Amino acid racemase with broad substrate specificity,its properties and use in phenylalanine racemization

Summary Broad substrate specificity amino acid racemase (EC 5.1.1.10) was purified from a crude extract of Pseudomonas putida SCRC-744 to near homogeneity. The enzyme has an isoelectric point of 7.6 and a molecular weight of 62,000–65,000. The enzyme showed a broad substrate specificity toward amino acids, utilizing d-glutamine as the best substrate. d-Phenylalanine acted as a substrate to 1% the velocity for d-glutamine. Maximal reaction velocities were observed at 50°–60°C and around pH 8. The apparent K_m values for d-glutamine and d-phenylalanine were 7.8 mM and 25.7 mM, respectively. Both enantiomers of phenylalanine were efficiently racemized by acetone-dried cells of P. putida SCRC-744.     

Evolution of amino acid biosynthesis and enzymes with broad substrate specificity.

I selected 82 proteins that were related to amino acid biosynthesis in the genome of Escherichia coli. I then searched the extensive sequence homology for each of the selected proteins from among the proteins of E.coli. The result showed that 30 proteins of the selected proteins had extensive sequence homology within the selected proteins, and 21 proteins had extensive sequence homology to proteins outside the selected proteins. In addition, the enzymes with broad substrate specificity play an important role in the amino acid biosynthesis. I demonstrate here that some substrate-specific enzymes evolved from an ancestor enzyme with broad substrate specificity. CONTACT: hnishida@iam.u-tokyo.ac.jp     

Prediction of amino acid residues participated in substrate recognition by cytochrome P450 subfamilies with broad substrate specificity

Cytochromes P450 comprise a large superfamily and several of their isoforms play a crucial role in metabolism of xenobiotics, including drugs. Although these enzymes demonstrate broad and cross‐substrate specificity, different cytochrome P450 subfamilies exhibit certain selectivity for some types of substrates. Analysis of amino acid residues of the active sites of six cytochrome subfamilies (CYP1А, CYP2А, CYP2С, CYP2D, CYP2E and CYP3А) enables to define subfamily‐specific patterns that consist of four residues. These residues are located on the periphery of the active sites of these cytochromes. We suggest that they can form a primary binding site at the entrance to the active site, defining cytochrome substrate recognition. Copyright © 2013 John Wiley & Sons, Ltd.     

Structural basis for catalytic racemization and substrate specificity of an N-acylamino acid racemase homologue from Deinococcus radiodurans

N-acylamino acid racemase (NAAAR) catalyzes the racemization of N-acylamino acids and can be used in concert with an aminoacylase to produce enantiopure alpha-amino acids, a process that has potential industrial applications. Here we have cloned and characterized an NAAAR homologue from a radiation-resistant ancient bacterium, Deinococcus radiodurans. The expressed NAAAR racemized various substrates at an optimal temperature of 60 degrees C and had Km values of 24.8 mM and 12.3 mM for N-acetyl-D-methionine and N-acetyl-L-methionine, respectively. The crystal structure of NAAAR was solved to 1.3 A resolution using multiwavelength anomalous dispersion (MAD) methods. The structure consists of a homooctamer in which each subunit has an architecture characteristic of enolases with a capping domain and a (beta/alpha)7 beta barrel domain. The NAAAR.Mg2+ and NAAAR.N-acetyl-L-glutamine.Mg2+ structures were also determined, allowing us to define the Lys170-Asp195-Glu220-Asp245-Lys269 framework for catalyzing 1,1-proton exchange of N-acylamino acids. Four subsites enclosing the substrate are identified: catalytic site, metal-binding site, side-chain-binding region, and a flexible lid region. The high conservation of catalytic and metal-binding sites in different enolases reflects the essentiality of a common catalytic platform, allowing these enzymes to robustly abstract alpha-protons of various carboxylate substrates efficiently. The other subsites involved in substrate recognition are less conserved, suggesting that divergent evolution has led to functionally distinct enzymes.     

Reaction mechanism of glutamate racemase, a pyridoxal phosphate-independent amino acid racemase.

Glutamate racemase of Pediococcus pentosaceus contained no cofactor, and was completely inactivated by a thiol reagent. The role of a cysteine residue in the enzyme reaction was studied by chemical modification. The modification of this cysteine residue resulted in a concomitant loss of activity. DL-Glutamate protected the enzyme from inactivation. The inactivated enzyme was reactivated by addition of dithiothreitol. The racemization in 2H2O showed an overshoot in the optical rotation of glutamate before the substrate was completely racemized. This indicates that the removal of alpha-hydrogen is the rate determining step. During the racemization of D- or L-glutamate in 3H2O, tritium was incorporated preferentially into the product. Glutamate is racemized by the enzyme probably through a two base mechanism.     

Properties of aspartate racemase, a pyridoxal 5'-phosphate-independent amino acid racemase.

Aspartate racemase from Streptococcus thermophilus contains no pyridoxal 5'-phosphate or other cofactors such as FAD, NAD+, and metal ions. It was affected by neither carbonyl reagents such as hydroxylamine nor sodium borohydride but was strongly inhibited by iodoacetamide and other thiol reagents. Aspartate, cysteate, and cysteine sulfinate were the only substrates. The Km values for L- and D-aspartate were 35 and 8.7 mM, respectively. The enzyme catalyzed the exchange of alpha-hydrogen of the substrate with the solvent hydrogen. Racemization of L-aspartate in 2H2O showed an overshooting in the optical rotation of aspartate before the substrate was fully racemized. This shows that the removal of alpha-hydrogen of the substrate is at least partially rate-determining. When L- or D-aspartate was incubated with aspartate racemase in tritiated water, tritium was incorporated preferentially into the product enantiomer. The results strongly suggest that aspartate racemase contains two hydrogen acceptors.     

Differential expression of two related amino acid transporters with differing substrate specificity in Arabidopsis thaliana

A general amino acid permease cDNA ( AAP2 ) was isolated from Arabidopsis by complementation of a yeast mutant defective in citrulline uptake. Direct transport measurements in yeast show that the protein mediates uptake of l -[¹⁴C]-citrulline and l -[¹⁴C]-proline. Detailed analyses of the substrate specificity by competition studies demonstrate that all proteogenic amino acids are recognized by the carrier, including those that represent the major transport forms of reduced nitrogen in many species, i.e. glutamine, glutamate and asparagine. Thus, AAP2 is less selective as compared with AAP1 and transports basic amino acids such as histidine as shown by expression in a histidine transport-deficient yeast strain. The predicted polypeptide of 53 kDa is highly hydrophobic with 12 putative membrane-spanning regions and shows significant homologies to the Arabidopsis broad specificity permease AAP1, and a limited homology to bacterial branched chain amino acid transporters, but not to any other known proteins. Alterations in the charged residues as compared with AAP1 in four regions might be involved in the difference in selectivity towards basic amino acids. Both genes are highly expressed in developing pods indicating a role in supplying the developing seeds with reduced nitrogen. AAP2 is selectively expressed in the stem and might therefore play a role in xylem-to-phloem transfer of amino acids during seed filling. Furthermore in situ hybridization shows that both genes are expressed in the vascular system of cotyledons in developing seedlings.     

Molecular mechanism of substrate specificity in the bacterial neutral amino acid transporter LeuT

The recently published X-ray structure of LeuT, a Na(+)/Cl(-)-dependent neurotransmitter transporter, has provided fresh impetus to efforts directed at understanding the molecular principles governing specific neurotransmitter transport. The combination of the LeuT crystal structure with the results of molecular simulations enables the functional data on specific binding and transport to be related to molecular structure. All-atom FEP and molecular dynamics (MD) simulations of LeuT embedded in an explicit membrane were performed alongside a decomposition analysis to dissect the molecular determinants of the substrate specificity of LeuT. It was found that the ligand must be in a zwitterionic (ZW) form to bind tightly to the transporter. The theoretical results on the absolute binding-free energies for leucine, alanine, and glycine show that alanine can be a potent substrate for LeuT, although leucine is preferred, which is consistent with the recent experimental data (Singh et al., Nature 2007;448:952-956). Furthermore, LeuT displays robust specificity for leucine over glycine. Interestingly, the ability of LeuT to discriminate between substrates relies on the dynamics of residues that form its binding pocket (e.g., F253 and Q250) and the charged side chains (R30-D404) from a second coordination shell. The water-mediated R30-D404 salt bridge is thought to be part of the extracellular (EC) gate of LeuT. The introduction of a polar ligand such as glycine to the water-depleted binding pocket of LeuT gives rise to structural rearrangements of the R30-D404-Q250 hydrogen-bonding network and leads to increased hydration of the binding pocket. Conformational changes associated with the broken hydrogen bond between Q250 and R30 are shown to be important for tight and selective ligand binding to LeuT.     

Two amino acid residues determine the low substrate affinity of human cationic amino acid transporter-2A

Mammalian cationic amino acid transporters (CAT) differ in their substrate affinity and sensitivity to trans-stimulation. The apparent Km values for cationic amino acids and the sensitivity to trans-stimulation of CAT-1, -2B, and -3 are characteristic of system y+. In contrast, CAT-2A exhibits a 10-fold lower substrate affinity and is largely independent of substrate at the trans-side of the membrane. CAT-2A and -2B demonstrate such divergent transport properties, even though their amino acid sequences differ only in a stretch of 42 amino acids. Here, we identify two amino acid residues within this 42-amino acid domain of the human CAT-2A protein that are responsible for the apparent low affinity of both the extracellular and intracellular substrate-binding sites. These residues are located in the fourth intracellular loop, suggesting that they are not part of the translocation pathway. Rather, they may be responsible for the low affinity conformation of the substrate-binding sites. The sensitivity to trans-stimulation is not determined by the same amino acid residues as the substrate affinity and must involve a more complex interaction between individual amino acid residues. In addition to the 42-amino acid domain, the adjacent transmembrane domain X seems to be involved in this function.     

Modulation of substrate specificity within the amino acid editing site of leucyl-tRNA synthetase

The aminoacyl-tRNA synthetases covalently link transfer RNAs to their cognate amino acids. Some of the tRNA synthetases have evolved editing mechanisms to ensure fidelity in this first step of protein synthesis. The amino acid editing site for leucyl- (LeuRS) and isoleucyl- (IleRS) tRNA synthetases reside within homologous CP1 domains. In each case, a threonine-rich peptide and a second conserved GTG region that are separated by about 100 amino acids comprise parts of the hydrolytic editing site. While a number of sites are conserved between these two enzymes and likely confer a commonality to the mechanisms, some positions are idiosyncratic to LeuRS or IleRS. Herein, we provide evidence that a conserved arginine and threonine at respective sites in LeuRS and IleRS diverged to confer amino acid substrate recognition. This site complements other sites in the amino acid binding pocket of the editing active site of Escherichia coli LeuRS, including Thr252 and Val338, which collectively fine-tune amino acid specificity to confer fidelity.     

Modulating substrate specificity of histone acetyltransferase with unnatural amino acids

Controlling the substrate specificity of enzymes is a major challenge for protein engineers. Here we explore the effects of residue-specific incorporation of ortho-, meta- and para-fluorophenylalanine (oFF, mFF, pFF) on the selectivity of human histone acetyltransferase (HAT) protein, p300/CBP associated factor (PCAF). Varying the position of the fluorine group in the phenylalanine ring confers different effects on the ability of PCAF to acetylate target histone H3 as well as non-histone p53. Surprisingly, pFF-PCAF exhibits an increase in activity for non-histone p53, while mFF-PCAF is selective for histone H3. These results suggest that global incorporation of unnatural amino acids may be used to re-engineer protein specificity.     

腾冲嗜热厌氧菌丙氨酸消旋酶底物通道氨基酸位点的功能

【目的】通过定点突变探究腾冲嗜热厌氧菌MB4中生物合成型丙氨酸消旋酶Tt Alr底物通道内氨基酸位点A172和S173的功能。【方法】利用定点突变PCR技术构建突变体,通过亲和层析法纯化酶蛋白,采用D-氨基酸氧化酶偶联法检测各突变蛋白的活性及其稳定性。【结果】通过定点突变PCR成功得到8个突变体,酶学特性分析发现,A172位点突变为丝氨酸(S)后酶蛋白的相对活性有所提升,但含有该位点突变的酶蛋白稳定性均大幅下降;S173位点突变为天门冬氨酸(D)后导致突变体蛋白的最适反应温度提升了15°C,半衰期大幅延长,但相对活性明显下降。【结论】丙氨酸消旋酶Tt Alr底物通道内A172和S173位点均是影响酶蛋白催化活性和稳定性的关键位点。     

A single amino acid substitution affects substrate specificity in cysteine proteinases from Fasciola hepatica

The trematode Fasciola hepatica secretes a number of cathepsin L-like proteases that are proposed to be involved in feeding, migration, and immune evasion by the parasite. To date, six full cDNA sequences encoding cathepsin L preproproteins have been identified. Previous studies have demonstrated that one of these cathepsins (L2) is unusual in that it is able to cleave substrates with a proline in the P2 position, translating into an unusual ability (for a cysteine proteinase) to clot fibrinogen. In this study, we report the sequence of a novel cathepsin (L5) and compare the substrate specificity of a recombinant enzyme with that of recombinant cathepsin L2. Despite sharing 80% sequence identity with cathepsin L2, cathepsin L5 does not exhibit substantial catalytic activity against substrates containing proline in the P2 position. Molecular modeling studies suggested that a single amino acid change (L69Y) in the mature proteinases may account for the difference in specificity at the S2 subsite. Recombinant cathepsin L5/L69Y was expressed in yeast and a substantial increase in the ability of this variant to accommodate substrates with a proline residue in the P2 position was observed. Thus, we have identified a single amino acid substitution that can substantially influence the architecture of the S2 subsite of F. hepatica cathepsin L proteases.     

Identification of the amino acid residues conferring substrate specificity upon Selenomonas ruminantium lysine decarboxylase

Lysine decarboxylase (LDC, EC 4.1.1.18) from Selenomonas ruminantium has decarboxylating activities towards both L-lysine and L-ornithine with similar K(m) and Vmax. Here, we identified four amino acid residues that confer substrate specificity upon S. ruminantium LDC and that are located in its catalytic domain. We have succeeded in converting S. ruminantium LDC to an enzyme with a preference in decarboxylating activity for L-ornithine when the four-residue of LDC were replaced by the corresponding residues of mouse ornithine decarboxylase (EC 4.1.1.17).     

Modified substrate specificity of pyrroloquinoline quinone glucose dehydrogenase by biased mutation assembling with optimized amino acid substitution

A biased mutation-assembling method—that is, a directed evolution strategy to facilitate an optimal accumulation of multiple mutations on the basis of additivity principles, was applied to the directed evolution of water-soluble PQQ glucose dehydrogenase (PQQGDH-B) to reduce its maltose oxidation activity, which can lead to errors in blood glucose determination. Mutations appropriate for the reduction without fatal deterioration of its glucose oxidation activity were developed by an error-prone PCR method coupled with a saturation mutagenesis method. Moreover, two types of incorporation frequency based on their contribution were assigned to the mutations: high (80%) and evens (50%), in constructing a multiple mutant library. The best mutant created showed a marked reduction in maltose oxidation activity, corresponding to 4% of that of the wild-type enzyme, with 35% retention of glucose oxidation activity. In addition, this mutant showed a reduction in galactose oxidation activity corresponding to 5% of that of the wild-type enzyme. In conclusion, we succeeded in developing the PQQGDH-B mutants with improved substrate specificity and validated our method coupled with optimized mutations and their contribution-based incorporation frequencies by applying it to the development.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Fatty acid amide hydrolase substrate specificity

Fatty acid amide hydrolase (FAAH), also referred to as oleamide hydrolase and anandamide amidohydrolase, is a serine hydrolase responsible for the degradation of endogenous oleamide and anandamide, fatty acid amides that function as chemical messengers. FAAH hydrolyzes a range of fatty acid amides, and the present study examines the relative rates of hydrolysis of a variety of natural and unnatural fatty acid primary amide substrates using pure recombinant rat FAAH.     

Alteration of a single amino acid changes the substrate specificity of dihydroflavonol 4-reductase

Many plant species exhibit a reduced range of flower colors due to the lack of an essential gene or to the substrate specificity of a biosynthetic enzyme. Petunia does not produce orange flowers because dihydroflavonol 4-reductase (DFR) from this species, an enzyme involved in anthocyanin biosynthesis, inefficiently reduces dihydrokaempferol, the precursor to orange pelargonidin-type anthocyanins. The substrate specificity of DFR, however, has not been investigated at the molecular level. By analyzing chimeric DFRs of Petunia and Gerbera, we identified a region that determines the substrate specificity of DFR. Furthermore, by changing a single amino acid in this presumed substrate-binding region, we developed a DFR enzyme that preferentially reduces dihydrokaempferol. Our results imply that the substrate specificity of DFR can be altered by minor changes in DFR.     

Identification of amino acid substitutions that alter the substrate specificity of TEM-1 beta-lactamase.

TEM-1 beta-lactamase is the most prevalent plasmid-mediated beta-lactamase in gram-negative bacteria. Recently, TEM beta-lactamase variants with amino acid substitutions in the active-site pocket of the enzyme have been identified in natural isolates with increased resistance to extended-spectrum cephalosporins. To identify other amino acid substitutions that alter the activity of TEM-1 towards extended-spectrum cephalosporins, we probed regions around the active-site pocket by random-replacement mutagenesis. This mutagenesis technique involves randomizing the DNA sequence of three to six codons in the blaTEM-1 gene to form a library containing all or nearly all of the possible substitutions for the region randomized. In total, 20 different residue positions that had been randomized were screened for amino acid substitutions that increased enzyme activity towards the extended-spectrum cephalosporin cefotaxime. Substitutions at positions 104, 168, and 238 in the TEM-1 beta-lactamase that resulted in increased enzyme activity towards extended-spectrum cephalosporins were found. In addition, small deletions in the loop containing residues 166 to 170 drastically altered the substrate specificity of the enzyme by increasing activity towards extended-spectrum cephalosporins while virtually eliminating activity towards ampicillin.