Conversion of serine-114 to cysteine-114 and the role of the active site nucleophile in acyl transfer by myristoyl-ACP thioesterase from Vibrio harveyi

The lux-specific myristoyl-ACP thioesterase (LuxD) is responsible for diverting myristic acid into the luminescent system and can function as an esterase and transferase as well as cleave myristoyl-CoA and other thioesters. The recently elucidated crystal structure of the enzyme shows that it belongs to the alpha/beta hydrolase family and that it contains a typical catalytic triad composed of Asp211, His241, and Ser114. What is unusual is that the nucleophilic S114 is not contained within the esterase consensus motif GXSXG although the stereochemistry of the turn involving S114 is almost identical to the nucleophilic elbow found in alpha/beta hydrolases. In contrast to mammalian thioesterases, deacylation of LuxD was the rate-limiting step, with the level of acylated enzyme formed on reaction with myristoyl-CoA and the pre-steady-state burst of p-nitrophenol on cleavage of p-nitrophenyl myristate both being 0.7 mol/mol. Cold chase experiments showed that the deacylation rate of LuxD corresponded closely to the turnover rate of the enzyme with ester or thioester substrates. Replacement of S114 by a cysteine residue generated a mutant (S114C) that was acylated with the same pH dependence as LuxD but had greatly diminished capacity to transfer acyl groups to water or glycerol. The acyl group could be removed from the S114C mutant by neutral hydroxylamine, showing that a cysteine residue had been acylated. Mutation of H241 creating the double mutant, S114C.H241N, decreased acylation of the cysteine residue. These results provide direct kinetic and chemical evidence that S114 is the site of acylation linked to H241 in the charge relay system and have led to the recognition of a more general consensus motif flanking the nucleophilic serine in thioesterases.

The occurrence of C-H...O hydrogen bonds in proteins

Hydrogen bonds are a major feature of protein structure. By a generally accepted definition, they occur whenever a proton is shared by two electronegative atoms. Hence, only hydrogens bonded to nitrogen and oxygen atoms are usually considered in analyses of protein hydrogen bond networks. However, X-ray and neutron diffraction studies have shown that crystals of various organic compounds exhibit close C-H...X contacts (where X is an electronegative atom, in most cases oxygen) which show all the stereochemical hallmarks of hydrogen bonds. In this work, we describe an analysis of short C-H...O interactions in a sample of known protein structures representing different categories of tertiary folds and refined at a resolution of at least 2 A. Although our analysis is based on the calculated coordinates of hydrogen atoms, its results are statistically significant: we find strong evidence that a large percentage of short C...O contacts constitute cohesive interactions. Moreover, the stereochemical study of C-H...O = C contacts, in which the orientation of free electron orbitals on the acceptor oxygen atom can be predicted, reveals that these interactions exhibit stereochemical features typical of hydrogen bonds. Among the hydrogen atoms involved in these contacts, the most common are those bonded to alpha carbon. This is consistent with the fact that these hydrogens are more acidic than others. We describe four different categories of C-H...O = C bonds. Those found between C alpha-H groups and main chain oxygens in adjacent strands of beta sheets are the most ubiquitous. Our results call for a revision of crystallographic restrained refinement programs which treat close carbon-oxygen contacts as purely repulsive; they may also have implications for the understanding of some enzymatic reaction mechanisms.

The Escherichia coli malonyl-CoA:acyl carrier protein transacylase at 1.5-A resolution. Crystal structure of a fatty acid synthase component

Endogenous fatty acids are synthesized in all organisms in a pathway catalyzed by the fatty acid synthase complex. In bacteria, where the fatty acids are used primarily for incorporation into components of cell membranes, fatty acid synthase is made up of several independent cytoplasmic enzymes, each catalyzing one specific reaction. The initiation of the elongation step, which extends the length of the growing acyl chain by two carbons, requires the transfer of the malonyl moiety from malonyl-CoA onto the acyl carrier protein. We report here the crystal structure (refined at 1.5-A resolution to an R factor of 0.19) of the malonyl-CoA specific transferase from Escherichia coli. The protein has an alpha/beta type architecture, but its fold is unique. The active site inferred from the location of the catalytic Ser-92 contains a typical nucleophilic elbow as observed in alpha/beta hydrolases. Serine 92 is hydrogen bonded to His-201 in a fashion similar to various serine hydrolases. However, instead of a carboxyl acid typically found in catalytic triads, the main chain carbonyl of Gln-250 serves as a hydrogen bond acceptor in an interaction with His-201. Two other residues, Arg-117 and Glu-11, are also located in the active site, although their function is not clear.

A twist in the tale of lipolytic enzymes

Structural studies of phospholipase A2 in the presence of micelles, and investigations into molecular properties of lipids indicate that the mechanism of interfacial activation of lipolytic enzymes may be far more complex than presently supposed at present.

A novel variant of the catalytic triad in the Streptomyces scabies esterase

The crystal structure of a novel esterase from Streptomyces scabies, a causal agent of the potato scab disease, was solved at 2.1 A resolution. The tertiary fold of the enzyme is substantially different from that of the alpha/beta hydrolase family and unique among all known hydrolases. The active site contains a dyad of Ser 14 and His 283, closely resembling two of the three components of typical Ser-His-Asp(Glu) triads from other serine hydrolases. Proper orientation of the active site imidazol is maintained by a hydrogen bond between the N delta-H group and a main chain oxygen. Thus, the enzyme constitutes the first known natural variation of the chymotrypsin-like triad in which a carboxylic acid is replaced by a neutral hydrogen-bond acceptor.

Crystallization of the malonyl coenzyme A-acyl carrier protein transacylase from Escherichia coli

The malonyl coenzyme A-acyl carrier protein transacylase, a single polypeptide chain of 358 amino acid residues and a molecular mass of 32 kDa, is a key component of the fatty acid synthase multienzyme complex. The elucidation of its three-dimensional structure will help in the understanding of the molecular basis of the biosynthesis of fatty acids, as well as of polyketides and related biologically active molecules. Three X-ray-quality crystal forms of the Escherichia coli fabD gene product encoding for malonyl coenzyme A-acyl carrier protein transacylase have been obtained using the hanging-drop method and ammonium sulfate as precipitant. Two are tetragonal and each contains two molecules in the asymmetric unit (form I: space group P4(3(1))2(1)2 with a = b = 83.9 A, c = 166.5 A and form II: space group P4 with a = b = 132.64 A, c = 38.85 A), whereas the third form belongs to the hexagonal system and contains one molecule in the asymmetric unit (space group P6(1(5)) with a = b = 68.52 A, c = 117.71 A). In each case, the diffraction pattern extends to approximately 2.0 A resolution using CuK alpha radiation from a rotating anode source.

Crystal structure, at 2.6-A resolution, of the Streptomyces lividans xylanase A, a member of the F family of beta-1,4-D-glycanases

The crystal structure of the 32-kDa catalytic domain of the Streptomyces lividans xylanase A was solved by molecular isomorphous replacement methods and subsequently refined at 2.6-A resolution to a conventional crystallographic R factor of 0.21. This is the first successful structure determination of a member of the F family of endo-beta-1,4-D-glycanases. Unlike the recently determined xylanases of the G family (Wakarchuk, W. W., Campbell, R. L., Sung, W. L., Davoodi, J., and Yaguchi, M. (1994) Protein Sci. 3, 467-475), where the catalytic domains have a unique beta-sheet structure, the 32-kDa domain of the S. lividans xylanase A is folded into a complete (alpha/beta)8 barrel, the first such fold observed among beta-1,4-D-glycanases. The active site is located at the carbonyl end of the beta barrel. The crystal structure supports the earlier assignment of Glu-128 and Glu-236 as the catalytic amino acids (Moreau, A., Roberge, M., Manin, C., Shareck, F., Kluepfel, D., and Morosoli, R. (1994) Biochem. J., in press).

Structure of a myristoyl-ACP-specific thioesterase from Vibrio harveyi

The crystal structure of a myristoyl acyl carrier protein specific thioesterase (C14ACP-TE) from a bioluminescent bacterium, Vibrio harveyi, was solved by multiple isomorphous replacement methods and refined to an R factor of 22% at 2.1-A resolution. This is the first elucidation of a three-dimensional structure of a thioesterase. The overall tertiary architecture of the enzyme resembles closely the consensus fold of the rapidly expanding superfamily of alpha/beta hydrolases, although there is no detectable homology with any of its members at the amino acid sequence level. Particularly striking similarity exists between the C14ACP-TE structure and that of haloalkane dehalogenase from Xanthobacter autotrophicus. Contrary to the conclusions of earlier studies [Ferri, S. R., & Meighen, E. A. (1991) J. Biol. Chem. 266, 12852-12857] which implicated Ser77 in catalysis, the crystal structure of C14ACP-TE reveals a lipase-like catalytic triad made up of Ser114, His241, and Asp211. Surprisingly, the gamma-turn with Ser114 in a strained secondary conformation (phi = 53 degrees, psi = -127 degrees), characteristic of the so-called nucleophilic elbow, does not conform to the frequently invoked lipase/esterase consensus sequence (Gly-X-Ser-X-Gly), as the positions of both glycines are occupied by larger amino acids. Site-directed mutagenesis and radioactive labeling support the catalytic function of Ser114. Crystallographic analysis of the Ser77-->Gly mutant at 2.5-A resolution revealed no structural changes; in both cases the loop containing the residue in position 77 is disordered.(ABSTRACT TRUNCATED AT 250 WORDS)

(His)C epsilon-H...O=C < hydrogen bond in the active sites of serine hydrolases

Close interactions of the C-H...O type are known to occur in a variety of organic crystals, although it had been often argued that they do not represent true hydrogen bonds. During an extensive comparative study of all structurally characterized serine hydrolases containing an Asp(Glu)-His-Ser catalytic triad at their active centers (i.e. serine proteinases, lipases, acetylcholinesterase and a thioesterase), we have discovered that the C epsilon 1 atom of the active site histidine is invariably in a close contact with a carbonyl oxygen. The stereochemistry of these contacts suggests a cohesive, predominantly electrostatic interaction, fully consistent with the requirements imposed by the generally accepted definition of a hydrogen bond. A study of a sample of protein structures refined at high resolution revealed that similar hydrogen bonds involving (His) C epsilon 1-H are found in approximately 15% of non-active site histidine residues. The ubiquitous occurrence of this hitherto underestimated contact in the active sites of serine hydrolases suggests functional significance. We propose that the (His)C epsilon 1-H...O=C bond affects the charge distribution within the imidazolium ion so as to weaken the N epsilon 2-H bond, thereby facilitating general acid catalysis by the active site histidine during both the acylation and deacylation steps of hydrolysis.

Current progress in crystallographic studies of new lipases from filamentous fungi

Lipases from filamentous fungi have been studied extensively over many years. They exhibit properties attractive for industrial applications, e.g. in laundry detergents, tanning and paper industries and stereospecific organic synthesis. Enzymes from the fungi Rhizomucor miehei and Geotrichum candidum have been among the first neutral lipases to be characterized structurally by X-ray diffraction methods. In this paper we report a preliminary account of crystallographic studies of three other fungal lipases homologous to that from R. miehei and obtained from Humicola lanuginosa, Penicillium camembertii and Rhizopus delemar. These newly characterized structures have important implications for our understanding of structure-function relationships in lipases in general and the molecular basis of interfacial activation.

Crystallization and preliminary crystallographic studies of the precursor and mature forms of a neutral lipase from the fungus Rhizopus delemar

A neutral lipase from the filamentous fungus Rhizopus delemar has been crystallized in both its proenzyme and mature forms. Although the latter crystallizes readily and produces a variety of crystal forms, only one was found to be suitable for X-ray studies. It is monoclinic (C2, a = 92.8 A, b = 128.9 A, c = 78.3 A, beta = 135.8) with two molecules in the asymmetric unit related by a noncrystallographic diad. The prolipase crystals are orthorhombic (P2(1)2(1)2(1), with a = 79.8 A, b = 115.2 A, c = 73.0 A) and also contain a pair of molecules in the asymmetric unit. Initial results of molecular replacement calculations using the refined coordinates of the related lipase from Rhizomucor miehei identified the correct orientations and positions of the protein molecules in the unit cells of crystals of both proenzyme and the mature form.

Conformational lability of lipases observed in the absence of an oil-water interface: crystallographic studies of enzymes from the fungi Humicola lanuginosa and Rhizopus delemar

Considerable controversy exists regarding the exact nature of the molecular mechanism of interfacial activation, a process by which most lipases achieve maximum catalytic activity upon adsorption to an oil water interface. X-ray crystallographic studies show that lipases contain buried active centers and that displacements of entire secondary structure elements, or "lids," take place when the enzymes assume active conformations [Derewenda, U., A. M. Brzozowski, D. M. Lawson, and Z. S. Derewenda. 1992. Biochemistry: 31: 1532-1541; van Tilbeurgh, H., M-P. Egloff, C. Martinez, N. Rugani, R. Verger, and C. Cambillau. 1993. Nature: 362: 814-820; Grochulski, P., L. Yunge, J. D. Schrag, F. Bouthillier, P. Smith, D. Harrison, B. Rubin, and M. Cygler. 1993. J. Biol. Chem. 268: 12843-12847]. A simple two-state model inferred from these results implies that the "closed" conformation is stable in an aqueous medium, rendering the active centers inaccessible to water soluble substrates. We now report that in crystals of the Humicola lanuginosa lipase the "lid" is significantly disordered irrespective of the ionic strength of the medium, while in a related enzyme from Rhizopus delemar, crystallized in the presence of a detergent, the two molecules that form the asymmetric unit show different "lid" conformations. These new results call into question the simplicity of the "enzyme theory" of interfacial activation.

Crystallization of thioesterase II from Escherichia coli

X-ray quality single crystals of the Escherichia coli thioesterase II have been obtained. The protein used for crystallization was overexpressed in parent organism. The crystals are orthorhombic, space group C222(1) with axial lengths a = 99.0 A, b = 121.1 A, c = 166.6 A. A complete homotetramer (120,000 Da) of four polypeptide chains, each 286 residues long, occupies the asymmetric unit. The diffraction pattern extends to approximately 2.4 A resolution using CuK alpha radiation from a rotating anode source. The elucidation of the three-dimensional structure of this unusual bacterial thioesterase will provide basis for the analysis of its unique catalytic mechanism and substrate specificity.

Crystallization of canine cardiac calsequestrin

Calsequestrin is the major Ca2+ binding protein in the lumen of the sarcoplasmic reticulum membranes. Two X-ray quality crystal forms of canine cardiac calsequestrin were obtained by the hanging drop method using KCl as a precipitant. One form is monoclinic (space group P2(1), a = 73.4 A, b = 104.4 A, c = 60.2 A, beta = 120.4 degrees) with two molecules in the asymmetric unit and a solvent content of approximately 40%. The second form is trigonal (P3(1)21 or P3(2)21, a = b = 99.3 A, c = 89.8 A) with a single molecule in the asymmetric unit and 55% solvent content. Cross rotation function calculations show that despite the different space groups the packing of the molecules in both crystals is likely to be similar suggesting the existence of a stable dimer. The monoclinic crystals diffract beyond 3 A using a laboratory rotating anode source, while under the same conditions the trigonal crystals diffract only to approximately 4.5 A. This is the first report of successful preparation of X-ray quality crystals of a high capacity Ca2+ binding protein.

An unusual buried polar cluster in a family of fungal lipases

The stability of globular proteins arises largely from the burial of non-polar amino acids in their interior. These residues are efficiently packed to eliminate energetically unfavorable cavities. Contrary to these observations, high resolution X-ray crystallographic analyses of four homologous lipases from filamentous fungi reveal an alpha/beta fold which contains a buried conserved constellation of charged and polar side chains with associated cavities containing ordered water molecules. It is possible that this structural arrangement plays an important role in interfacial catalysis.

News from the interface: the molecular structures of triacylglyceride lipases

Neutral lipases constitute one of the most ubiquitous and diverse families of enzymes. The recently solved crystal structures of three lipases show that enzymatic hydrolysis occurs with the assistance of a catalytic triad, which is structurally reminiscent of serine proteinases. However, these lipases only become active at the oil-water interface through a conformational change that exposes the active centre of the enzyme.

The crystal and molecular structure of the Rhizomucor miehei triacylglyceride lipase at 1.9 A resolution

The crystal and molecular structure of a triacylglyceride lipase (EC 3.1.1.3) from the fungus Rhizomucor miehei was analyzed using X-ray single crystal diffraction data to 1.9 A resolution. The structure was refined to an R-factor of 0.169 for all available data. The details of the molecular architecture and the crystal structure of the enzyme are described. A single polypeptide chain of 269 residues is folded into a rather unusual singly wound beta-sheet domain with predominantly parallel strands, connected by a variety of hairpins, loops and helical segments. All the loops are right-handed, creating an uncommon situation in which the central sheet is asymmetric in that all the connecting fragments are located on one side of the sheet. A single N-terminal alpha-helix provides the support for the other, distal, side of the sheet. Three disulfide bonds (residues 29-268, 40-43, 235-244) stabilize the molecule. There are four cis peptide bonds, all of which precede proline residues. In all, 230 ordered water molecules have been identified; 12 of them have a distinct internal character. The catalytic center of the enzyme is made up of a constellation of three residues (His257, Asp203 and Ser144) similar in structure and function to the analogous (but not homologous) triad found in both of the known families of serine proteinases. The fourth residue in this system equivalent to Thr/Ser in proteinases), hydrogen bonded to Asp, is Tyr260. The catalytic site is concealed under a short amphipatic helix (residues 85 to 91), which acts as "lid", opening the active site when the enzyme is adsorbed at the oil-water interface. In the native enzyme the "lid" is held in place by hydrophobic interactions.

Expression, purification and crystallization of the Vibrio harveyi acyltransferase

We have obtained X-ray quality single crystals of Vibrio harveyi acyltransferase. The protein was obtained from V. harveyi by a gene mobilization expression system. The crystals are monoclinic (space group P2(1), a = 89.9 A, b = 83.6 A, c = 47.1 A, beta = 97.3 degrees) with two molecules related by a pronounced non-crystallographic dyad in the asymmetric unit, with a solvent content of approximately 50%. The diffraction pattern from fresh crystals extends beyond 2 A resolution using sealed tube CuK alpha radiation. The elucidation of the three-dimensional structure of this enzyme, believed to contain a proteinase-like catalytic triad, which resembles in many ways other eukaryotic fatty acid chain terminating enzymes, may have important consequences for our understanding of the molecular basis of the final stages of the synthesis of fatty acids.

Crystallization and preliminary crystallographic data of a Streptomyces scabies extracellular esterase

X-ray quality single crystals of an extracellular esterase from pathogenic Streptomyces scabies were obtained by the hanging drop method. The crystals are monoclinic (space group C2, a = 161.1 A, b = 51.2 A, c = 124.2 A, beta = 100.6 degrees) with two molecules related by a noncrystallographic dyad in the asymmetric unit, with a solvent content of approximately 64%. The diffraction pattern from fresh crystals extends beyond 2 A resolution using sealed tube CuK alpha radiation. The study has been initiated in order to elucidate the mechanism of this unusual non-serine-dependent esterase, and to gain better understanding of the molecular basis of the pathogenesis of the scab disease.

Catalysis at the interface: the anatomy of a conformational change in a triglyceride lipase

The crystal structure of an extracellular triglyceride lipase (from a fungus Rhizomucor miehei) inhibited irreversibly by diethyl p-nitrophenyl phosphate (E600) was solved by X-ray crystallographic methods and refined to a resolution of 2.65 A. The crystals are isomorphous with those of n-hexylphosphonate ethyl ester/lipase complex [Brzozowski, A. M., Derewenda, U., Derewenda, Z. S., Dodson, G. G., Lawson, D. M., Turkenburg, J. P., Bjorkling, F., Huge-Jensen, B., Patkar, S. A., & Thim, L. (1991) Nature 351, 491-494], where the conformational change was originally observed. The higher resolution of the present study allowed for a detailed analysis of the stereochemistry of the change observed in the inhibited enzyme. The movement of a 15 amino acid long "lid" (residues 82-96) is a hinge-type rigid-body motion which transports some of the atoms of a short alpha-helix (residues 85-91) by over 12 A. There are two hinge regions (residues 83-84 and 91-95) within which pronounced transitions of secondary structure between alpha and beta conformations are caused by dramatic changes of specific conformational dihedral angles (phi and psi). As a result of this change a hydrophobic area of ca. 800 A2 (8% of the total molecule surface) becomes exposed. Other triglyceride lipases are also known to have "lids" similar to the one observed in the R. miehei enzyme, and it is possible that the general stereochemistry of lipase activation at the oil-water interfaces inferred from the present X-ray study is likely to apply to the entire family of lipases.

Effects of gene mutations in lipoprotein and hepatic lipases as interpreted by a molecular model of the pancreatic triglyceride lipase

A molecular model of human pancreatic lipase (Winkler, F. K., D'Arcy, A., and Hunziker, W. (1990) Nature 343, 771-774) is used to explain the possible structural effects of the amino acid mutations identified to date in the human lipoprotein and hepatic lipase genes. A sequence homology profile was used to evaluate the alignment of the amino acid sequences of all three lipolytic enzymes (Kirchgessner, T. G., Chuat, J.-C., Heinzmann, C., Etienne, J., Guilhot, S., Svenson, K., Ameis, D., Pilon, C., D'Auriol, L., Andalibi, A., Schotz, M. C., Galibert, F., and Lusis, A. J. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 9647-9651) with respect to the secondary structure elements identified in the pancreatic lipase. As expected, maximum homology is observed in internal regions namely the hydrophobic strands of the central beta-pleated sheet. This observation strongly supports the hypothesis that all three molecules exhibit a very similar three-dimensional structure, particularly in the N-terminal catalytic domain. There is considerable variation in some of the surface loops connecting the individual strands, whereas others are conserved. It is hypothesized that the most conserved loops located around the active site are responsible for the catalytic function (similar for all three enzymes), whereas those that markedly differ are involved in the regulation at the molecular level, namely the binding of colipase (pancreatic enzyme) and apolipoprotein CII (lipoprotein lipase). The currently available library of hepatic and lipoprotein gene mutations seems to indicate that the majority of mutants disrupt the folding of the polypeptide chain, rather than affect specific constellations in and around the catalytic site or regulatory loops.

Relationships among serine hydrolases: evidence for a common structural motif in triacylglyceride lipases and esterases

A detailed analysis of the highly refined (1.9 A resolution) molecular model of the fungal (Rhizomucor miehei) triglyceride lipase reveals a unique conformation of the oligopeptide containing the active serine (Ser 144) residue. It consists of a six-residue beta-strand (strand 4 of the central sheet), a four-residue turn of type II' with serine in the epsilon conformation, and a buried alpha-helix packed in a parallel way against strands 4 and 5 of the central beta-pleated sheet. It is shown that the invariant glycines in positions (1) and (5) of the so-called lipase consensus sequence (G-X-S-X-G) are in extended and helical conformations, respectively, and that they are conserved owing to the steric restrictions imposed on these residues by the packing stereochemistry of this beta-epsilon Ser-alpha motif, and not by secondary structure requirements, as is the case in serine proteinases. Sequence homologies indicate that this unique motif is likely to be found in serine esterases and other lipases, indicating a possible evolutionary link of these families of hydrolytic enzymes.

Structure and molecular model refinement of Aspergillus oryzae (TAKA) alpha-amylase: an application of the simulated-annealing method

Monoclinic crystals of a neutral alpha-amylase from Aspergillus oryzae, containing three molecules in the asymmetric unit, have been reported previously and studied at 3 A resolution [Matsuura, Kunusoki, Harada & Kakudo (1984). J. Biochem. 95, 697-702]. Here we report the solution of the structure of this enzyme in a different crystal form (space group P2(1)2(1)2(1), a = 50.9, b = 67.2, c = 132.7 A), with only one molecule in the asymmetric unit. The structure was solved by the molecular replacement method, using a model of acid alpha-amylase from a related fungus A. niger [Brady, Brzozowski, Derewenda, Dodson & Dodson (1991). Acta Cryst. B47, 527-535]. Conventional least-squares crystallographic refinement failed to converge in a satisfactory manner, and the technique of molecular dynamics in the form of the XPLOR package [Brunger (1988). XPLOR Manual. Yale Univ., USA] was used to overcome the problem. A large rigid-body type movement of the C-terminal domain was identified and accounted for. The final round of restrained least-squares refinement (at 2.1 A resolution) including 3675 protein atoms and 247 water molecules resulted in a conventional crystallographic R factor of 0.183 and an atomic model which conforms well to standard stereochemical parameters (standard deviation of bond lengths from their expected values is 0.028 A, while that for planar groups is 0.029 A).