Blockade of ATP-sensitive potassium channels in cerebral arterioles inhibits vasoconstriction from hypocapnic alkalosis in cats.

BACKGROUND AND PURPOSE: Recent studies have shown that the cerebral arteriolar dilation from hypercapnic acidosis is blocked by agents which inhibit KATP channels. These findings suggested that this response is due to opening of KATP channels. Because the repose to CO2 is a continuum, with hypercapnic acidosis causing vasodilation and hypocapnic alkalosis causing vasoconstriction, it would be expected that the response to hypocapnic alkalosis would be due to closing of KATP channels. There are no studies of the effect of inhibition of KATP channels on the response to hypocapnic alkalosis. METHODS: We investigated the effect of 3 agents that in earlier studies were found to inhibit KATP channels--NG-nitro-L-arginine, hydroxylysine, and glyburide--on the cerebral arteriolar constriction caused by graded hypocapnia induced by hyperventilation in anesthetized cats equipped with cranial windows. RESULTS: Hypocapnic alkalosis caused dose-dependent vasoconstriction that was inhibited completely by each of the 3 inhibitors of KATP channels. The blockade induced by these agents was eliminated in the presence of topical L-lysine (5 micromol/L). CONCLUSIONS: The findings show that agents which inhibit ATP-sensitive potassium channels in cerebral arterioles inhibit the vasoconstriction from hypocapnic alkalosis. These and earlier results showing that inhibition of KATP channels inhibited dilation from hypercapnic acidosis demonstrate that the response to CO2 in cerebral arterioles is mediated by the opening and closing of KATP channels.

Metabolism of polyamines and basic amino acids in Erwinia amylovora: application of liquid chromatography/electrospray mass spectrometry to proferrioxamine precursor feeding and inhibition studies.

Erwinia amylovora, the etiological agent of fire blight, produces a family of proferrioxamine siderophores, which may be essential for the pathogen to establish itself in its hosts. If so, then control of fire blight may perhaps be possible via interference with proferrioxamine biosynthesis. Proof of this hypothesis requires prior knowledge of the corresponding biosynthetic pathways in E. amylovora. As a first step towards understanding proferrioxamine biosynthesis, it was of interest to investigate the ability of the fire blight bacterium to utilize various potential biosynthetic pathways for diamines. Feeding of lysine, ornithine and diaminobutyric acid gave rise to highly elevated levels of cadaverine, putrescine and diaminopropane, respectively, indicating that the corresponding decarboxylase activities are all present in E. amylovora. The conclusion for lysine decarboxylase was confirmed with (15N2)lysine, which was converted to (15N2)cadaverine. Arginine did not increase putrescine levels substantially, but (13C6)arginine nevertheless gave rise to (13C4)putrescine while suppressing excretion of non-labeled putrescine. A serendipitous result of this study was the finding that the growth of E. amylovora can be inhibited with 5-hydroxylysine and 1,4-diamino-2-butanone. The mechanism of inhibition appears complex and is not yet understood. For 5-hydroxylysine, preliminary investigations point to a competitive inhibition of lysine decarboxylase. However, the growth inhibition cannot be reversed by providing cadaverine, the decarboxylation product of lysine.

Inhibition of alpha-aminoadipate-semialdehyde dehydrogenase from Trichosporon adeninovorans by lysine and lysine analogues.

The alpha-aminoadipate-semialdehyde dehydrogenase (EC 1.2.1.31) of Trichosporon adeninovorans, an enzyme of lysine biosynthesis, was partially purified, some properties of the enzyme were studied and a novel regulatory pattern was found. The Km values of the enzyme were estimated to be 0.78 mM for alpha-aminoadipate, 1.0 mM for ATP, 0.23 mM for NADPH and 0.77 mM for MgCl2. It is demonstrated that the enzyme can be regulated by lysine and lysine analogues. L-Lysine (Ki of 0.09 mM), S-(beta-aminoethyl)-L-cysteine (Ki of 0.007 mM) and delta-hydroxylysine (Ki of 1.65 mM) inhibited the enzyme activity. The inhibition was competitive with respect to alpha-aminoadipate and non-competitive with respect to both ATP and NADPH.

Modulation of nitrate uptake in Anacystis nidulans by the balance between ammonium assimilation and CO2 fixation.

Gradual inhibition of ammonium assimilation in Anacystis nidulans cells by increasing concentrations of 5-hydroxylysine resulted in a progressive enhancement of nitrate uptake. For 5-hydroxylysine-treated cells, the magnitude of the inhibition of nitrate uptake promoted by added ammonium was dependent on the ammonium assimilation capacity. In cells with a moderate ammonium assimilation activity, acceleration of CO2 fixation induced by bicarbonate addition antagonized the negative effect of ammonium, allowing full nitrate uptake activity. The results support the contention that nitrate utilization is under the feed-back control exerted by products of its own assimilation via ammonium, the inhibitory effect being potentiated by ammonium addition and alleviated by enhanced CO2 fixation. Results of amino acid analysis in cells exhibiting different capacities to utilize nitrate speak against these compounds as direct effectors of nitrate uptake.

Influence of glutamine on the growth of human glioma and medulloblastoma in culture.

Cellular supply of glutamine, an essential substrate for growth, is derived from extracellular fluid and de novo synthesis. We investigated the relative importance of these sources to the growth of six human anaplastic glioma- and one human medulloblastoma-derived permanent cell lines. Exogenous glutamine was limiting for the proliferation of glioma-derived lines D-54 MG, U-118 MG, and U-251 MG. In contrast, medulloblastoma-derived line TE-671 and glioma-derived lines U-373 MG, D-245 MG, and D-259 MG grew in the absence of supplemental glutamine. Two cell lines with contrasting glutamine requirements, D-54 MG and TE-671, were used to explore the pharmacological interference with glutamine metabolism. DL-alpha-Aminoadipic acid, a reported glutamic acid analogue with gliotoxic properties, significantly inhibited the growth of both lines. These effects were reversed by increasing glutamine, suggesting that the major action of DL-alpha-aminoadipic acid is as a glutamine antagonist. In contrast, the glutamine synthetase inhibitor delta-hydroxylysine demonstrated activity only against TE-671. Acivicin and 6-diazo-5-oxo-L-norleucine, glutamine analogues available for clinical use, reduced the proliferation of both cell lines at pharmacological concentrations. Methionine sulfoximine, a glutamine synthetase inhibitor previously used clinically, produced marked growth inhibition only against TE-671. These findings indicate that the synthesis and utilization of glutamine are potentially exploitable targets for the chemotherapy of some human gliomas and medulloblastomas.

Variation of antimetabolite sensitivity with different carbon sources in Bacillus subtilis.

The susceptibility of Bacillus subtilis to amino acid analogues was found to be markedly influenced by the carbon source used in the test media. Thialysine inhibited the bacterium with a greater number of carbon sources than the other two analogues tested. 5-Hydroxylysine was inhibitory with glycerol, lactose, D-xylose, L-arabinose and soluble starch while ethionine showed toxicity with lactose, D-xylose and L-arabinose. None of these analogues were toxic at the levels tested when D-galactose was used as carbon source. The bacterium was not susceptible to thialysine with glycerol, to 5-hydroxylysine with L-arabinose and to ethionine with lactose.

In vitro inhibition of collagen cross links by catechol analogs.

Catechol analogs inhibit the formation of hydroxylysine-derived intermolecular collagen cross links in tissue cultures of chick embryo calvaria. Formation of intermolecular collagen cross links was measured following incorporation of [14C]lysine, reduction with sodium borohydride, and elution from an ion exchange column with a pyridine-formate gradient. Cultures grown in the presence of 10(-3) M catechol, 10(-3) M dopamine, 10(-3) M L-dopa, or 10(-3) M D,L-serine-(2,3,4-trihydroxybenzyl)-hydrazide demonstrated between 43 and 84% inhibition of hydroxylysine formation. Collagen biosynthesis was not diminished in these cultures as compared to controls without additions or with beta-aminopropionitrile when measured by collagenase digestion. The formation of hydroxylysine-derived intermolecular cross links was inhibited 34 to 93% for 5,5'-dihydroxylysinonorleucine and 7 to 71% for 5-hydroxylysinonorleucine. The catechol analogs also inhibit the activity of lysyl hydroxylase as measured by specific tritium release as triated water from an L-[4,5-3H]lysine-labeled unhydroxylated collagen substrate prepared from chick calvaria. Since catechol analogs inhibit the formation of hydroxylysine in a cell-free assay, these compounds must pass into the cells of calvaria in this culture system to inhibit intracellular hydroxylysine formation and subsequently to diminish the reducible intermolecular cross links of the newly synthesized collagen.

The role of hydroxylation of proline in the antigenicity of basement membrane collagen.

Rabbit antibodies to bovine basement membrane collagen were used to compare the antigenic determinants of rat parietal yolk sac basement membrane [14C]procollagen with [14C]protocollagen. Basement membrane [14C]protocollagen was found to be less antigenic than basement membrane [14C]procollagen. Hydroxylation of basement membrane [14C]protocollagen, either intracellularly or in vitro with protocollagen prolyl hydroxylase, resulted in restoration of antigenicity. The difference in antigenicity observed between basement membrane [14C]procollagen and basement membrane [14C]protocollagen appeared to depend primarily upon the presence of hydroxyproline in the collagen molecule. Glucosylgalactosylhydroxylysine was found to be unimportant for antigenicity.

Effect of hydroxylysine on the biosynthesis of lysine in saccharomyces.

Hydroxylysine acts as a growth inhibitor of Saccharomyces for a certain period of time. The inhibition is concentration-dependent and is reversed by a small amount of lysine in the medium. After the growth-inhibitory period, the wild-type cells are able to grow rapidly even in the presence of hydroxylysine. Both lysine auxotrophs and wild-type cells are unable to utilize hydroxylysine in place of lysine. Hydroxylysine, mimicking lysine, controls the biosynthesis of lysine and thereby limits the availability of biosynthetic lysine to the cells. Hydroxylysine affects the biosynthesis of lysine at a number of enzymatic steps. Accumulation of homocitric acid, the first intermediate of lysine biosynthesis, in the mutant strains 19B and A B9 is reduced significantly in the presence of hydroxylysine. Hydroxylysine, like lysine, exerts a significant inhibition in vitro on the homocitric acid-synthesizing activity. Enzymes following the alpha-aminoadipic acid step respond in a noncoordinate fashion to hydroxylysine. Level of the enzyme saccharopine reductase, but not of alpha-aminoadipic acid reductase or saccharopine dehydrogenase, is reduced significantly. These regulatory effects of hydroxylysine are similar to those observed for lysine.

Control of glutamine synthesis in rat liver.

1. On perfusion of livers from fed rats with a semi-synthetic medium containing no added amino acids there is a rapid release of glutamine during the first 15min (15.6+/-0.8mumol/h per g wet wt.; mean+/-s.e.m. of 35 experiments), followed by a low linear rate of production (3.6+/-0.3mumol/h per g wet wt.; mean+/-s.e.m. of three experiments). The rapid initial release can be accounted for as wash-out of preexisting intracellular glutamine. 2. Addition of readily permeating substrates, or substrate combinations, giving rise to intracellular glutamate or ammonia, or both, did not appreciably increase the rate of glutamine production over the endogenous rate. The maximum rate obtained was from proline plus alanine; even then the rate represented less than one-fortieth of the capacity of glutamine synthetase measured in vitro. 3. Complete inhibition of respiration in the perfusions [no erythrocytes in the medium; 1mm-cyanide; N(2)+CO(2) (95:5) in the gas phase] or perfusion with glutamine synthetase inhibitors [l-methionine dl-sulphoximine; dl-(+)-allo-delta-hydroxylysine] abolishes the low linear rate of glutamine synthesis, but not the initial rapid release of glutamine. 4. In livers from 48h-starved rats initial release (0-15min) of glutamine was decreased (10.6+/-1.1mumol/h per g wet wt.; mean+/-s.e.m. of 11 experiments) and the subsequent rate of glutamine production was lower than in livers from fed rats. Again proline plus alanine was the only substrate combination giving an increase significantly above the endogenous rate. 5. The rate of glutamine synthesis de novo by the liver is apparently unrelated to the tissue content of glutamate or ammonia. 6. The blood glutamine concentration is increased by 50% within 1h of elimination of the liver from the circulation of rats in vivo. 7. There is an output of glutamine by the brain under normal conditions; the mean arterio-venous difference for six rats was 0.023mumol/ml. 8. The high potential activity of liver glutamine synthetase appears to be inhibited by some unknown mechanism: the function of the liver under normal conditions is probably the disposal of glutamine produced by extrahepatic tissues.