Determination of pools of tricarboxylic acid cycle and related acids in bacteria.

Methods for sampling, extracting, and quantitating the metabolic pools of organic acids from bacteria have been developed. The concentration of these metabolites was determined by a new gas chromatographic method that can quantitatively determine the levels of lactate, pyruvate, fumarate, succinate, malate, alpha-ketoglutarate, and citrate. Values obtained were confirmed by fluorimetric analyses of five of the individual acids. In Escherichia coli, pools range from about 1 to 5 mumol/g of dry weight, with a variation in replicate samples of 5 to 15%. Under similar conditions, these pools in Bacillus licheniformis are in the same range, although the pyruvic acid pool is significantly larger.     

Free amino acids in various tissues of a fresh-water teleost, Rasbora daniconius (Ham). I. Qualitative analysis

Seven different tissues of the fish, Rasbora daniconius are analysed chromatographically for their free amino acid contents. Alanine and Cystine followed by Glycine and Glutamic acid are the most common amino acids found in the tissues. On the basis of sex, no apparent difference in amino acid pattern in various tissues is found. Up to 70% of the amino acids of the pools fall in the range of pH from 4.5-6.5. Thus it appears that the pools have some bearing on the maintenance of the tissue pH.     

Changes in Cerebral Acyl-CoA Concentrations Following Ischemia-Reperfusion in Awake Gerbils

Abstract: Transient global cerebral ischemia affects phospholipid metabolism and features a considerable increase in unesterified fatty acids. Reincorporation of free fatty acids into membrane phospholipids during reperfusion following transient ischemia depends on conversion of fatty acids to acyl-CoAs via acyl-CoA synthetases and incorporation of the acyl group into lysophospholipids. To study the effect of ischemia-reperfusion on brain fatty acid and acyl-CoA pools, the common carotid arteries were tied for 5 min in awake gerbils, after which the ligatures were released for 5 min and the animals were killed by microwave irradiation. Twenty percent of these animals (two of 10) were excluded from the ischemia-reperfusion group when it was demonstrated statistically that brain unesterified arachidonic acid concentration was not elevated beyond the range of the control group. Brain unesterified fatty acid concentration was increased 4.4-fold in the ischemic-reperfused animals, with stearic acid and arachidonic acid increasing the most among the saturated and polyunsaturated fatty acids, respectively. The total acyl-CoA concentration remained unaffected, indicating that reacylation of membrane lysophospholipids is maintained during recovery. However, there was a substantial increase in the stearoyl- and arachidonoyl-CoA and a marked decrease in palmitoyl- and docosahexaenoyl-CoA. These results suggest that unesterified fatty acid reacylation into phospholipids is reprioritized according to the redistribution in concentration of acyl-CoA molecular species, with incorporation of stearic acid and especially arachidonic acid being favored.     

Relative effects of S-adenosylmethionine depletion on nucleic acid methylation and polyamine biosynthesis.

Treatment of cultured L1210 cells with 1 mM-L-2-amino-4-methoxy-cis-but-3-enoic acid (L-cisAMB), a methionine-analogue inhibitor of S-adenosylmethionine (AdoMet) synthetase (EC 2.5.1.6), produced a rapid and near-total depletion of AdoMet by 4 h. After this, the pools recovered to 60% of control by 48 h, apparently because of an increase in AdoMet synthetase activity. Both AdoMet depletion and the accompanying increase in synthetase activity were substantially enhanced by lowering methionine concentrations in the media from 100 microM to 30 microM, the minimal concentration that supports cell growth at control values. During a 4 h incubation in media containing 30 microM-methionine, 1-5 mM-L-cisAMB depleted cellular AdoMet to undetectable values, and inhibited nucleic acid methylation by 44-72% and RNA methylation by 60-87%. Under these same treatment conditions, putrescine pools increased by about 3-fold, whereas spermidine pools decreased by only 20% and spermine pools remained the same. Pool changes were accompanied by a 2-4-fold increase in ornithine decarboxylase activities and AdoMet activities. Thus the rapid depletion of AdoMet pools by L-cisAMB results immediately in a decrease in methyl-transfer reactions involving nucleic acids, whereas, by contrast, biosynthesis of higher polyamines appears to be minimally affected, owing to compensatory increases in key enzyme activities.     

Assessment of protein turnover in perfused rat liver. Evidence for amino acid compartmentation from differential labeling of free and tRNA-gound valine.

Total protein synthesis in perfused livers of fed rats was determined by measuring the rate of valine incorporation based on the specific activity of valine attached to tRNA. Rates were not significantly altered when perfusate valine was increased from 0.40 to 5 mM and were similar to values calculated earlier from the specific activity of extracellular valine at a concentration of 15 mM. Overall protein degradation, computed from the sum of the rates of synthesis and the total increase of free intra- and extracellular valine, corresponded closely to the increase of free valine that occurred between 5 and 15 min after the addition of cycloheximide. In the latter experiments advantage was taken of the fact that the previously established suppressive effect of cycloheximide on proteolysis does not begin initially with the inhibition of synthesis, but 15 min later. Thus, the release of valine from 5 to 15 min was assumed to represent rates of protein degradation in effect prior to the addition of cycloheximide. The close agreement found among these independent assessments of protein metabolism thus appears to eliminate much of the previous uncertainty in the quantitation of hepatic protein turnover. In the course of these studies we noted that the specific activity of valyl-tRNA attained steady state values that were intermediate between specific activities of the extracellular and intracellular pools, but appeared to reach a steady state sooner than that of intracellular valine. To evaluate these early events more precisely, the specific activity of valine in tRNA and the intracellular pool was measured in a series of single-pass perfusion experiments where extracellular valine concentration and specific activity were held constant. The intracellular valine specific activity rose with a half-life of 1.2 min. By contrast, the rise in the specific activity of valyl-tRNA was biphasic: the initial phase of the valyl-tRNA curve was rapid, while the second phase had a half-life equal to that of intracellular valine. These data show that at physiological concentrations of valine, valyl-tRNA derives its amino acids from both the extracellular and cytoplasmic pools, and that at least some tRNA is charged by extracellular amino acids before they mix with intracellular amino acid pools, possibly from a precursor pool at or near the cell membrane.     

肠道菌群与胆汁酸的互作在 相关疾病中的作用

胆汁酸在人体的胆固醇代谢、脂质消化、宿主-微生物相互作用及通路调控等方面具有重要作用。大多数胆汁酸(95%)通过肝肠循环重回收,还有约5%作为结肠内细菌生物转化的基质。胆汁酸微生物转化中涉及的各种酶可通过肠道细菌培养而被验证,证明其有种属特异性。最近,生物信息学方法揭示了这些酶有多种亚型。因此,在胆汁酸转化中肠道菌群发挥重要的作用,微生物群落结构和功能对次级胆汁酸在胆汁酸池中的分布有深刻影响。研究认为胆汁酸和胆汁酸池的组成与几种疾病有关,包括炎症性肠病、代谢综合征和结直肠癌。最近,人们的重点放在肠道菌群如何改变胆汁酸进而导致或减轻某些疾病。本文总结了肠道菌群、胆汁酸生物转化和疾病状态之间的相互作用的研究进展。     

Effect of growth conditions on accumulation of internal nitrate,ammonium, amino acids,and protein in three marine diatoms

The capacity of marine phytoplankton to change their cellular content of nitrate, ammonium, amino acids, and protein in response to different growth conditions was systematically investigated. Cellular concentrations of these compounds were measured in N-starved, N-deficient, and N-sufficient Skeletonema costatum (Grev.) Cleve and in N-deficient Chaetoceros debilis Cleve and Thalassiosira gravida Cleve, both before and after the addition of a pulse of nitrogen.N-sufficient Skeletonema costatum contains high concentrations of protein, large persistent pools of amino acids, and, if it is growing on nitrate, sizeable amounts of nitrate. As it becomes N-starved, the total cellular nitrogen decreases, the internal nitrate and amino acids become entirely depleted, and the protein content is drastically reduced. After nitrogen additions to N-deficient and N-starved cultures, transient pools of unassimilated nitrogen form which can account for a large fraction of newly taken up nitrogen. The size and kind of pool which accumulates is determined by the preconditioning of the cells, the nitrogen compound which is added, and the species identity. The pools which form in S. costatum indicate that nitrate reduction is the slowest step in nitrogen assimilation, the synthesis of protein from amino acids is the next slowest, and the incorporation of ammonium into amino acid is the fastest. However, the rate limiting steps may vary between diatom species.For the first time, measurements of the variation in cellular nitrogen compounds over a wide range of environmental conditions reveal the ability of some phytoplankton to buffer the effects of a changing, and sometimes growth-limiting, nitrogen supply. They accomplish this by utilizing stored internal nitrogen for growth when the external supply is low and by quickly storing unassimilated nitrogen when the external supply is suddenly increased beyond their ability to immediately assimilate it. The accumulation of large pools of unassimilated nitrogen compounds can explain the often observed difference between nitrogen uptake rates and growth rates.     

Effects of temperature on the uptake of glutamic acid and lysine in a psychrophilic yeast

Uptake of labeled amino acids occurred at –4 C to 50 C accompanied by amino acid pool formation and protein synthesis. Maximum assimilation rates of both amino acids occurred at a temperature at which growth of this yeast was inhibited. Over a wide range of temperature the organism took up more exogenous lysine than glutamic acid, even though glutamic acid was present in the cellular protein in greater quantities. At 25 C the uptake and incorporation rates of glutamic acid was significantly higher than at 3 C; however, the size of the glutamic acid pools, at these two temperatures, appeared to be equal and independent of temperature.     

Soil amino-acid availability across a temperate-forest fertility gradient

Despite increasing recognition that free amino acids can be an important source of N for plant uptake, we have a poor understanding of environmental variation in the availability of amino-acid N in soils outside of arctic, alpine and boreal regions. I investigated patterns of amino-acid availability along a temperate forest fertility gradient ranging from low mineral N availability, oak-dominated forests to high mineral N availability, maple-basswood forests (5 sites). I measured standing pools of free amino acids, soluble peptides, ammonium and nitrate, rates of amino acid production (native proteolysis activity) and rates of consumption of a ¹⁵N-labeled leucine tracer. Standing pools of amino acid N decreased consistently along the fertility gradient from the low fertility black oak/white oak system to the high fertility sugar maple/basswood system, with a 25-fold difference in pool sizes between the poorest and richest sites. Standing pools of soluble peptides varied little among sites, instead, the relationship between free amino acids and peptides changed markedly across the gradient. At low fertility sites free amino acids were positively correlated with soluble peptides, whereas free amino acid pools were universally low at high fertility sites, regardless of peptide pools. Assays for native proteolysis activity indicated that amino acid production did not vary significantly among sites. Recovery of leucine tracer in inorganic (NH₄ ⁺ and NO₃ ⁻) pools and in residual soil organic matter both increased with increasing soil fertility; however, total consumption of the added amino-acid tracer did not vary among sites. Results from this study demonstrate that free amino acids can make an important contribution to potentially plant-available N pools in temperate forest soils, particularly at low fertility sites.     

Chirality differences in amino acid retention and release from the acid-extractable pool of cultured mammalian cells

In previous work, no chiral differences were found between D and L enantiomers of Leu in their ability to displace one another from the acid-extractable pool in mammalian cells. Recent evidence suggested otherwise. Our aim is to examine whether, in physiological range, D-amino acids have an equivalent ability to displace L-amino acids from the acid-extractable pool of HeLa cells, and vice versa. In the millimolar range, D-Leu and L-Leu have similar uptake and displacement properties with regard to the acid-extractable pool in HeLa cells, despite only the latter isomer being incorporated into protein. Below millimolar concentrations however, a distinct difference was found in the displacement of tritium-labelled L-Leu from the pool by unlabelled D-Leu compared with unlabelled L-Leu. Thus, unlabelled L-Leu in the external medium at 10⁻⁴ or 10⁻⁵ M displaced an equivalent amount of label from the pool as D-Leu introduced at a concentration approx. one order of magnitude higher, respectively. Reciprocal experiments, in which the acid-extractable pool was preloaded with ³H-D-Leu, confirmed this finding. The chirality difference was noted whether pool prelabelling was carried out at 37 or 0°C; but in order to avoid the complications of active transport mechanisms, the competition work reported here was done at 0°C. Similar chirality differences were observed with other hydrophobic amino acids, including His, Ile and Phe, such as, preferential displacement by the L-Leu racemer compared with the D-Leu racemer below mM levels. This was also true for the D and L forms of the non-utilisable isomer of Leu, norleucine (nLeu). We conclude that D-forms of hydrophobic amino acids have lower affinity for similar or the same intracellular binding sites involved in the acid-extractable pool than their L-forms. The significance of these chirality findings to amino acid pools in cells, and to the predominance of L-forms of amino acids in the biosphere is considered.     

Some characteristics of a high molecular weight lipid-protein aggregate and its possible role in intracellular fatty acid metabolism

Several physical aspects of a high molecular weight lipid-protein aggregate separated by gel chromatography from chick and rat liver cytosol and its possible role in intracellular fatty acid metabolism were investigated. Electron microscopic examination of the high molecular weight lipid-protein aggregate indicated spherical particles with a diameter range of 200-600 A. This structure is consistent with a microemulsion particle of triglyceride encapsulated by phospholipid and protein. Uptake of fatty acids by microsomes occurred from the same lipid-protein aggregate, and the triglycerides synthesized in microsomes also became associated with these particles in the cytosol. The lipid-protein aggregate prepared by different homogenization methods showed identical ratios of components, but these ratios changed following incubation. These findings lend support to the concept that this aggregate plays a physiological role in intracellular lipid metabolism, and may be identifiable with previously reported subcellular fatty acid and triglyceride pools.     

In Vivo Studies on the Extracellular, and Veratrine-Releasable, Pools of Endogenous Amino Acids in the Rat Striatum: Effects of Corticostriatal Deafferentation and Kainic Acid Lesion

The effects of corticostriatal deafferentation (decortication) and destruction of intrinsic neurons (intrastriatal kainate injection) on the extracellular concentration, and veratrine-releasable pools, of endogenous amino acids in the rat striatum were examined using the in vivo brain dialysis technique. Intracellular amino acid content was also determined. Decortication reduced selectively intra- and extracellular levels of glutamate (Glu) and aspartate (Asp). Extracellular changes were more pronounced than those in tissue content. gamma-Aminobutyric acid (GABA), taurine (Tau), and phosphoethanolamine (PEA) levels were not affected, whereas nonneuroactive amino acids were increased at 1 week but not at 1 month post-lesion. The intracellular pool of Glu and Asp was also reduced in kainate-lesioned striata. However, extracellular levels of these compounds were not affected significantly by this treatment. The tissue content of all other amino acids was decreased, the most prominent change being in the concentration of GABA. Extracellular GABA concentration was also reduced dramatically, whereas the concentrations of noneuroactive amino acids were increased to varying degrees. These data suggest that transmitter pools of neuroactive amino acids are an important supply for their extracellular pools. Lesion-induced alterations in nonneuroactive amino acids are discussed with regard to the loss of metabolic pools, glial reactivity, and changes in blood-brain barrier transport. Veratrine induced a massive release of neuroactive amino acids such as Glu, Asp, GABA, and Tau into the extracellular fluid, and a delayed increase in PEA. Extracellular levels of neuroactive amino acids were raised slightly. Decortication reduced, selectively, the amounts of Glu and Asp released by veratrine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of 9-O-acetyl-N-acetylneuraminic acid in normal canine pre-ocular tear film secreted mucins and its depletion in Keratoconjunctivitis sicca

O-Acetylated sialic acids have been reported in many sialoglycoproteins where they mediate a variety of immune and other biological events. We have previously demonstrated that the protective mucus barrier on the surface of the canine eye contains sialoglycoproteins. We have also investigated the occurrence of O-Acetylated sialic acids in these ocular mucins. Mucus aspirated from the surface of normal dog eyes and those with keratoconjunctivitis sicca (KCS) was fractionated into three pools by density gradient centrifugation. Sialic acids comprised 0.6–0.9% of the dry weight of the mucins isolated. The sialic acid profile in these pools was examined using HPLC. O-Acetylated sialic acids, mainly Neu5,9Ac₂, were detected in normal animals and made up 10–30% of the total sialic acids detected. A doubling of the sialic acid content was found in KCS mucins, but the level of 9-O-Acetylated sialic acid was reduced below 4% of total. Histological analysis of conjunctival tissue from normal and KCS dogs showed the presence of sialic acids, detected with the α(2–6) sialic acid-specific lectin Sambucus nigra, in the goblet cells and corresponding to the staining pattern for MUC5AC, the major ocular-secreted mucin gene product. In KCS animals a disruption of the normal pattern of conjunctival goblet cells was seen with preservation of the pattern of lectin binding observed in normal animals. Thus the data demonstrate the presence of mono-O-Acetylated sialic acids in normal canine ocular mucins and a loss of this population of sialic acids in dry eye disease in spite of a significant increase in total sialic acids in KCS mucin.     

Isotope labelling of Rubisco subunits provides in vivo information on subcellular biosynthesis and exchange of amino acids between compartments

The architecture of plant metabolism includes substantial duplication of metabolite pools and enzyme catalyzed reactions in different subcellular compartments. This poses challenges for understanding the regulation of metabolism particularly in primary metabolism and amino acid biosynthesis. To explore the extent to which amino acids are made in single compartments and to gain insight into the metabolic precursors from which they derive, we used steady state (13) C labelling and analysed labelling in protein amino acids from plastid and cytosol. Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) is a major component of green tissues and its large and small subunits are synthesized from different pools of amino acids in the plastid and cytosol, respectively. Developing Brassica napus embryos were cultured in the presence of [U-(13) C]-sucrose, [U-(13) C]-glucose, [U-(13) C]-glutamine or [U-(13) C]-alanine to generate proteins. The large subunits (LSU) and small subunits (SSU) of Rubisco were isolated and the labelling in their constituent amino acids was analysed by gas chromatography-mass spectrometry. Amino acids including alanine, glycine and serine exhibited different (13) C enrichment in the LSU and SSU, demonstrating that these pools have different metabolic origins and are not isotopically equilibrated between the plastid and cytosol on the time scale of cellular growth. Potential extensions of this novel approach to other macromolecules, organelles and cell types of eukaryotes are discussed.     

The metabolism of macromolecules during the differentiation of myxamoebae of the cellular slime mould Dictyostelium discoideum containing different amounts of glycogen

1. Methods of obtaining myxamoebae of Dictyostelium discoideum strain Ax-2 (ATCC 24397) with glycogen contents in the range 0.05-5mg of glycogen/10(8) cells are described. The changes in cellular glycogen, protein and RNA content during the differentiation of such myxamoebae were determined. 2. Myxamoebal glycogen is not conserved during differentiation and gluconeogenesis may occur even in cells that contain a large amount of glycogen initially. 3. There is a marked net loss of cellular protein and RNA during differentiation and associated with this there are also marked decreases in the sizes of the intracellular pools of amino acids, acid-soluble proteins and pentose-containing materials. 4. During the early stages of development some protein and pentose(s) are excreted, but this cannot account for the decreased cellular content of protein and RNA. 5. There is a linear rate of production of NH(3) during development, and oxidation appears to be the fate of the major portion of the degraded protein and RNA. 6. However, provision of an alternative metabolizable energy source (glycogen) has little effect on the rate or extent of protein or RNA breakdown or on the changes in the sizes of the intracellular pools of amino acids, acid-soluble proteins and pentose-containing materials. 7. It is concluded that during development there is a requirement for the destruction of specific RNA and protein molecules for reasons other than the provision of oxidizable substrates. 8. The kinetic model of Wright et al. (1968) is discussed in relation to these changes in macromolecular content.     

A physical-chemical model for cellular uptake of fatty acids: prediction of intracellular pool sizes

If the uptake of fatty acids by liver is a physical, not a biological, process, then the size and location of the intrahepatic pool of fatty acids can be predicted from uptake rates and thermodynamic data. The purpose of the experiments in this paper was to test the accuracy of this idea. Rat livers were perfused with palmitate bound to albumin, and the total amounts of palmitate removed from the perfusate were measured at 3-s intervals. The intrahepatic pools of palmitate calculated from these data were 13.8 and 23.0 nmol/g of liver at ratios of palmitate/albumin (mol/mol) (afferent side) of 2/1 and 4/1, respectively, in the steady state. The intrahepatic pools of palmitate calculated from the distributions of palmitate between membranes, H2O, albumin, and fatty acid binding protein and the measured first-order rate constants for acyl-CoA ligases in mitochondria and microsomes were 12.1 and 34.6 nmol/g for perfusate ratios of palmitate/albumin of 2/1 and 4/1, in the steady state. Intrahepatic pools of palmitate measured after establishment of a steady-state rate of uptake were 15.0 and 31.8 nmol/g for these ratios of palmitate/albumin of 2/1 and 4/1.     

The sphingomyelin pools in the outer and inner layer of the human erythrocyte membrane are composed of different molecular species

Analyses of the fatty acid composition of the outer and inner pools of sphingomyelin in the human erythrocyte membrane revealed significant differences in molecular species composition of these two pools. The sphingomyelin in the inner monolayer, representing 15–20% of the total sphingomyelin content of this membrane, is characterized by a relatively high content (73%) of fatty acids, which have less than 20 carbon atoms, whereas these account for only 31% of the total fatty acids in the sphingomyelin in the outer leaflet. On the other hand, the ratio saturated/unsaturated fatty acids in the two pools is similar. Significant differences are also observed for the fatty acid composition of the sphingomyelin in human serum when compared to that in the outer monolayer of the corresponding red cell. These results are interpreted to indicate an (almost) complete absence of transbilayer movements of sphingomyelin molecules in the human erythrocyte membrane, whereas an exchange of this phospholipid between the red cell membrane and serum is either virtually absent, or affects only a minor fraction of the sphingomyelin in the outer membrane layer.     

Polyenoic acid metabolism in cultured dissociated brain cells

The incorporation of [1-(14)C]linolenate (18:3 n - 3) into cellular lipids of cultured dissociated brain cells was studied. During the initial phases of incubation, radioactivity was found in free fatty acids, diacylglycerols, triacylglycerols, and choline phosphoglyceride pools preferentially. Incorporation into the ethanolamine phosphoglyceride pool increased steadily and paralleled desaturation and chain elongation of 18:3 --> 20:3 --> 20:4 --> 20:5 --> 22:5 --> 22:6. From pulse-chase studies it was evident that the label of the highly polyunsaturated fatty acids in ethanolamine phosphoglycerides is constantly increased while the label in the fatty acids of choline phosphoglycerides decreased. Uptake of 18:3 by the cells was reduced by lowering incubation temperature, the triacylglycerol and ethanolamine phosphoglyceride pools being mainly affected. Lowering the incubation temperatures essentially abolished conversion of labeled 18:3 to the higher polyenoic acids. At intermediate temperatures, conversion of 18:3 to 20:5 n - 3 was still active, but conversion of 20:5 n - 3 to 22:6 n - 3 was abolished, suggesting that formation of 22:6 from 18:3 proceeds by at least two reactions distinguishable by their temperature dependency.     

Cholinephosphotransferase and Diacylglycerol Acyltransferase (Substrate Specificities at a Key Branch Point in Seed Lipid Metabolism)

Many oilseed plants accumulate triacylglycerols that contain unusual fatty acyl structures rather than the common 16- and 18-carbon fatty acids found in membrane lipids of these plants. In vitro experiments demonstrate that triacylglycerols are synthesized via diacylglycerols in microsomal preparations and that this same sub-cellular fraction is the site for the synthesis of phosphatidylcholine, which in seeds is synthesized from diacylglycerol by CDP-choline: diacylglycerol cholinephosphotransferase. In microsomes from Cuphea lanceolata, a plant that accumulates fatty acids with 10 carbons and no double bonds (10:0) in its oil, the diacylglycerol acyltransferase exhibited 4-fold higher activity with 10:0/10:0 molecular species of diacylglycerol than with molecular species containing 18-carbon fatty acids. In castor bean (Ricinus communis), which accumulates oil containing ricinoleic acid, diricinoleoyldiacylglycerol was the favored substrate for triacylglycerol synthesis. In contrast to these modest specificities of the diacylglycerol acyltransferases, the cholinephosphotransferases from these plants and from safflower (Carthamus tinctorius) and rapeseed (Brassica napus) showed little or no specificity across a range of different diacylglycerol substrates. Consideration of these results and other data suggests that the targeting of unusual fatty acids to triacylglycerol synthesis and their exclusion from membrane lipids are not achieved on the basis of the diacylglycerol substrate specificities of the enzymes involved and may instead require the spatial separation of two different diacylglycerol pools.     

Screening for Rabbit Brain Neuropeptide-metabolizing Peptidases. Inhibition of Endopeptidase B by Bradykinin Potentiating Peptide 9a (SQ 20881)

Abstract: Neutral thiol-activated peptidases present in the pH 5-soluble fraction of rabbit brain (separated by step-elution chromatography on diethylaminoethyl cellulose) were screened for the hydrolysis of bradykinin, Lysbradykinin, Met-Lys-bradykinin, angiotensin I, angiotensin II, substance P, luteinizing hormone-releasing hormone (LH-RH) and neurotensin by bioassay. The column effluent was monitored for bradykinin inactivation and arylamidase activity and combined in six pools on the basis of bradykinin inactivation. The pools were characterized by determining the peptide fragments and amino acids released from bradykinin with an amino acid analyzer. Pools 1 through 3 contained 80% of the kininase activity and essentially all of the endopeptidase A and B activity, whereas pools 4 through 6 accounted for 98% of the recovered arylamidase activity. Bradykinin, angiotensin I, angiotensin II and substance P were inactivated by all the pools, whereas LH-RH and neurotensin were inactivated by pools 3 and 4 and pools 3, 4 and 5, respectively. These data show that rabbit brain contains peptidases having some selectivity for the inactivation of neuropeptides. Endopeptidase B purified from pool 3 is inhibited by bradykinin-potentiating peptide 9a (BPP_9a' SQ 20881) (Glu-Trp-Pro-Arg-Pro-Gln-Ile-Pro-Pro), a competitive inhibitor of the hydrolysis of bradykinin ( K _m = 3.5 ± 10⁻⁵ m , K _i = 3 ± 10^−6m) which also completely inhibits the inactivation of LH-RH.