Secondary structure and side-chain 1H and 13C resonance assignments of calmodulin in solution by heteronuclear multidimensional NMR spectroscopy

Heteronuclear 2D and 3D NMR experiments were carried out on recombinant Drosophila calmodulin (CaM), a protein of 148 residues and with molecular mass of 16.7 kDa, that is uniformly labeled with 15N and 13C to a level of greater than 95%. Nearly complete 1H and 13C side-chain assignments for all amino acid residues are obtained by using the 3D HCCH-COSY and HCCH-TOCSY experiments that rely on large heteronuclear one-bond scalar couplings to transfer magnetization and establish through-bond connectivities. The secondary structure of this protein in solution has been elucidated by a qualitative interpretation of nuclear Overhauser effects, hydrogen exchange data, and 3JHNH alpha coupling constants. A clear correlation between the 13C alpha chemical shift and secondary structure is found. The secondary structure in the two globular domains of Drosophila CaM in solution is essentially identical with that of the X-ray crystal structure of mammalian CaM [Babu, Y., Bugg, C. E., & Cook, W.J. (1988) J. Mol. Biol. 204, 191-204], which consists of two pairs of a "helix-loop-helix" motif in each globular domain. The existence of a short antiparallel beta-sheet between the two loops in each domain has been confirmed. The eight alpha-helix segments identified from the NMR data are located at Glu-6 to Phe-19, Thr-29 to Ser-38, Glu-45 to Glu-54, Phe-65 to Lys-77, Glu-82 to Asp-93, Ala-102 to Asn-111, Asp-118 to Glu-127, and Tyr-138 to Thr-146. Although the crystal structure has a long "central helix" from Phe-65 to Phe-92 that connects the two globular domains, NMR data indicate that residues Asp-78 to Ser-81 of this central helix adopt a nonhelical conformation with considerable flexibility.     

Site-specific mutagenesis of lysine-204, tyrosine-224, tyrosine-228, and histidine-307 of porcine kidney D-amino acid oxidase and the implications as to its catalytic function

In order to evaluate the possible contributions of Lys-204, Tyr-224, Tyr-228, and His-307 in porcine kidney D-amino acid oxidase [EC 1.4.3.3] (DAO) to its catalytic function, we constructed four point mutant cDNAs encoding enzymes possessing Glu-204, Phe-224, Phe-228, and Leu-307 by oligonucleotide-directed in vitro mutagenesis. The four mutant cDNAs and the wild type cDNA could be expressed in vitro with similar efficiencies and about 200 ng of each enzyme protein was produced from 5 micrograms of the respective capped RNA. The electrophoretic mobilities of the in vitro synthesized mutant enzymes on SDS-polyacrylamide gel were almost identical with that of the wild type DAO, and the molecular weight was calculated to be 38,000. The Glu-204 and Phe-224 mutant DAOs showed comparable enzyme activities to that of the wild type enzyme, and were inhibited strongly by sodium benzoate, a potent competitive inhibitor of DAO. The kinetic parameters of the two mutant DAOs were also comparable to those of the wild type DAO. On the other hand, the Phe-228 and Leu-307 mutant DAOs showed no detectable activity. The results indicate that Tyr-228 and His-307 play important roles as to the constitution of the active site or participate in the reaction directly, while Lys-204 and Tyr-224 are not essential in the enzyme reaction.     

Structure of formamidopyrimidine-DNA glycosylase covalently complexed to DNA

Formamidopyrimidine-DNA glycosylase (Fpg) is a DNA repair enzyme that excises oxidized purines from damaged DNA. The Schiff base intermediate formed during this reaction between Escherichia coli Fpg and DNA was trapped by reduction with sodium borohydride, and the structure of the resulting covalently cross-linked complex was determined at a 2.1-A resolution. Fpg is a bilobal protein with a wide, positively charged DNA-binding groove. It possesses a conserved zinc finger and a helix-two turn-helix motif that participate in DNA binding. The absolutely conserved residues Lys-56, His-70, Asn-168, and Arg-258 form hydrogen bonds to the phosphodiester backbone of DNA, which is sharply kinked at the lesion site. Residues Met-73, Arg-109, and Phe-110 are inserted into the DNA helix, filling the void created by nucleotide eversion. A deep hydrophobic pocket in the active site is positioned to accommodate an everted base. Structural analysis of the Fpg-DNA complex reveals essential features of damage recognition and the catalytic mechanism of Fpg.     

Isolation of four novel tachykinins from frog (Rana catesbeiana) brain and intestine

In a survey for unknown bioactive peptides in frog (Rana catesbeiana) brain and intestine, we isolated four novel peptides that exhibit potent stimulant effects on smooth muscle preparation of guinea pig ileum. By microsequencing and synthesis, these peptides were identified as Lys- Pro- Ser- Pro- Asp- Arg- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin A), Tyr- Lys- Ser- Asp- Ser- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin B), His- Asn- Pro- Ala- Ser- Phe- Ile- Gly- Leu- Met- NH2 (ranatachykinin C) and Lys- Pro- Ans- Pro- Glu- Arg- Phe- Tyr- Ala- Pro- Met- NH2 (ranatachykinin D). Ranatachykinin (RTK) A, B and C conserve the C- terminal sequence, Phe- X- Gly- Leu- Met- NH2, which is common to known members of the tachykinin family. On the other hand, RTK-D has a striking feature in its C-terminal sequence, Phe- Tyr- Ala- Pro- Met- NH2, which has never been found in other known tachykinins, and may constitute a new subclass in the tachykinin family.     

Catalytic role for arginine 188 in the C-C hydrolase catalytic mechanism for Escherichia coli MhpC and Burkholderia xenovorans LB400 BphD

The alpha/beta-hydrolase superfamily, comprised mainly of esterase and lipase enzymes, contains a family of bacterial C-C hydrolases, including MhpC and BphD which catalyze the hydrolytic C-C cleavage of meta-ring fission intermediates on the Escherichia coli phenylpropionic acid pathway and Burkholderia xenovorans LB400 biphenyl degradation pathway, respectively. Five active site amino acid residues (Arg-188, Asn-109, Phe-173, Cys-261, and Trp-264) were identified from sequence alignments that are conserved in C-C hydrolases, but not in enzymes of different function. Replacement of Arg-188 in MhpC with Gln and Lys led to 200- and 40-fold decreases, respectively, in k(cat); the same replacements for Arg-190 of BphD led to 400- and 700-fold decreases, respectively, in k(cat). Pre-steady-state kinetic analysis of the R188Q MhpC mutant revealed that the first step of the reaction, keto-enol tautomerization, had become rate-limiting, indicating that Arg-188 has a catalytic role in ketonization of the dienol substrate, which we propose is via substrate destabilization. Mutation of nearby residues Phe-173 and Trp-264 to Gly gave 4-10-fold reductions in k(cat) but 10-20-fold increases in K(m), indicating that these residues are primarily involved in substrate binding. The X-ray structure of a succinate-H263A MhpC complex shows concerted movements in the positions of both Phe-173 and Trp-264 that line the approach to Arg-188. Mutation of Asn-109 to Ala and His yielded 200- and 350-fold reductions, respectively, in k(cat) and pre-steady-state kinetic behavior similar to that of a previous S110A mutant, indicating a role for Asn-109 is positioning the active site loop containing Ser-110. The catalytic role of Arg-188 is rationalized by a hydrogen bond network close to the C-1 carboxylate of the substrate, which positions the substrate and promotes substrate ketonization, probably via destabilization of the bound substrate.     

Structure-function analysis of the OB and latch domains of chlorella virus DNA ligase

Chlorella virus DNA ligase (ChVLig) is a minimized eukaryal ATP-dependent DNA sealing enzyme with an intrinsic nick-sensing function. ChVLig consists of three structural domains, nucleotidyltransferase (NTase), OB-fold, and latch, that envelop the nicked DNA as a C-shaped protein clamp. The OB domain engages the DNA minor groove on the face of the duplex behind the nick, and it makes contacts to amino acids in the NTase domain surrounding the ligase active site. The latch module occupies the DNA major groove flanking the nick. Residues at the tip of the latch contact the NTase domain to close the ligase clamp. Here we performed a structure-guided mutational analysis of the OB and latch domains. Alanine scanning defined seven individual amino acids as essential in vivo (Lys-274, Arg-285, Phe-286, and Val-288 in the OB domain; Asn-214, Phe-215, and Tyr-217 in the latch), after which structure-activity relations were clarified by conservative substitutions. Biochemical tests of the composite nick sealing reaction and of each of the three chemical steps of the ligation pathway highlighted the importance of Arg-285 and Phe-286 in the catalysis of the DNA adenylylation and phosphodiester synthesis reactions. Phe-286 interacts with the nick 5'-phosphate nucleotide and the 3'-OH base pair and distorts the DNA helical conformation at the nick. Arg-285 is a key component of the OB-NTase interface, where it forms a salt bridge to the essential Asp-29 side chain, which is imputed to coordinate divalent metal catalysts during the nick sealing steps.     

Beta-lactamase of Bacillus licheniformis 749/C at 2 A resolution

Two crystal forms (A and B) of the 29,500 Da Class A beta-lactamase (penicillinase) from Bacillus licheniformis 749/C have been examined crystallographically. The structure of B-form crystals has been solved to 2 A resolution, the starting model for which was a 3.5 A structure obtained from A-form crystals. The beta-lactamase has an alpha + beta structure with 11 helices and 5 beta-strands seen also in a penicillin target DD-peptidase of Streptomyces R61. Atomic parameters of the two molecules in the asymmetric unit were refined by simulated annealing at 2.0 A resolution. The R factor is 0.208 for the 27,330 data greater than 3 sigma (F), with water molecules excluded from the model. The catalytic Ser-70 is at the N-terminus of a helix and is within hydrogen bonding distance of conserved Lys-73. Also interacting with the Lys-73 are Asn-132 and the conserved Glu-166, which is on a potentially flexible helix-containing loop. The structure suggests the binding of beta-lactam substrates is facilitated by interactions with Lys-234, Thr-235, and Ala-237 in a conserved beta-strand peptide, which is antiparallel to the beta-lactam's acylamido linkage; an exposed cavity near Asn-170 exists for acylamido substituents. The reactive double bond of clavulanate-type inhibitors may interact with Arg-244 on the fourth beta-strand. A very similar binding site architecture is seen in the DD-peptidase.     

A structure-based mutational analysis of cyclophilin 40 identifies key residues in the core tetratricopeptide repeat domain that mediate binding to Hsp90

Cyclophilin 40 (CyP40) is a tetratricopeptide repeat (TPR)-containing immunophilin and a modulator of steroid receptor function through its binding to heat shock protein 90 (Hsp90). Critical to this binding are the carboxyl-terminal MEEVD motif of Hsp90 and the TPR domain of CyP40. Two different models of the CyP40-MEEVD peptide interaction were used as the basis for a comprehensive mutational analysis of the Hsp90-interacting domain of CyP40. Using a carboxyl-terminal CyP40 construct as template, 24 amino acids from the TPR and flanking acidic and basic domains were individually mutated by site-directed mutagenesis, and the mutants were coexpressed in yeast with a carboxyl-terminal Hsp90beta construct and qualitatively assessed for binding using a beta-galactosidase filter assay. For quantitative assessment, mutants were expressed as glutathione S-transferase fusion proteins and assayed for binding to carboxyl-terminal Hsp90beta using conventional pulldown and enzyme-linked immunosorbent assay microtiter plate assays. Collectively, the models predict that the following TPR residues help define a binding groove for the MEEVD peptide: Lys-227, Asn-231, Phe-234, Ser-274, Asn-278, Lys-308, and Arg-312. Mutational analysis identified five of these residues (Lys-227, Asn-231, Asn-278, Lys-308, and Arg-312) as essential for Hsp90 binding. The other two residues (Phe-234 and Ser-274) and another three TPR domain residues not definitively associated with the binding groove (Leu-284, Lys-285, and Asp-329) are required for efficient Hsp90 binding. These data confirm the critical importance of the MEEVD binding groove in CyP40 for Hsp90 recognition and reveal that additional charged and hydrophobic residues within the CyP40 TPR domain are required for Hsp90 binding.     

The transducer domain is important for clamp operation in human DNA topoisomerase IIalpha

DNA topoisomerase II is a multidomain homodimeric enzyme that changes DNA topology by coupling ATP hydrolysis to the transport of one DNA helix through a transient double-stranded break in another. The process requires dramatic conformational changes including closure of an ATP-operated clamp, which is comprised of two N-terminal domains from each protomer. The most N-terminal domain contains the ATP-binding site and is directly involved in clamp closure, undergoing dimerization upon ATP binding. The second domain, the transducer domain, forms the walls of the N-terminal clamp and connects the clamp to the enzyme core. Although structurally conserved, it is unclear whether the transducer domain is involved in clamp mechanism. We have purified and characterized a human topoisomerase II alpha enzyme with a two-amino acid insertion at position 408 in the transducer domain. The enzyme retains both ATPase and DNA cleavage activities. However, the insertion, which is situated far from the N-terminal dimerization area, severely disrupts the function of the N-terminal clamp. The clamp-deficient enzyme is catalytically inactive and lacks most aspects of interdomain communication. Surprisingly, it seems to have retained the intersubunit communication, allowing it to bind ATP cooperatively in the presence of DNA. The results show that even distal parts of the transducer domain are important for the dynamics of the N-terminal clamp and furthermore indicate that stable clamp closure is not required for cooperative binding of ATP.     

Residues involved in the catalysis,base specificity,and cytotoxicity of ribonuclease from Rana catesbeiana based upon mutagenesis and X-ray crystallography

The Rana catesbeiana (bullfrog) ribonucleases, which belong to the RNase A superfamily, exert cytotoxicity toward tumor cells. RC-RNase, the most active among frog ribonucleases, has a unique base preference for pyrimidine-guanine rather than pyrimidine-adenine in RNase A. Residues of RC-RNase involved in base specificity and catalytic activity were determined by site-directed mutagenesis, k(cat)/K(m) analysis toward dinucleotides, and cleavage site analysis of RNA substrate. The results show that Pyr-1 (N-terminal pyroglutamate), Lys-9, and Asn-38 along with His-10, Lys-35, and His-103 are involved in catalytic activity, whereas Pyr-1, Thr-39, Thr-70, Lys-95, and Glu-97 are involved in base specificity. The cytotoxicity of RC-RNase is correlated, but not proportional to, its catalytic activity. The crystal structure of the RC-RNase.d(ACGA) complex was determined at 1.80 A resolution. Residues Lys-9, His-10, Lys-35, and His-103 interacted directly with catalytic phosphate at the P(1) site, and Lys-9 was stabilized by hydrogen bonds contributed by Pyr-1, Tyr-28, and Asn-38. Thr-70 acts as a hydrogen bond donor for cytosine through Thr-39 and determines B(1) base specificity. Interestingly, Pyr-1 along with Lys-95 and Glu-97 form four hydrogen bonds with guanine at B(2) site and determine B(2) base specificity.     

Characterization of putative hydrophobic substrate binding site residues of a Delta class glutathione transferase from Anopheles dirus

To date, investigations of the hydrophobic substrate site of the insect Delta class glutathione transferase are limited in number. In the present study, putative hydrophobic site residues of AdGSTD4-4 have been proposed and characterized. These residues are Gln-112, Thr-174, Phe-212, Arg-214, Tyr-215 and Phe-216. It was found that Gln-112 does not contribute significantly to the catalytic properties of AdGSTD4-4. Arg-214, Tyr-215 and Phe-216 made contributions to catalytic properties and the rate-limiting step. Thr-174 and Phe-212 appeared to be important in enzymatic catalysis by stabilizing the active site β1-α1 loop on which the critical catalytic residue Ser-9 is located. The aromatic Phe-212 pi cloud appears to be important for interactions with its hydrophobic size representing an almost equally important factor. The data suggests that these residues are not directly involved in catalysis but exert their influence through secondary interactions. In addition, active site rearrangements occur to bring different residues into play even for conjugation through the same mechanisms. Therefore, due to the conformational rearrangements topologically equivalent residues observed in crystal structures may not perform equivalent roles in catalysis in different GST classes.     

Mutational analysis of bacteriophage T4 RNA ligase 1. Different functional groups are required for the nucleotidyl transfer and phosphodiester bond formation steps of the ligation reaction

T4 RNA ligase 1 (Rnl1) exemplifies an ATP-dependent RNA ligase family that includes fungal tRNA ligase (Trl1) and a putative baculovirus RNA ligase. Rnl1 acts via a covalent enzyme-AMP intermediate generated by attack of Lys-99 N zeta on the alpha phosphorus of ATP. Mutation of Lys-99 abolishes ligase activity. Here we tested the effects of alanine mutations at 19 conserved positions in Rnl1 and thereby identified 9 new residues essential for ligase activity: Arg-54, Lys-75, Phe-77, Gly-102, Lys-119, Glu-227, Gly-228, Lys-240, and Lys-242. Seven of the essential residues are located within counterparts of conserved nucleotidyltransferase motifs I (99KEDG102), Ia (118SK119), IV (227EGYVA231), and V (238HFKIK242) that comprise the active sites of DNA ligases, RNA capping enzymes, and T4 RNA ligase 2. Three other essential residues, Arg-54, Lys-75 and Phe-77, are located upstream of the AMP attachment site within a conserved domain unique to the Rnl1-like ligase family. We infer a shared evolutionary history and active site architecture in Rnl1 (a tRNA repair enzyme) and Trl1 (a tRNA splicing enzyme). We determined structure-activity relationships via conservative substitutions and examined mutational effects on the isolated steps of Rnl1 adenylylation (step 1) and phosphodiester bond formation (step 3). Lys-75, Lys-240, and Lys-242 were found to be essential for step 1 and overall ligation of 5'-phosphorylated RNA but not for phosphodiester bond formation. These results suggest that the composition of the Rnl1 active site is different during steps 1 and 3. Mutations at Arg-54 and Lys-119 abolished the overall RNA ligation reaction without affecting steps 1 and 3. Arg-54 and Lys-119 are thereby implicated as specific catalysts of the RNA adenylation reaction (step 2) of the ligation pathway.     

Site-directed alteration of four active-site residues of a pyruvoyl-dependent histidine decarboxylase

Site-directed mutagenesis has been used to examine the chemical roles of four active-site residues in histidine decarboxylase (HDC) from Lactobacillus 30a. This protein is known to undergo an autoactivation in which chain cleavage between serines-81 and -82 leads to cofactor (pyruvoyl) formation at position 82. Conversion of Ser-81 to Ala virtually eliminates productive cleavage. It is proposed that the residue plays a key role in stabilizing the transition state of the chain cleavage reaction. Conversion of Phe-83 to Met renders the proenzyme thermally less stable than wild type and appears to slightly increase the rate of autoactivation. The Km value for histidine is increased about 8-fold, confirming crystallographic evidence that Phe-83 is involved in substrate binding. Both wild-type and F83M enzymes show constant Km and steadily increasing kcat values as a function of temperature. Lys-155 and Tyr-262, by virtue of their positions in the active site of HDC, have been proposed to possibly play specific roles in either autoactivation or catalysis by active HDC. Conversion to Gln and Phe respectively suggests that these residues have real but minor roles in those processes.     

Structure of a complex between E. coli DNA topoisomerase I and single-stranded DNA

In order to gain insights into the mechaism of ssDNA binding and recognition by Escherichia coli DNA topoisomerase I, the structure of the 67 kDa N-terminal fragment of topoisomerase I was solved in complex with ssDNA. The structure reveals a new conformational stage in the multistep catalytic cycle of type IA topoisomerases. In the structure, the ssDNA binding groove leading to the active site is occupied, but the active site is not fully formed. Large conformational changes are not seen; instead, a single helix parallel to the ssDNA binding groove shifts to clamp the ssDNA. The structure helps clarify the temporal sequence of conformational events, starting from an initial empty enzyme and proceeding to a ssDNA-occupied and catalytically competent active site.     

Membrane topography of ColE1 gene products: the immunity protein.

The topography of the colicin E1 immunity (Imm) protein was determined from the positions of TnphoA and complementary lacZ fusions relative to the three long hydrophobic segments of the protein and site-directed substitution of charged for nonpolar residues in the proposed membrane-spanning segments. Inactivation of the Imm protein function required substitution and insertion of two such charges. It was concluded that the 113-residue colicin E1 Imm protein folds in the membrane as three trans-membrane alpha-helices, with the NH2 and COOH termini on the cytoplasmic and periplasmic sides of the membrane, respectively. The approximate spans of the three helices are Asn-9 to Ser-28, Ile-43 to Phe-62, and Leu-84 to Leu-104. An extrinsic highly charged segment, Lys-66 to Lys-74, containing seven charges in nine residues, extends into the cytoplasmic domain. The specificity of the colicin E1 Imm protein for interaction with the translocation apparatus and the colicin E1 ion channel is proposed to reside in its peripheral segments exposed on the surface of the inner membrane. These regions include the highly charged segment Lys-66 to Lys-83 (loop 2) and the short (approximately eight-residue) NH2 terminus on the cytoplasmic side, and Glu-29 to Val-44 (loop 1) and the COOH-terminal segment Gly-105 to Asn-113 on the periplasmic side.     

Flexibility at Gly-194 is required for DNA cleavage and relaxation activity of Escherichia coli DNA topoisomerase I

The proposed mechanism of type IA DNA topoisomerase I includes conformational changes by the single enzyme polypeptide to allow binding of the G strand of the DNA substrate at the active site, and the opening or closing of the "gate" created on the G strand of DNA to the passing single or double DNA strand(s) through the cleaved G strand DNA. The shifting of an alpha helix upon G strand DNA binding has been observed from the comparison of the type IA DNA topoisomerase crystal structures. Site-directed mutagenesis of the strictly conserved Gly-194 at the N terminus of this alpha helix in Escherichia coli DNA topoisomerase I showed that flexibility around this glycine residue is required for DNA cleavage and relaxation activity and supports a functional role for this hinge region in the enzyme conformational change.     

Identification of simian virus 40 T-antigen residues important for specific and nonspecific binding to DNA and for helicase activity.

We have previously identified three regions (called elements) in the DNA-binding domain of simian virus 40 large tumor (T) antigen which are critical for binding of the protein to the recognition pentanucleotides GAGGC at the viral replication origin. These are elements A (residues 147 to 159), B1 (185 to 187), and B2 (203 to 207). In this study, we generated mutants of simian virus 40 in order to make single-point substitution mutations at nearly every site in these three elements. Each mutation was tested for its effect on virus replication, and T antigen was produced from all replication-negative mutants. The mutant proteins were assayed for binding to several different DNA substrates and for helicase activity. We found that within each element, mutations at some sites had major effects on DNA binding while mutations at other sites had moderate, mild, or minimal effects, suggesting that some residues are more important than others in mediating DNA binding. Furthermore, we provide evidence that certain residues in elements A and B2 (Ala-149, Phe-159, and His-203) participate in nonspecific double-stranded and helicase substrate (single-stranded) DNA binding while others (Ser-147, Ser-152, Asn-153, Thr-155, Arg-204, Val-205, and Ala-207) are involved in sequence-specific binding at the origin. The residues in element B1 (primarily Ser-185 and His-187) take part only in nonspecific DNA binding. The amino acids important for nonspecific DNA binding are also required for helicase activity, and we hypothesize that they make contact with the sugar-phosphate backbone of DNA. On the other hand, those involved in sequence-specific binding are not needed for helicase activity. Finally, our analysis showed that three residues (Asn-153 and Thr-155 in element A and Arg-204 in element B2) may be the most important for sequence-specific binding. They are likely to make direct or indirect contacts with the pentanucleotide sequences at the origin.     

Mutational analysis of duck delta 2 crystallin and the structure of an inactive mutant with bound substrate provide insight into the enzymatic mechanism of argininosuccinate lyase.

The major soluble avian eye lens protein, delta crystallin, is highly homologous to the housekeeping enzyme argininosuccinate lyase (ASL). ASL is part of the urea and arginine-citrulline cycles and catalyzes the reversible breakdown of argininosuccinate to arginine and fumarate. In duck lenses, there are two delta crystallin isoforms that are 94% identical in amino acid sequence. Only the delta2 isoform has maintained ASL activity and has been used to investigate the enzymatic mechanism of ASL. The role of the active site residues Ser-29, Asp-33, Asp-89, Asn-116, Thr-161, His-162, Arg-238, Thr-281, Ser-283, Asn-291, Asp-293, Glu-296, Lys-325, Asp-330, and Lys-331 have been investigated by site-directed mutagenesis, and the structure of the inactive duck delta2 crystallin (ddeltac2) mutant S283A with bound argininosuccinate was determined at 1.96 A resolution. The S283A mutation does not interfere with substrate binding, because the 280's loop (residues 270-290) is in the open conformation and Ala-283 is more than 7 A from the substrate. The substrate is bound in a different conformation to that observed previously indicating a large degree of conformational flexibility in the fumarate moiety when the 280's loop is in the open conformation. The structure of the S283A ddeltac2 mutant and mutagenesis results reveal that a complex network of interactions of both protein residues and water molecules are involved in substrate binding and specificity. Small changes even to residues not involved directly in anchoring the argininosuccinate have a significant effect on catalysis. The results suggest that either His-162 or Thr-161 are responsible for proton abstraction and reinforce the putative role of Ser-283 as the catalytic acid, although we cannot eliminate the possibility that arginine is released in an uncharged form, with the solvent providing the required proton. A detailed enzymatic mechanism of ASL/ddeltac2 is presented.     

Functional dissection of the DNA interface of the nucleotidyltransferase domain of chlorella virus DNA ligase

Chlorella virus DNA ligase (ChVLig) has pluripotent biological activity and an intrinsic nick-sensing function. ChVLig consists of three structural modules that envelop nicked DNA as a C-shaped protein clamp: a nucleotidyltransferase (NTase) domain and an OB domain (these two are common to all DNA ligases) as well as a distinctive β-hairpin latch module. The NTase domain, which performs the chemical steps of ligation, binds the major groove flanking the nick and the minor groove on the 3'-OH side of the nick. Here we performed a structure-guided mutational analysis of the NTase domain, surveying the effects of 35 mutations in 19 residues on ChVLig activity in vivo and in vitro, including biochemical tests of the composite nick sealing reaction and of the three component steps of the ligation pathway (ligase adenylylation, DNA adenylylation, and phosphodiester synthesis). The results highlight (i) key contacts by Thr-84 and Lys-173 to the template DNA strand phosphates at the outer margins of the DNA ligase footprint; (ii) essential contacts of Ser-41, Arg-42, Met-83, and Phe-75 with the 3'-OH strand at the nick; (iii) Arg-176 phosphate contacts at the nick and with ATP during ligase adenylylation; (iv) the role of Phe-44 in forming the protein clamp around the nicked DNA substrate; and (v) the importance of adenine-binding residue Phe-98 in all three steps of ligation. Kinetic analysis of single-turnover nick sealing by ChVLig-AMP underscored the importance of Phe-75-mediated distortion of the nick 3'-OH nucleoside in the catalysis of DNA 5'-adenylylation (step 2) and phosphodiester synthesis (step 3). Induced fit of the nicked DNA into a distorted conformation when bound within the ligase clamp may account for the nick-sensing capacity of ChVLig.     

Reaction of 1-amino-2-methylenecyclopropane-1-carboxylate with 1-aminocyclopropane-1-carboxylate deaminase: analysis and mechanistic implications

1-aminocyclopropane-1-carboxylate (ACC) deaminase is a pyridoxal 5'-phosphate (PLP) dependent enzyme which catalyzes the opening of the cyclopropane ring of ACC to give alpha-ketobutyric acid and ammonia. In an early study of this unusual C(alpha)-C(beta) ring cleavage reaction, 1-amino-2-methylenecyclopropane-1-carboxylic acid (2-methylene-ACC) was shown to be an irreversible inhibitor of ACC deaminase. The sole turnover product was identified as 3-methyl-2-oxobutenoic acid. These results provided strong evidence supporting the ring cleavage of ACC via a nucleophilic addition initiated process, thus establishing an unprecedented mechanism of coenzyme B(6) dependent catalysis. To gain further insight into this inactivation, tritiated 2-methylene-ACC was prepared and used to trap the critical enzyme nucleophiles. Our results revealed that inactivation resulted in the modification of an active site residue, Ser-78. However, an additional 5 equiv of inhibitor was also found to be incorporated into the inactivated enzyme after prolonged incubation. In addition to Ser-78, other nucleophilic residues modified include Lys-26, Cys-41, Cys-162, and Lys-245. The location of the remaining unidentified nucleophile has been narrowed down to be one of the residues between 150 and 180. Labeling at sites outside of the active site is not enzyme catalyzed and may be a consequence of the inherent reactivity of 2-methylene-ACC. Further experiments showed that Ser-78 is responsible for abstracting the alpha-H from d-vinylglycine and may serve as the base to remove the beta-H in the catalysis of ACC. However, it is also likely that Ser-78 serves as the active site nucleophile that attacks the cyclopropane ring and initiates the fragmentation of ACC, while the conserved Lys-51 is the base required for beta-H abstraction. Clearly, the cleavage of ACC to alpha-ketobutyrate by ACC deaminase represents an intriguing conversion beyond the common scope entailed by coenzyme B(6) dependent catalysts.