Bile acid sulfates. I. Synthesis of lithocholic acid sulfates and their identification in human bile

Sulfate esters of lithocholic, glycolithocholic, and taurolithocholic acids were synthesized using sulfur trioxide in pyridine; they were purified by crystallization from methanol or ethanol as the diammonium salts, and their chemical compositions, infared spectra, and chromatographic behavior were determined. Strong alkaline hydrolysis of these sulfates, as commonly performed during quantitative and qualitative analyses of conjugated bile salts, was found to result in a number of degradation products, presumably through disruption of the C-O bond of the hydroxyl group and conversion of the original steroid to isolithocholate and other (possibly olefinic) compounds. After oral administration of lithocholate-(14)C to three patients with cholelithiasis, radioactive metabolites having the chromatographic properties of sulfated lithocholates were isolated from bile and, confirming a preliminary report (1), were identified as sulfated glycolithocholate and taurolithocholate by their characteristic chromatographic mobilities during a series of specific hydrolytic procedures and by crystallizing them to constant specific activities with the synthetic sulfates. The fraction of endogenous lithocholate present in bile as the sulfate was calculated for two patients by isotope dilution and was shown to be 41% and 75% of the total. Sulfation can be expected to affect the physiological and pharmacological properties of lithocholates and may, therefore, influence the toxic properties of these compounds.     

Bacterial N-succinyl-L-diaminopimelic acid desuccinylase. Purification, partial characterization, and substrate specificity

The enzyme N-succinyl-L-diaminopimelic acid desuccinylase from Escherichia coli has been purified 7,100-fold to apparent homogeneity. The enzyme is part of the diaminopimelic acid-lysine pathway in bacteria and catalyzes the hydrolysis of N-succinyl-L-diaminopimelic acid to produce L-diaminopimelic acid and succinate. The enzyme exists as a mixture of dimeric and tetrameric species of identical subunits of molecular weight approximately 40,000. Activity was completely abolished following dialysis of the enzyme against metal chelators. Cobalt(II) and zinc were effective in restoring the activity. The apparent affinities of the apoenzyme for cobalt and zinc were similar (Kd values near 1 microM) and the cobalt enzyme was 2.2-fold more active than the zinc enzyme. The Km and turnover number for the hydrolysis of the natural substrate, N-succinyl-L-diaminopimelic acid, were 0.4 mM and 16,000 min-1, respectively. The substrate specificity of the enzyme was defined by preparing a number of substrate analogues that systematically lack the various functional groups present in the molecule. These studies show that the enzyme is highly specific for the natural substrate. These properties of N-succinyl-L-diaminopimelic acid desuccinylase and the fact that the enzyme is essential for bacterial growth make it an ideal target for the development of inhibitors with potential antibacterial activity.     

Synthesis and characterization of three primary oligomers of alpha-L-glutamic acid. I

In the present work, the synthesis of the three primary oligomers of α-L -glutamic acid is described; the general formula is the following: [I] The choice of protective groups at the both ends of the chain allows for the good solubility in the water and the liberation of free carboxyl groups on the side chain. Thus, models are obtained for the study of thermodynamic properties of solutions and especially of the interactions between polyanions and cations. The prepared products are characterized by different techniques such as mass spectrometry potentiometry, tonometry, and thin-layer chromatography. The results are in agreement and lead to the conclusions that the molecules have the general formula of [I] and are stereoregular.     

Synthesis and evaluation of GGPP geometric isomers: divergent substrate specificities of FTase and GGTase I.

A stereocontrolled synthetic route has been used to prepare two of the geometric isomers of all-trans-GGPP. Neither of these isomers is effective substrates for mammalian GGTase I, but 3 is a potent inhibitor of this enzyme (IC(50)=100 nM). Surprisingly, both compounds are effective substrates for mammalian FTase.     

pH dependence, substrate specificity and inhibition of human kynurenine aminotransferase I.

Human kynurenine aminotransferase I/glutamine transaminase K (hKAT-I) is an important multifunctional enzyme. This study systematically studies the substrates of hKAT-I and reassesses the effects of pH, Tris, amino acids and alpha-keto acids on the activity of the enzyme. The experiments were comprised of functional expression of the hKAT-I in an insect cell/baculovirus expression system, purification of its recombinant protein, and functional characterization of the purified enzyme. This study demonstrates that hKAT-I can catalyze kynurenine to kynurenic acid under physiological pH conditions, indicates indo-3-pyruvate and cysteine as efficient inhibitors for hKAT-I, and also provides biochemical information about the substrate specificity and cosubstrate inhibition of the enzyme. hKAT-I is inhibited by Tris under physiological pH conditions, which explains why it has been concluded that the enzyme could not efficiently catalyze kynurenine transamination. Our findings provide a biochemical basis towards understanding the overall physiological role of hKAT-I in vivo and insight into controlling the levels of endogenous kynurenic acid through modulation of the enzyme in the human brain.     

Synthesis of renin substrate by rat liver.

The present study attempts to determine if the isolated rat liver is capable of synthesizing renin substrate from 14C-labelled amino acids added in the perfusate. The renin substrate is characterized via reaction with renin, forming a substance that is subsequently identified as proangiotensin. Extensive evaluation of the reaction product is carried out by using molecular-sieve chromatography, countercurrent distribution, reactivity with converting enzyme, radioimmunological technique and bioassay. The results demonstrate that isolated rat liver perfused with artificial salt solution is capable of synthesizing a protein that reacts with renin to form a radioactive substance indistinguishable from proangiotensin.     

Kinetic studies, mechanism, and substrate specificity of amadoriase I from Aspergillus sp.

Amadoriase is a flavoenzyme that catalyzes the oxidative deglycation of Amadori products (fructosyl amino acids or aliphatic amines) to yield free amine, glucosone, and hydrogen peroxide. The mechanism of action of amadoriase I from Aspergillus sp. has been investigated by stopped-flow kinetic studies using fructosyl propylamine and O(2) as substrates in 10 mM Tris HCl, pH 7.9, 4 degrees C. Using both substrate analogues and fast kinetic techniques, the active configuration of the substrate was found to be the beta-pyranose form. Stopped-flow studies showed that the reductive half-reaction is triphasic and generates intermediates that absorb at long wavelengths and is consistent either with (i) the reaction of the substrate with the flavin followed by iminium deprotonation or hydrolysis and then product release or with (ii) the formation of flavin reduction intermediates (carbanion equivalents or adducts), followed by product release. The rate of product release after flavin reduction is lower than the aerobic turnover rate, 14.4 s(-1), suggesting that it is not involved in the catalytic cycle and that reoxidation of the reduced enzyme occurs in the E(red)-product complex. In the oxidative half-reaction, the reduced flavin is oxidized by O(2) in a single phase. The observed rate constant has a linear dependence on oxygen concentration, giving a bimolecular rate constant of 4.9 x 10(4) M(-1) s(-1) in the absence of product, and 3.6 x 10(4) M(-1) s(-1) when the product is bound. The redox potentials of amadoriase have been measured at pH 7.0, 25 degrees, giving values of +48 and -52 mV for the oxidized enzyme/anionic semiquinone and anionic semiquinone/reduced enzyme couples, respectively.     

Poly(L-histidyl-L-alanyl-α-L-glutamic acid). I. Synthesis

Poly(L -histidyl-L -alanyl-α-L -glutamic acid) has been prepared in order to test the acid–base catalytic ability of a carboxyl-imidazole hydrogen-bonded system. Two different blocked histidyl-alanyl-glutamic acid monomers were used in the polymerization step. The imidazole ring was blocked with either a dinitrophenyl or a t-butyloxycarbonyl group. The γ-carboxyl of glutamic acid was protected as the benzyl ester. Both the coupling reactions and the polymerization step were via the N-hydroxysuccinimide active ester method. Thiolysis removed the dinitrophenyl group, while hydrogen bromide removed the t-butyloxycarbonyl and the benzyl groups. The water-soluble unblocked polymers obtained were fractionated on Sephadex G-50 or Bio-Gel P30. Fractions within a range of average molecular weights of 2,000 to 25,000 were isolated. Enzymatic oxidation of the acid hydrolyzate of the polymers revealed that no detectable racemization had occurred.     

I Siah substrate!

Proteins are targeted to the E3 RING ubiquitin ligase Siah through a PxAxVxP degron motif. In this issue of Structure, House et al. (2006) present the structural basis by which Siah recognizes its degron with high affinity and specificity.