Lesion specificity in the base excision repair enzyme hNeil1: modeling and dynamics studies

Base excision repair (BER) is the major pathway employed to excise oxidized DNA lesions. Human Neil1, a versatile glycosylase in the BER pathway, repairs a diverse array of oxidative lesions; however, the most prevalent, 8-oxo-7,8-dihydroguanine (8-oxoG), is only weakly excised. The structural origin of hNeil1's ability to repair a variety of lesions but not 8-oxoG is a model system for connecting enzyme structure and lesion-recognition specificity. To elucidate structural properties determining hNeil1's substrate specificities, we have investigated it in complex with two pairs of representative well-repaired substrates: the R- and S-spiroiminodihydantoin (Sp) stereoisomers, nonplanar further oxidation products of guanine, and the 5R,6S- and 5S,6R-thymine glycol (Tg) stereoisomers, the most prevalent oxidative lesions of thymine. We also investigate the poorly repaired 8-oxoG. We employed molecular modeling and 10 ns molecular dynamics (MD) simulations. The results of our investigations provide structural explanations for the ability of hNeil1 to excise a variety of oxidative lesions: they possess common chemical features, namely, a pyrimidine-like ring and shared hydrogen bond donor-acceptor properties, which allow the lesions to fit well in the binding pocket, which is somewhat flexible. However, the planar 8-oxoG is not as well accommodated in the shallow and comparatively cramped recognition pocket; it has fewer hydrogen bonding interactions with the enzyme and a solvent exposed six-membered ring, consistent with its poor repair susceptibility by this enzyme.     

Dextransucrase: studies on donor substrate specificity

Previous studies (D. S. Genghoff and E. J. Hehre, Proc. Soc. Exp. Biol. Med., 1972, 140, 1298–1301) have shown that an α-linked fluorine atom at C-1 of glucose provided sufficient activation to permit this analog to be a donor substrate for dextransucrase. In order to study the specificity at the donor substrate binding site, a series of α-1-fluorosugars have been synthesized. In kinetic experiments, it has been determined that they served as competitive inhibitors of sucrose, the natural substrate. A comparison of the K_i's provided information about the importance of specific changes in the glucose moiety with regard to binding to the enzyme. Similar kinetic studies were carried out with several β-1-fluorosugars, and the corresponding free monosaccharides. These were found to be noncompetitive inhibitors, and to bind poorly. The α-1-fluorosugars were also examined as donor substrates in reactions with known acceptors. With the exception of α-1-fluoroglucose, none of these analogs were active in this capacity.     

Substrate specificity of inner membrane peptidase in yeast mitochondria

The inner membrane protease (IMP) cleaves intra-organelle sorting peptides from precursor proteins in mitochondria of the yeast Saccharomyces cerevisiae. An unusual feature of the IMP is the presence of two catalytic subunits, Imp1p and Imp2p, which recognize distinct substrate sets even though both enzymes belong to the same protease family. This nonoverlapping substrate specificity was hypothesized to result from the recognition of distinct residues at the P′₁ position (also termed +1 position) in the protease substrates. Here, we constructed an extensive series of mutations to obtain a profile of the critical cleavage site residues in IMP substrates and conclude that Imp1p, and not Imp2p, recognizes specific P′₁ residues. In addition to its specificity for P′₁ residues, Imp1p also shows substrate specificity for the P₃ (−3) position. In contrast, Imp2p recognizes the P₁ (−1) position and the P₃ position. Based on this new understanding of IMP substrate specificity, we conducted a survey for candidate IMP substrates in mammalian mitochondria and found consensus Imp2p cleavage sites in mammalian precursors to cytochrome c₁ and glycerol-3-phosphate (G-3-P) dehydrogenase. Presence of a putative Imp2p cleavage site in G-3-P dehydrogenase was surprising, as its yeast ortholog contains an Imp1p cleavage site. To address this issue experimentally, we performed the first co-expression of mammalian IMP with proposed mammalian IMP precursors in yeast and show that murine precursors to cytochrome c₁ and G-3-P dehydrogenase are cleaved by murine Imp2p. These results suggest, surprisingly, G-3-P dehydrogenase has switched from Imp1p in yeast to Imp2p in mammals.     

反应介质对酶选择性的影响

有机相酶催化是酶工程研究最活跃的领域之一。本文主要综述了反应介质对酶底物选择性、酶对映体选择性、酶前手性选择性、酶区域选择性及酶基因选择性的影响。     

Glutamine transaminase from brain tissue. Further studies on kinetic properties and specificity of the enzyme.

Glutamine transaminase, highly purified from rat brain, was studied. In the first series of experiments, the kinetics of the transamination reaction between 2-oxoglutaramate and phenylalanine were examined in order to determine the type of reaction mechanism. This proved to be of the ping-pont type, as can be expected for a transamination. The specificity of the enzyme for various amino acids and 2-oxo acids was then studied in detail. The most active substrates were glutamine, methionine and ethionine as amino-group donors, and phenylpyruvate, glyoxalate and 2-oxo-4-methiobutyrate as amino-group acceptors. For these and several other substrates, the kinetic constants, V and Km, were determined.     

Crystalline enzyme kinetics: activity of the Streptomyces R61 D-alanyl-D-alanine peptidase.

The specificity constant, kcat/Km, for the hydrolysis of hippuryl-mercaptoacetate by crystals of the Streptomyces R61 D-D peptidase was measured by reaction of the thiol produced with 4,4'-dithiodipyridine. The values of kcat/Km for the crystal and in solution were the same (within experimental error). A novel method for treating the lag in the progress curves was developed.     

Redesigning the substrate specificity of an enzyme: isocitrate dehydrogenase

Despite the structural similarities between isocitrate and isopropylmalate, isocitrate dehydrogenase (IDH) exhibits a strong preference for its natural substrate. Using a combination of rational and random mutagenesis, we have engineered IDH to use isopropylmalate as a substrate. Rationally designed mutations were based on comparison of IDH to a similar enzyme, isopropylmalate dehydrogenase (IPMDH). A chimeric enzyme that replaced an active site loop-helix motif with IPMDH sequences exhibited no activity toward isopropylmalate, and site-directed mutants that replaced IDH residues with their IPMDH equivalents only showed small improvements in k(cat). Random mutants targeted the IDH active site at positions 113 (substituted with glutamate), 115, and 116 (both randomized) and were screened for activity toward isopropylmalate. Six mutants were identified that exhibited up to an 8-fold improvement in k(cat) and increased the apparent binding affinity by as much as a factor of 80. In addition to the S113E mutation, five other mutants contained substitutions at positions 115 and/or 116. Most small hydrophobic substitutions at position 116 improved activity, possibly by generating space to accommodate the isopropyl group of isopropylmalate; however, substitution with serine yielded the most improvement in k(cat). Only two substitutions were identified at position 115, which suggests a more specific role for the wild-type asparagine residue in the utilization of isopropylmalate. Since interactions between neighboring residues in this region greatly influenced the effects of each other in unexpected ways, structural solutions were best identified in combinations, as allowed by random mutagenesis.     

Parasite-host specificity: experimental studies on the basis of parasite adaptation

Specificity in parasitic interactions can be defined by host genotypes that are resistant to only a subset of parasite genotypes and parasite genotypes that are infective on a subset of host genotypes. It is not always clear if specificity is determined by the genotypes of the interactors, or if phenotypic plasticity (sometimes called acclimation) plays a larger role. Coevolutionary outcomes critically depend on the pervasiveness of genetic interactions. We studied specificity using the bacterial parasite Pasteuria ramosa and its crustacean host Daphnia magna. First, we tested for short-term adaptation of P. ramosa lines that had been rapidly shifted among different host genotypes. Adaptation at this time-scale would demonstrate the contribution of phenotypic plasticity to specificity. We found that infectivity was stable across lines irrespective of recent passage history, indicating that in the short term infection outcomes are fixed by genetic backgrounds. Second, we studied longer-term evolution with two host clones and two parasite lines. In this experiment, P. ramosa lines had the possibility to evolve adaptations to the host genotype (clone) in which they were serially passaged, which allowed us to test for a genetic component to specificity. Substantial differences arose in the two passaged lines: one parasite line gained infectivity on the host clone it was grown on, but it lost infectivity on the other host genotype (this line evolved specificity), while the other parasite line evolved higher infectivity on both host clones. We crossed the two host genotypes used in the serial passage experiment and found evidence that the number of host genes that underlies resistance variation is small. In sum, our results show that P. ramosa specificity is a stably inherited trait, it can evolve rapidly, and it is controlled by few genes in the host. These findings are consistent with the idea of a rapid, ongoing arms race between the bacterium and its host.     

Immunochemical studies on the specificity of soybean agglutinin

The specificity of the purified soybean agglutinin has been studied immunochemically by quantitative precipitin and quantitative precipitin inhibition assays. The lectin is precipitated by human A and Le^a blood-group substance, by the products of the second, third, fourth, and fifth stages of periodate oxidation of a human H blood-group substance (JS), and by precursor blood-group substances, as well as by a pig-submaxillary mucin having blood-group A activity, by partially hydrolyzed blood-group B substances (Pl fraction), and by group C streptococcal polysaccharide. The activity is attributable to terminal α-linked 2-acetamido-2-deoxy-d-galactopyranosyl or to α- or β-d-galactopyranosyl residues. The lectin did not precipitate with human blood-group H substances, with the product of the first stage of periodate oxidation (JS), with streptococcal group A polysaccharide, or with pig-submaxillary mucin devoid of blood-group A activity, and is poorly precipitated by blood-group B substances. Inhibition of precipitation with various monosaccharides indicated that the lectin is strongly specific for 2-acetamido-2-deoxy-d-galactose and for its oligosaccharides, and to a lesser extent for d-galactose and its oligosaccharides; the α-glycosides of both sugars were slightly more reactive than the β-glycosides of 2-acetamido-2-deoxy-d-galactose, and both α- and β-glycosides were more active than the free monosaccharides. Aromatic α- and β-glycosides of 2-acetamido-2-deoxy-d-galactose and d-galactose were better inhibitors than the corresponding methyl or ethyl compounds. The blood-group A trisaccharide α-d-GalNAcp-(1→3)-β-d-Galp-(1→3)-d-GlcNAc was more active than the disaccharide lectins by the use of precipitation with polysaccharides, as well as inhibition reactions, is essential to the understanding of their reactivity with cell-surface receptors.     

Factors governing nonoverlapping substrate specificity by mitochondrial inner membrane peptidase

At least three peptidases are involved in cleaving presequences from imported mitochondrial proteins. One of the peptidase, the inner membrane peptidase, has two catalytic subunits, Imp1p and Imp2p, which are structurally related but functionally distinct in the yeast Saccharomyces cerevisiae. Whereas both subunits are members of the type I signal peptidase family, they exhibit nonoverlapping substrate specificities. A clue to the substrate specificity mechanism has come from our discovery of the importance not only of the -1 and -3 residues in the signal peptides cleaved by Imp1p and Imp2p but also the +1 cargo residues attached to the signal peptides. We specifically find that Imp1p prefers substrates having a negatively charged residue (Asp or Glu) at the +1 position, whereas Imp2p prefers substrates having the Met residue at the +1 position. We further suggest that the conformation of the cargo is important for substrate recognition by Imp2p. A role for the cargo in presequence recognition distinguishes Imp1p and Imp2p from other type I signal peptidases.     

Human dipeptidyl peptidase III acts as a post-proline-cleaving enzyme on endomorphins

Dipeptidyl peptidase III (DPP III) is a zinc exopeptidase with an implied role in the mammalian pain-modulatory system owing to its high affinity for enkephalins and localisation in the superficial laminae of the spinal cord dorsal horn. Our study revealed that this human enzyme hydrolyses opioid peptides belonging to three new groups, endomorphins, hemorphins and exorphins. The enzymatic hydrolysis products of endomorphin-1 were separated and quantified by capillary electrophoresis and the kinetic parameters were determined for human DPP III and rat DPP IV. Both peptidases cleave endomorphin-1 at comparable rates, with liberation of the N-terminal Tyr-Pro. This is the first evidence of DPP III acting as an endomorphin-cleaving enzyme.