homogenates lowers by the 90th day after implantation both for the D-1 and for A-10 samples. For the D-1 sample the enzyme activation in blood serum is observed by the 30th day after implantation, three months later it falls to reach the normal level in 6-12 months and inhibition activity on the 30th day after implantation on the A-10 sample. Such changes in the activity of enzymes in homogenates and blood serum may reflect certain stages of polyurethane biodestruction participation of various enzymic systems of the organism in these processes.     

The effect of starvation on the incorporation of palmitate into glycerides and phospholipids of rat liver homogenates

1. Glyceride biosynthesis from glycerol phosphate and [1-(14)C]palmitate was studied in liver homogenates of rats that were fed ad libitum or starved for 36-40hr. The changes in enzyme activity were related to total DNA content or total liver homogenate as these were found to be equivalent and to be the most meaningful parameters. 2. In liver homogenates from fed rats, labelled palmitate was incorporated mainly into phosphatidate (58% of the total incorporation into lipids), diglycerides (25%) and triglycerides (16%), whereas monoglycerides, cholesterol esters and phospholipids other than phosphatidate were labelled only to a small extent. Addition of particle-free supernatant to full homogenates increased the total incorporation of palmitate by 45% and the pattern of incorporation altered to 53% incorporated into triglycerides, 24% into diglycerides and 17% into phosphatidate. This result suggested that, in liver homogenates, phosphatidate phosphohydrolase (EC 3.1.3.4) may be rate-limiting in the biosynthesis of glycerides via the glycerol phosphate pathway. 3. Upon starvation, the amount of palmitate incorporated per liver into total phospholipids plus glycerides was decreased to between 68% and 75% of that observed with fed animals. In homogenates from fed animals 41-44% of the labelled phospholipids plus glycerides was in glycerides; this value increased to between 63% and 75% with starved rats. Of the palmitate incorporated into total phospholipids, between 85% and 86% was found in phosphatidate, independent of the nutritional state of the animal. The ratio of palmitate incorporated into triglycerides/diglycerides rose from 0.7, obtained with fed rats, to 1.0 with starved animals. 4. These results indicate that starvation caused a decrease in the activity (per total liver) of acyl-CoA-glycerol phosphate acyltransferase(s) (EC 2.3.1.15) and an increase in the activity of acyl-CoA-diglyceride acyltransferase (EC 2.3.1.20). The largest change, however, seemed to be related to the increased activity of the phosphatidate phosphohydrolase in the particle-free supernatant. 5. The latter enzyme was assayed in the particle-free supernatant with membrane-bound phosphatidate as substrate. In starvation, the activity per total liver was increased to between 130% and 190% and the specific activity to between 180% and 320% of the values for fed rats.