New insights into the active center of rat liver cystathionase.

Treatment by urea of purified rat liver cystathionase (L-Cystathionine cysteine-lyase (deaminating), EC 4.4.1.1) provoked a similar alteration of two activities of the enzyme, namely cysteine desulfhydration and homoserine deamination. Since the decreases of the two activities were also comparable as a result of chymotrypsin digestion of the enzyme, these observations suggest that the two sites responsible for the one and the other activites are in close proximity. Studies of the effect of derivatives of substrates (S-carboxymethylcyste-ine, S-carboxyethylcysteine, S-carboxymethylhomocysteine and S-carboxyethylhomocysteine) on both activities were performed. All of them inhibited cysteine desulfhydration and homoserine deamination; in several cases, the type of inhibition was also determined. The results are in agreement with the hypothesis that each of the two sites of the active center has, at least, three binding points which "recognise" groupings of substrates or of inhibitors, and this led us to propose a model for the active center. Each site has an -NH-2 binding point, hence the active center has two -NH-2 binding points; therefore, as cystathionase consists of four subunits and contains four molecules of pyriodoxal phosphate, it might be of interest to determine whether the smallest active molecule is the dimer.     

Citrate and the conversion of carbohydrate into fat. The regulation of fatty acid synthesis by rat liver extracts

1. The rate of fatty acid synthesis by particle-free extracts prepared from rat liver is increased greatly if the enzyme system is first activated with citrate. 2. The extent of the activation depends on the citrate concentration and on the time of activation in an interdependent manner. 3. Citrate activation is strongly dependent on temperature. 4. Tricarballylate can replace citrate as an activator, but its presence in the assay inhibits fatty acid synthesis. 5. Mg(2+) ions can replace citrate in the activation but not in the complete reaction system. 6. ATP prevents the activating effect of citrate and Mg(2+) ions. 7. The rate of fatty acid synthesis is increased by palmitoyl-dl-carnitine. This type of activation, additional to that caused by citrate, is rapid and does not depend on prior incubation. 8. Inhibition of fatty acid synthesis by palmitoyl-CoA can be prevented by palmitoyl-dl-carnitine or by increasing the concentration of protein.     

Transamination of L-cystathionine and related compounds by a bovine liver enzyme. Possible identification with glutamine transaminase

A transaminase which catalyses the monodeamination of L-cystathionine was purified 1100-fold with a yield of 15% from bovine liver. The monoketoderivative of cystathionine spontaneously produces the cyclic ketimine. Other sulfur-containing amino acids related to cystathionine such as cystine, lanthionine and aminoethylcysteine were also substrates for the enzyme. The relative molecular mass of the enzyme was determined to be 94 000 with a probable dimeric structure formed of identical subunits. The isoelectric point of the enzyme was at pH 5.0 and the maximal enzymatic activity was found at pH 9.0--9.2. Kinetic parameters for cystathionine and for the other sulfur amino acids as well as for some alpha-keto acids were also determined. Among the natural amino acids tested, glutamine, methionine and histidine were the best amino donors. The enzyme exhibited maximal activity toward phenylpyruvate and alpha-keto-gamma-methiolbutyrate as amino acceptors. The broad specificity of the enzyme leads us to infer that the cystathionine transaminase is very similar or identical to glutamine transaminase.     

The transamination of L-cystathionine, L-cystine and related compounds by a bovine kidney transaminase

An enzyme which actively transaminates L-cystathionine, L-cystine, L-lanthionine and S-aminoethyl-L-cysteine has been purified from bovine kidney. The transaminase appears to be pure up to 90% and probably consists of two subunits of similar molecular mass of about 47 kDa. The enzymatic products arising from the transamination of L-cystathionine and related compounds spontaneously cyclize into ketiminic structures, which are the immediate precursors of unusual imino acids recovered in biological materials. The specificity towards other amino acid and oxo acid acceptors is similar to the specificity exhibited by rat kidney glutamine transaminase. This suggests that the sulfur amino acid transaminations that have been described could be performed by the bovine kidney glutamine transaminase.     

The oxidation of sulfur containing cyclic ketimines The sulfoxide is the main product of S-aminoethyl-cysteine ketimine autoxidation

Summary The products of autoxidation of S-aminoethyl-L-cysteine ketimine (AECK) have been analysed with the amino acid analyzer, with thin layer chromatography and with high performance liquid chromatography. Under the conditions of the assay (pH 8.5, 38°C, O₂ bubbling) AECK is almost totally oxidized in 1.5 hours. Among the final products a component running fast in HPLC, named Cx1, has been isolated, reduced with NaBH₄ and analysed. Reduced Cx1 resulted to show the same properties of synthetic thiomorpholine-3-carboxylic acid-S-oxide, known in the past literature with the name of chondrine. On the basis of these results and by specific chromatographic tests, Cx1 has been identified as the sulfoxide of AECK. Among the other autoxidation products, thiomorpholine-3-one has been identified. The detection, after HCl hydrolysis, of glyoxylic acid and mesoxalic semialdehyde together with cysteamine indicates that compounds provided with easily cleavable S-C bonds, possibly thiohemiacetals or (and) thioesters, are the likely intermediates for other products. AECK sulfoxide and thiomorpholine-3-one are relatively stable and cannot be taken as the main intermediates for the remaining oxidation products.Abbreviations AAA amino acid analyzer - TLC thin layer chromatography - HPLC high performance liquid chromatography - AECK S-aminoethyl-L-cysteine ketimine - AECK-SO aminoethylcysteine ketimine sulfoxide - TMA thiomorpholine-3-carboxylic acid - TMA-SO thiomorpholine-3-carboxylic acid-S-oxide - CMCA S-carboxymethylcysteamine - DNPH 2,4-dinitrophenylhydrazine     

The pathway for the conversion of dihydroagnosterol into cholesterol in rat liver.

Dihydroagnosterol is demethylated by a rat liver homogenate to give 4,4'-dimethylcholesta 7,9-dienol and then cholesta-7,9-dienol. The cholesta-7,9-dienol is isomerized to cholesta-8,14-dienol, which is converted into cholesterol by the normal pathway.     

The decarboxylation of S-adenosylmethionine by detergent-treated extracts of rat liver

1. The production of (14)CO(2) from S-adenosyl[carboxyl-(14)C]methionine by rat liver extracts was investigated. It was found that, in addition to the well-known cytosolic putrescine-activated S-adenosylmethionine decarboxylase, an activity carrying out the production of (14)CO(2) could be extracted from a latent, particulate or membrane-bound form by treatment with buffer containing 1% (v/v) Triton X-100 [confirming the report of Sturman (1976) Biochim. Biophys. Acta428, 56-69]. 2. The formation of (14)CO(2) by such detergent-solubilized extracts differed from that by cytosolic S-adenosylmethionine decarboxylase in a number of ways. The reaction by the solubilized extracts did not require putrescine and was not directly proportional to time of incubation or the amount of protein added. Instead, activity a showed a distinct lag period and was much greater when high concentrations of the extracts were used. The cytosolic S-adenosylmethionine decarboxylase was activated by putrescine, showed strict proportionality to protein added and the reaction proceeded at a constant rate. Cytosolic activity was not inhibited by homoserine or by S-adenosylhomocysteine, whereas the Triton-solubilized activity was strongly inhibited. 3. By using an acetone precipitate of Triton-treated homogenates as a source of the activity, it was found that decarboxylated S-adenosylmethionine was not present among the products of the reaction, although 5'-methylthioadenosine and 5-methylthioribose were found. Such extracts were able to produce (14)CO(2) when incubated with [U-(14)C]-homoserine, and (14)CO(2) production was greater when S-adenosyl[carboxyl-(14)C]methionine that had been degraded by heating at pH6 at 100 degrees C for 30min (a procedure known to produce mainly 5'-methylthioadenosine and homoserine lactone) was used as a substrate than when S-adenosyl[carboxyl-(14)C]methionine was used. 4. These results indicate that the Triton-solubilized activity is not a real S-adenosylmethionine decarboxylase, but that (14)CO(2) is produced via a series of reactions involving degradation of the S-adenosyl-[carboxyl-(14)C]methionine. It is probable that this degradation can occur via several pathways. Our results would suggest that part of the reaction occurs via the production of S-adenosylhomocysteine, which can then be converted into 2-oxobutyrate via the transsulphuration pathway, and that part occurs via the production of homoserine by an enzyme converting S-adenosylmethionine into 5'-methylthioadenosine and homoserine lactone.     

Presence of an intermediate synthase form during the conversion of glycogen synthase D into synthase I in rat liver extract

When synthase D was converted into synthase I in a liver extract, it progressed through a synthase form with activity characteristics that could not be explained by a mixture of the original synthase D and the final product, synthase I. This form was distinguished by an affinity for UDP-glucose, in the absence of glucose 6-phosphate, which was intermediate between those of the two known forms.     

Pathways of fructose conversion into glucose in foetal rat liver

1. Glucose, formed from [1-(14)C]fructose or [6-(14)C]fructose in rat-liver slices, has been isolated as gluconate and degraded to give the radioactivity in C-1, C-2-5 and C-6. 2. By using this method it has been shown that, in liver from foetal rats younger than 20 days, glucose is formed from fructose without splitting of the molecule by the aldolase reaction. The rate of glucose formation from fructose in liver from these foetuses is approximately half of the rate in adult liver. 3. The direct conversion of fructose into glucose in foetal rat liver is not via sorbitol as in seminal vesicles, as this pathway cannot be detected. 4. When liver slices are incubated with [U-(14)C]fructose of high specific activity, the labelled intermediates are similar whether from liver from 18-day foetal, newborn or adult rats. 5. These findings are discussed with reference to the changing pathways of fructose metabolism during perinatal development of the liver in the rat.