Directed evolution of N-carbamyl-D-amino acid amidohydrolase for simultaneous improvement of oxidative and thermal stability

Directed evolution of N-carbamyl-D-amino acid amidohydrolase from Agrobacterium tumefaciens NRRL B11291 was attempted in order to simultaneously improve oxidative and thermal stability. A mutant library was generated by DNA shuffling, and positive clones with improved oxidative and thermal stability were screened on the basis of the activity staining method on a solid agar plate containing pH indicator (phenol red) and substrate (N-carbamyl-D-p-hydroxyphenylglycine). Two rounds of directed evolution resulted in the best mutant 2S3 with a significantly improved stability. Oxidative stability of the evolved enzyme 2S3 was about 18-fold higher than that of the wild type, and it also showed an 8-fold increased thermostability. The K(m) value of 2S3 was comparable to that of wild-type enzyme, but k(cat) was slightly decreased. DNA sequence analysis revealed that six amino acid residues (Q23L, V40A, H58Y, G75S, M184L, and T262A) were substituted in 2S3. From the mutational analysis, four mutations (Q23L, H58Y, M184L, and T262A) were found to lead to an improvement of both oxidative and thermal stability. Of them, T262A had the most significant effect, and V40A and G75S only increased the oxidative stability.     

In vitro evolution of beta-glucuronidase into a beta-galactosidase proceeds through non-specific intermediates

The Escherichia coli beta-glucuronidase (GUS) was evolved in vitro to catalyze the hydrolysis of a beta-galactoside substrate 500 times more efficiently (k(cat)/K(m)) than the wild-type, with a 52 million-fold inversion in specificity. The amino acid substitutions that recurred among 32 clones isolated in three rounds of DNA shuffling and screening were mapped to the active site. The functional consequences of these mutations were investigated by introducing them individually or in combination into otherwise wild-type gusA genes. The kinetic behavior of the purified mutant proteins in reactions with a series of substrate analogues show that four mutations account for the changes in substrate specificity, and that they are synergistic. An evolutionary intermediate, unlike the wild-type and evolved forms, exhibits broadened specificity for substrates dissimilar to either glucuronides or galactosides. These results are consistent with the "patchwork" hypothesis, which postulates that modern enzymes diverged from ancestors with broad specificity.     

Directed evolution of alpha-aspartyl dipeptidase from Salmonella typhimurium.

Model-free approaches (error-prone PCR to introduce random mutations, DNA shuffling to combine positive mutations, and screening of the resultant mutant libraries) have been used to enhance the catalytic activity and thermostability of alpha-aspartyl dipeptidase from Salmonella typhimurium, which is uniquely able to hydrolyze Asp-X dipeptides (where X is any amino acid) and one tripeptide (Asp-Gly-Gly). Under double selective pressures of activity and thermostability, through two rounds of error-prone PCR and three sequential generations of DNA shuffling, coupled with screening, a mutant pepEM3074 with approximately 47-fold increased enzyme activity compared with its wild-type parent was obtained. Moreover, the stability of pepEM3074 is increased significantly. Three amino acid substitutions (Asn89His, Gln153Glu, and Leu205Arg), two of them are near the active site and substrate binding pocket, were identified by sequencing the genes encoding this evolved enzyme. The mechanism of the enhancement of activity and stability was analyzed in this paper.     

How does an enzyme evolved in vitro compare to naturally occurring homologs possessing the targeted function? Tyrosine aminotransferase from aspartate aminotransferase

Aspartate aminotransferase (AATase) and tyrosine aminotransferase (TATase) are Escherichia coli paralogs that share 43% sequence identity. A plausible model posits that TATase arose from a duplication of an ancestral AATase-like enzyme. Directed evolution of AATase to an enzyme having TATase activity was undertaken in order to compare the evolved AATase variants with homologous TATases. Eight rounds of DNA shuffling and in vivo selection followed by a backcross with WT AATase produced enzymes that exhibited 100-270-fold increases in k(cat)/K(m)(Phe) and had as much as 11% of the tyrosine aminotransferase activity of WT E.coli TATase. Amino acid substitutions in 11 clones from rounds 7 and 8 were compared with conserved residues in AATases and TATases. The findings are conveniently and compactly illustrated by the use of Venn diagrams and set theory notation. A statistically significant (0.001or=75% identical) in AATases and variable (<75% identical) in TATases. Very few mutations occur in the intersection (set AAT intersection TAT) of amino acid residues that are conserved in both enzyme types. Seven mutations from set AAT-TAT were combined by site-directed mutagenesis to give a construct that is 60% as active as the best round 8 enzyme, which has 13 amino acid replacements. The Venn diagrams may provide a generally useful tool to highlight the most important specificity determinants for rational redesign. Amino acid replacements were mapped onto the crystal structure of a hydrocinnamate complex of a designed TATase. Five of the seven positions most frequently substituted in the evolved clones are within 15 A of the phenyl side-chain, but only six of the 48 positions that were mutated once or twice are within that radius. Context dependence, neutral mutations, different selective pressures, and stochastic components provide explanations for the observation that many of the substitutions found in the directly evolved enzymes differ from the corresponding amino acids found in the modern natural TATases.     

Family Shuffling of Expandase Genes To Enhance Substrate Specificity for Penicillin G

Deacetoxycephalosporin C synthase (expandase) from Streptomyces clavuligerus, encoded by cefE, is an important industrial enzyme for the production of 7-aminodeacetoxycephalosporanic acid from penicillin G. To improve the substrate specificity for penicillin G, eight cefE-homologous genes were directly evolved by using the DNA shuffling technique. After the first round of shuffling and screening, using an Escherichia coli ESS bioassay, four chimeras with higher activity were subjected to a second round. Subsequently, 20 clones were found with significantly enhanced activity. The kinetic parameters of two isolates that lack substrate inhibition showed 8.5- and 118-fold increases in the k_cat/K_m ratio compared to the S. clavuligerus expandase. The evolved enzyme with the 118-fold increase is the most active obtained to date anywhere. Our shuffling results also indicate the remarkable plasticity of the expandase, suggesting that more-active chimeras might be achievable with further rounds.     

Enhancement of the enzymatic activity of ribonuclease HI from Thermus thermophilus HB8 with a suppressor mutation method

A genetic method for isolating a mutant enzyme of ribonuclease HI (RNase HI) from Thermus thermophilus HB8 with enhanced activity at moderate temperatures was developed. T. thermophilus RNase HI has an ability to complement the RNase H-dependent temperature-sensitive (ts) growth phenotype of Escherichia coli MIC3001. However, this complementation ability was greatly reduced by replacing Asp(134), which is one of the active site residues, with His, probably due to a reduction in the catalytic activity. Random mutagenesis of the gene encoding the resultant D134H enzyme, followed by screening for second-site revertants, allowed us to isolate three single mutations (Ala(12) --> Ser, Lys(75) --> Met, and Ala(77) --> Pro) that restore the normal complementation ability to the D134H enzyme. These mutations were individually or simultaneously introduced into the wild-type enzyme, and the kinetic parameters of the resultant mutant enzymes for the hydrolysis of a DNA-RNA-DNA/DNA substrate were determined at 30 degrees C. Each mutation increased the k(cat)/K(m) value of the wild-type enzyme by 2.1-4.8-fold. The effects of the mutations on the enzymatic activity were roughly cumulative, and the combination of these three mutations increased the k(cat)/K(m) value of the wild-type enzyme by 40-fold (5.5-fold in k(cat)). Measurement of thermal stability of the mutant enzymes with circular dichroism spectroscopy in the presence of 1 M guanidine hydrochloride and 1 mM dithiothreitol showed that the T(m) value of the triple mutant enzyme, in which all three mutations were combined, was comparable to that of the wild-type enzyme (75.0 vs 77.4 degrees C). These results demonstrate that the activity of a thermophilic enzyme can be improved without a cost of protein stability.     

Site-saturation mutagenesis is more efficient than DNA shuffling for the directed evolution of beta-fucosidase from beta-galactosidase

Protein engineers use a variety of mutagenic strategies to adapt enzymes to novel substrates. Directed evolution techniques (random mutagenesis and high-throughput screening) offer a systematic approach to the management of protein complexity. This sub-discipline was galvanized by the invention of DNA shuffling, a procedure that randomly recombines point mutations in vitro. In one influential study, Escherichia coli beta-galactosidase (BGAL) variants with enhanced beta-fucosidase activity (tenfold increase in k(cat)/K(M) in reactions with the novel para-nitrophenyl-beta-d-fucopyranoside substrate; 39-fold decrease in reactivity with the "native"para-nitrophenyl-beta-d-galactopyranoside substrate) were evolved in seven rounds of DNA shuffling and screening. Here, we show that a single round of site-saturation mutagenesis and screening enabled the identification of beta-fucosidases that are significantly more active (180-fold increase in k(cat)/K(M) in reactions with the novel substrate) and specific (700,000-fold inversion of specificity) than the best variants in the previous study. Site-saturation mutagenesis thus proved faster, less resource-intensive and more effective than DNA shuffling for this particular evolutionary pathway.     

Directed Evolution of E. coli Alkaline Phosphatase Towards Higher Catalytic Activity

Directed evolution was used to enhance the catalytic activity of E. coli alkaline phosphatase (EAP). Through two rounds of error-prone PCR and one round of DNA shuffling followed by a rapid, sensitive screening procedure, several improved variants were obtained. Their enzymatic kinetic properties, thermal stabilities and possible mechanism for the improvement were investigated. In 1.0 M Tris buffer, the specific activity of the most active EAP variant S2163 was 1500 units/mg protein, showing it to be 3.6 times more active than the D101S parent enzyme and ∼40 times more active than the wild-type EAP. At the same time, the K_m value of the S2163 variant decreased to 1491 μM from the 2384 μM of the D101S. As a result, the k_cat/K_m ratio of this variant showed a 5.8-fold enhancement over that of D101S parent enzyme. Three activating amino acid substitutions, K167R, G180S and S374C, which were located far away from the center of the catalytic pocket, were identified by sequencing the genes encoding evolved enzymes. Possible explanations for the improvement of activity were analyzed.     

Simultaneous optimization of enzyme activity and quaternary structure by directed evolution

Natural evolution has produced efficient enzymes of enormous structural diversity. We imitated this natural process in the laboratory to augment the efficiency of an engineered chorismate mutase with low activity and an unusual hexameric topology. By applying two rounds of DNA shuffling and genetic selection, we obtained a 400-fold more efficient enzyme, containing three non-active-site mutations. Detailed biophysical characterization of the evolved variant suggests that it exists predominantly as a trimer in solution, but is otherwise similarly stable as the parent hexamer. The dramatic structural and functional effects achieved by a small number of seemingly innocuous substitutions highlights the utility of directed evolution for modifying protein-protein interactions to produce novel quaternary states with optimized activities.     

Identification of amino acid residues involved in 4-chloroindole 3-hydroxylation by cytochrome P450 2A6 using screening of random libraries

Cytochrome P450 (P450) 2A6 is able to catalyze indole hydroxylation to form the blue dye indigo. The wild-type P450 2A6 enzyme was randomly mutated throughout the whole open reading frame and screened using 4-chloroindole hydroxylation, a substituted indole selected from 30 indole compounds for enhanced color development. Mutants with up to 5-fold increases of catalytic efficiency (k(cat)/K(m)) and 2-fold increases in k(cat) were selected after two rounds of screening. Important residues located both in (e.g., Thr305) and outside the active site (e.g., Ser224) were identified. The study utilized a better substrate for "indigo assay" to obtain new information on the structure-functional relationship of P450 2A6 that was not revealed by previous mutagenesis studies with this enzyme.     

Water activity and substrate concentration effects on lipase activity

Catalytic activity of lipases (from Rhizopus arrhizus, Canadida rugosa, and Pseudomonas sp. was studied in organic media, mainly diisopropyl ether. The effect of water activity (a(w)) on V(max) showed that the enzyme activity in general increased with increasing amounts of water for the three enzymes. This was shown both for esterification and hydrolysis reactions catalyzed by R. arrhizus lipase. In the esterification reaction the K(m) for the acid substrate showed a slight increase with increasing water activities. On the other hand, the K(m) for the alcohol substrate increased 10-20-fold with increasing water activity. The relative changes in K(m) were shown to be independent of the enzyme studied and solvent used. The effect was attributed to the increasing competition of water as a nucleophile for the acyl-enzyme at higher water activities. In a hydrolysis reaction the K(m) for the ester was also shown to increase as the water activity increased. The effect of water in this case was due to the fact that increased concentration of one substrate (water), and thereby increased saturation of the enzyme, will increase the apparent K(m) of the substrate (ester) to be determined. This explained why the hydrolysis rate decreased with increasing water activity at a fixed, low ester concentration. The apparent V(max) for R. arrhizus lipase was similar in four of six different solvents that were tested; exceptions were toulene and trichloroethylene, which showed lower values. The apparent K(m) for the alcohol in the solvents correlated with the hydrophobicity of the solvent, hydrophobic solvents giving lower apparent K(m). (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 55: 798-806, 1997.     

Making an Oriental equivalent of the yeast cytosolic aldehyde dehydrogenase as well as making one with positive cooperativity in coenzyme binding by mutations of glutamate 492 and arginine 480

Yeast has at least three partially characterized aldehyde dehydrogenases. Previous studies by gene disrupted in our laboratory revealed that the Saccharomyces cerevisiae cytosol ALDH1 played an important role in ethanol metabolism as did the class 2 mitochondrial enzyme. To date, few mutagenesis studies have been performed with the yeast enzymes. An important human variant of ALDH is one found in Asian People. In it, the glutamate at position 487 is replaced by a lysine. This glutamate interacts with an arginine (475) that is located in the subunit that makes up the dimer pair in the tetrameric enzyme. Sequence alignment shows that these two residues are located at positions 492 and 480, respectively, in the yeast class 1 enzyme which shares just 45% sequence identity with the human enzymes. Mutating glutamate 492 to lysine produced an enzyme with altered kinetic properties when compared to the wild-type glutamate-enzyme. The K(m) for NADP of E492K increased to nearly 3600 microM compare to 40 microM for wild-type enzyme. The specific activity decreased more than 10-fold with respect to the recombinant wild-type yeast enzyme. Moreover, substituting a glutamine for a glutamate was not detrimental in that the E492Q had wild-type-like K(m) for NADP and V(max). These properties were similar to the changes found with the human class 2 E487K mutant form. Further, mutating arginine 480 to glutamine produced an enzyme that exhibited positive cooperativity in NADP binding. The K(m) for NADP increased 11-fold with a Hill coefficient of 1.6. The NADP-dependent activity of R480Q mutant was 60% of wild-type enzyme. Again, these results are very similar to what we recently showed to occur with the human enzyme [Biochemistry 39 (2000) 5295-5302]. These findings show that the even though the glutamate and arginine residues are not conserved, similar changes occur in both the human and the yeast enzyme when either is mutated.     

抗脐带间充质干细胞表面分子噬菌体ScFv抗体库的构建及初步鉴定

目的：利用噬菌体展示技术构建抗脐带间充质干细胞表面分子噬菌体ScFv抗体库。方法：收集P3代培养的UC-MSCs免疫BALB/c小鼠,提取其脾细胞总RNA,RT-PCR扩增全套VH和VL基因片段,将其先后克隆入噬菌粒pSEX81中,构建成完整的噬菌体ScFv抗体库。结果:构建的噬菌体ScFv抗体库的库容为2×107cfu,ScFv插入重组率为93％,BstN1酶切图谱呈不同多样性。ScFv抗体库经3轮初步筛选后插入重组率达100％,3个克隆出现了相同的酶切图谱,并且随着筛选次数的增加,输出/输入比明显提高,这说明抗体库得到了特异性富集。结论：成功地构建了抗脐带间充质干细胞表面分子噬菌体ScFv抗体库,这为将来筛选特异性抗体和进一步用于间充质干细胞表面特异性分子研究奠定了坚实的基础。     

Enhancement of the activity and alkaline pH stability of <Emphasis Type="Italic">Thermobifida fusca</Emphasis> xylanase A by directed evolution

Directed evolution has been used to enhance the catalytic activity and alkaline pH stability of Thermobifida fusca xylanase A, which is one of the most thermostable xylanases. Under triple screened traits of activity, alkaline pH stability and thermostability, through two rounds of random mutagenesis using DNA shuffling, a mutant 2TfxA98 with approximately 12-fold increased k _cat/K _m and 4.5-fold decreased K _m compared with its parent was obtained. Moreover, the alkaline pH stability of 2TfxA98 is increased significantly, with a thermostability slightly lower than that of its parent. Five amino acid substitutions (T21A, G25P, V87P, I91T, and G217L), three of them are near the catalytic active site, were identified by sequencing the genes encoding this evolved enzyme. The activity and stabilizing effects of each amino acid mutation in the evolved enzyme were evaluated by site-directed mutagenesis. This study shows a useful approach to improve the catalytic activity and alkaline pH stability of T. fusca xylanase A toward the hydrolysis of xylan.     

大肠杆菌碱性磷酸酶的体外定向进化研究

大肠杆菌碱性磷酸酶（E.coli alkaline phosphatase, EAP, EC 3.1.3.1）是一个非特异性二聚体磷酸单酯酶. 采用易错聚合酶链反应(error prone PCR)的方法,在原有高活力突变株的基础上,对EAP远离活性中心催化三联体的区域进行定向进化,经两轮error prone PCR,获得催化活力较亲本D101S突变株提高3倍、较野生型酶提高35倍的进化酶4-186,并对该酶的催化动力学特征进行了分析. 进化酶基因的DNA测序表明4-186含两个有义氨基酸置换：K167R和S374C,二者既不位于底物结合位点,也不位于酶的金属离子结合位点.     

Recombinant human DNA (cytosine-5) methyltransferase. I. Expression, purification, and comparison of de novo and maintenance methylation.

A method is described to express and purify human DNA (cytosine-5) methyltransferase (human DNMT1) using a protein splicing (intein) fusion partner in a baculovirus expression vector. The system produces approximately 1 mg of intact recombinant enzyme >95% pure per 1.5 x 10(9) insect cells. The protein lacks any affinity tag and is identical to the native enzyme except for the two C-terminal amino acids, proline and glycine, that were substituted for lysine and aspartic acid for optimal cleavage from the intein affinity tag. Human DNMT1 was used for steady-state kinetic analysis with poly(dI-dC).poly(dI-dC) and unmethylated and hemimethylated 36- and 75-mer oligonucleotides. The turnover number (k(cat)) was 131-237 h(-1) on poly(dI-dC).poly(dI-dC), 1.2-2.3 h(-1) on unmethylated DNA, and 8.3-49 h(-1) on hemimethylated DNA. The Michaelis constants for DNA (K(m)(CG)) and S-adenosyl-L-methionine (AdoMet) (K(m)(AdoMet)) ranged from 0.33-1.32 and 2.6-7.2 microM, respectively, whereas the ratio of k(cat)/K(m)(CG) ranged from 3.9 to 44 (237-336 for poly(dI-dC).poly(dI-dC)) x 10(6) M(-1) h(-1). The preference of the enzyme for hemimethylated, over unmethylated, DNA was 7-21-fold. The values of k(cat) on hemimethylated DNAs showed a 2-3-fold difference, depending upon which strand was pre-methylated. Furthermore, human DNMT1 formed covalent complexes with substrates containing 5-fluoro-CNG, indicating that substrate specificity extended beyond the canonical CG dinucleotide. These results show that, in addition to maintenance methylation, human DNMT1 may also carry out de novo and non-CG methyltransferase activities in vivo.     

Insight into the coupling mechanism of the vitamin K-dependent carboxylase: mutation of histidine 160 disrupts glutamic acid carbanion formation and efficient coupling of vitamin K epoxidation to glutamic acid carboxylation

Vitamin K-dependent (VKD) proteins become activated by the VKD carboxylase, which converts Glu's to carboxylated Glu's (Gla's) in their Gla domains. The carboxylase uses vitamin K epoxidation to drive Glu carboxylation, and the two half-reactions are coupled in 1:1 stoichiometry by an unknown mechanism. We now report the first identification of a residue, His160, required for coupling. A H160A mutant showed wild-type levels of epoxidation but substantially less carboxylation. Monitoring proton abstraction using a peptide with Glu tritiated at the gamma-carbon position revealed that poor coupling was due to impaired carbanion formation. H160A showed a 10-fold lower ratio of tritium release to vitamin K epoxidation than wild-type enzyme (i.e., 0.12 versus 1.14, respectively), which could fully account for the fold decrease in coupling efficiency. The Ala substitution in His160 did not affect the K m for vitamin K and caused only a 2-fold increase in the K m for Glu and 2-fold decrease in the activation of vitamin K epoxidation by Glu. The H160A K m for CO 2 was 5-fold higher than the wild-type enzyme. However, the k cat for H160A carboxylation was 8-9-fold lower than the wild-type enzyme with all three substrates (i.e., Glu, CO 2, and vitamin K), suggesting a catalytic role for His160 in carbanion formation. We propose that His160 facilitates the formation of the transition state for carbanion formation. His160 is highly conserved in metazoan VKD carboxylases but not in some bacterial orthologues (acquired by horizontal gene transfer), which has implications for how bacteria have adapted the carboxylase for novel functions.     

Directed Evolution of E. coli Alkaline Phosphatase Towards Higher Catalytic Activity

Directed evolution was used to enhance the catalytic activity of E. coli alkaline phosphatase (EAP). Through two rounds of error-prone PCR and one round of DNA shuffling followed by a rapid, sensitive screening procedure, several improved variants were obtained. Their enzymatic kinetic properties, thermal stabilities and possible mechanism for the improvement were investigated. In 1.0 M Tris buffer, the specific activity of the most active EAP variant S2163 was 1500 units/mg protein, showing it to be 3.6 times more active than the D101S parent enzyme and ～40 times more active than the wild-type EAP. At the same time, the K_m value of the S2163 variant decreased to 1491 μM from the 2384 μM of the D101S. As a result, the k_cat/K_m ratio of this variant showed a 5.8-fold enhancement over that of D101S parent enzyme. Three activating amino acid substitutions, K167R, G180S and S374C, which were located far away from the center of the catalytic pocket, were identified by sequencing the genes encoding evolved enzymes. Possible explanations for the improvement of activity were analyzed.     

Simultaneous purification and characterization of cytochrome b5 reductase and cytochrome b5 from sheep liver

Cytochrome b5 was purified from detergent solubilized sheep liver microsomes by using three successive DEAE-cellulose, and Sephadex G-100 column chromatographies. It was purified 54-fold and the yield was 23.5% with respect to microsomes. The apparent Mr of cytochrome b5 was estimated to be 16,200 +/- 500 by SDS-PAGE. Absolute absorption spectrum of the purified cytochrome b5 showed maximal absorption at 412 nm and dithionite-reduced cytochrome b5 gave peaks at 557, 526.5 and 423 nm. The ability of the purified sheep liver cytochrome b5 to transfer electrons from NADH-cytochrome b5 reductase to cytochrome c was investigated. The K(m) and Vmax values were calculated to be 0.088 microM cytochrome b5 and 315.8 microM cytochrome c reduced/min/mg enzyme, respectively. Also the reduction of cytochrome b5 by reductase was studied and K(m) and Vmax values were determined to be 5 microM cytochrome b5 and 5200 nmol cytochrome b5 reduced/min/mg enzyme, respectively. The K(m) and Vmax values for the cofactor NADH in the presence of saturating concentration of cytochrome b5 were found to be 0.0017 mM NADH and 6944 nmol cytochrome b5 reduced/min/mg enzyme, respectively. NADH-cytochrome b5 reductase was also partially purified from the same source, detergent solubilized sheep liver microsomes, by using two successive DEAE-cellulose, and 5'-ADP-agarose affinity column chromatographies. It was purified 144-fold and the yield was 7% with respect to microsomes. The apparent monomer Mr of reductase was estimated to be 34,000 by SDS-PAGE. When ferricyanide was used as an electron acceptor, reductase showed maximum activity between 6.8 and 7.5. The K(m) and Vmax values of the enzyme for ferricyanide were calculated as 0.024 mM ferricyanide and 673 mumol ferricyanide reduced/min/mg enzyme, respectively. The K(m) and Vmax values for the cofactor NADH in the presence of saturating amounts of ferricyanide were found to be 0.020 mM NADH and 699 mumol ferricyanide reduced/min/mg enzyme, respectively.     

Involvement of conserved aspartate and glutamate residues in the catalysis and substrate binding of maize starch synthase

Chemical modification of maize starch synthase IIb-2 (SSIIb-2) using 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDAC), which modifies acidic amino acid residues, resulted in a time- and concentration-dependent inactivation of SSIIb-2. ADPGlc was found to completely protect SSIIb-2 from inactivation by EDAC. These results suggest that glutamate or aspartate is important for SS activity. On the basis of the sequence identity of SS, conserved acidic amino acids were mutagenized to identify the specific amino acid residues important for SS activity. Three amino acids (D21, D139, and E391) were found to be important for SS activity. D21N showed 4% of the wild-type enzyme activity and a 10-fold decrease in the affinity for ADPGlc, while the conservative change from D21 to E resulted in a decrease in V(max) and no change in affinity for ADPGlc, suggesting that the negative charge is important for ADPGlc binding. When sites D139 and E391 were changed to their respective amide form, no SS activity was detected. With the conservative change, D139E showed a decrease in V(max) and no changes in apparent K(m) for substrates. E391D showed a 9-fold increase in K(m) for ADPGlc, a 12-fold increase in apparent K(m) for glycogen, and a 4-fold increase in apparent K(m) for amylopectin. The circular dichroism analysis indicates that these kinetic changes may not be due to a major conformation change in the protein. These results provide the first evidence that the conserved aspartate and glutamate residues could be involved in the catalysis or substrate binding of SS.