Production and crystallization of the C-propeptide trimer from human procollagen III.

The C-propeptide domains of the fibrillar procollagens, which are present throughout the Metazoa in the form of ∼90 kDa trimers, play crucial roles in both intracellular molecular assembly and extracellular formation of collagen fibrils. The first crystallization of a C-propeptide domain, that from human procollagen III, is described. Following transient expression in mammalian 293T cells of both the native protein and a selenomethionine derivative, two crystal forms of the homotrimer were obtained: an orthorhombic form (P2(1)2(1)2(1)) that diffracted to 1.7 Šresolution and a trigonal form (P321) that diffracted to 3.5 Šresolution. Characterization by MALDI-TOF mass spectrometry allowed the efficiency of selenomethionine incorporation to be determined.

Specificity modulation of barley alpha-amylase through biased random mutagenesis involving a conserved tripeptide in beta --> alpha loop 7 of the catalytic (beta/alpha)(8)-barrel domain.

The relative specificity and bond cleavage pattern of barley alpha-amylase 1 (AMY1) were dramatically changed by mutation in F(286)VD that connected beta-strand 7 of the catalytic (beta/alpha)(8)-barrel to a succeeding 3(10)-helix. This conserved tripeptide of the otherwise variable beta --> alpha segment 7 lacked direct ligand contact, but the nearby residues His290 and Asp291 participated in transition-state stabilization and catalysis. On the basis of sequences of glycoside hydrolase family 13, a biased random mutagenesis protocol was designed which encoded 174 putative F(286)VD variants of C95A-AMY1, chosen as the parent enzyme to avoid inactivating glutathionylation by the yeast host. The FVG, FGG, YVD, LLD, and FLE mutants showed 12-380 and 1.8-33% catalytic efficiency (k(cat)/K(m)) toward 2-chloro-4-nitrophenyl beta-D-maltoheptaoside and amylose DP17, respectively, and 0.5-50% activity for insoluble starch compared to that of C95A-AMY1. K(m) and k(cat) were decreased 2-9- and 1.3-83-fold, respectively, for the soluble substrates. The starch:oligosaccharide and amylose:oligosaccharide specificity ratios were 13-172 and 2.4-14 for mutants and 520 and 27 for C95A-AMY1, respectively. The FVG mutant released 4-nitrophenyl alpha-D-maltotrioside (PNPG(3)) from PNPG(5), whereas C95A-AMY1 produced PNPG and PNPG(2). The mutation thus favored interaction with the substrate aglycon part, while products from PNPG(6) reflected the fact that the mutation restored binding at subsite -6 which was lost in C95A-AMY1. The outcome of this combined irrational and rational protein engineering approach was evaluated considering structural accommodation of mutant side chains. FVG and FGG, present in the most active variants, represented novel sequences. This emphasized the worth of random mutagenesis and launched flexibility as a goal for beta --> alpha loop 7 engineering in family 13.

Specific inhibition of barley alpha-amylase 2 by barley alpha-amylase/subtilisin inhibitor depends on charge interactions and can be conferred to isozyme 1 by mutation.

alpha-Amylase 2 (AMY2) and alpha-amylase/subtilisin inhibitor (BASI) from barley bind with Ki = 0.22 nM. AMY2 is a (beta/alpha)8-barrel enzyme and the segment Leu116-Phe143 in domain B (Val89-Ile152), protruding at beta-strand 3 of the (beta/alpha)8-barrel, was shown using isozyme hybrids to be crucial for the specificity of the inhibitor for AMY2. In the AMY2-BASI crystal structure [F. Vallée, A. Kadziola, Y. Bourne, M. Juy, K. W. Rodenburg, B. Svensson & R. Haser (1998) Structure 6, 649-659] Arg128AMY2 forms a hydrogen bond with Ser77BASI, while Asp142AMY2 makes a salt-bridge with Lys140BASI. These two enzyme residues are substituted by glutamine and asparagine, respectively, to assess their contribution in binding of the inhibitor. These mutations were performed in the well-expressed, inhibitor-sensitive hybrid barley alpha-amylase 1 (AMY1)-(1-90)/AMY2-(90-403) with Ki = 0.33 nM, because of poor production of AMY2 in yeast. In addition Arg128, only found in AMY2, was introduced into an AMY1 context by the mutation T129R/K130P in the inhibitor-insensitive hybrid AMY1-(1-161)/AMY2-(161-403). The binding energy was reduced by 2.7-3.0 kcal.mol-1 as determined from Ki after the mutations R128Q and D142N. This corresponds to loss of a charged interaction between the protein molecules. In contrast, sensitivity to the inhibitor was gained (Ki = 7 microM) by the mutation T129R/K130P in the insensitive isozyme hybrid. Charge screening raised Ki 14-20-fold for this latter mutant, AMY2, and the sensitive isozyme hybrid, but only twofold for the R128Q and D142N mutants. Thus electrostatic stabilization was effectively introduced and lost in the different mutant enzyme-inhibitor complexes and rational engineering using an inhibitor recognition motif to confer binding to the inhibitor mimicking the natural AMY2-BASI complex.

Structures of the psychrophilic Alteromonas haloplanctis alpha-amylase give insights into cold adaptation at a molecular level.

BACKGROUND: . Enzymes from psychrophilic (cold-adapted) microorganisms operate at temperatures close to 0 degreesC, where the activity of their mesophilic and thermophilic counterparts is drastically reduced. It has generally been assumed that thermophily is associated with rigid proteins, whereas psychrophilic enzymes have a tendency to be more flexible. RESULTS: . Insights into the cold adaptation of proteins are gained on the basis of a psychrophilic protein's molecular structure. To this end, we have determined the structure of the recombinant form of a psychrophilic alpha-amylase from Alteromonas haloplanctis at 2.4 A resolution. We have compared this with the structure of the wild-type enzyme, recently solved at 2.0 A resolution, and with available structures of their mesophilic counterparts. These comparative studies have enabled us to identify possible determinants of cold adaptation. CONCLUSIONS: . We propose that an increased resilience of the molecular surface and a less rigid protein core, with less interdomain interactions, are determining factors of the conformational flexibility that allows efficient enzyme catalysis in cold environments.

Crystal structures of the psychrophilic alpha-amylase from Alteromonas haloplanctis in its native form and complexed with an inhibitor.

Alteromonas haloplanctis is a bacterium that flourishes in Antarctic sea-water and it is considered as an extreme psychrophile. We have determined the crystal structures of the alpha-amylase (AHA) secreted by this bacterium, in its native state to 2.0 angstroms resolution as well as in complex with Tris to 1.85 angstroms resolution. The structure of AHA, which is the first experimentally determined three-dimensional structure of a psychrophilic enzyme, resembles those of other known alpha-amylases of various origins with a surprisingly greatest similarity to mammalian alpha-amylases. AHA contains a chloride ion which activates the hydrolytic cleavage of substrate alpha-1,4-glycosidic bonds. The chloride binding site is situated approximately 5 angstroms from the active site which is characterized by a triad of acid residues (Asp 174, Glu 200, Asp 264). These are all involved in firm binding of the Tris moiety. A reaction mechanism for substrate hydrolysis is proposed on the basis of the Tris inhibitor binding and the chloride activation. A trio of residues (Ser 303, His 337, Glu 19) having a striking spatial resemblance with serine-protease like catalytic triads was found approximately 22 angstroms from the active site. We found that this triad is equally present in other chloride dependent alpha-amylases, and suggest that it could be responsible for autoproteolytic events observed in solution for this cold adapted alpha-amylase.

Crystallization and preliminary X-ray diffraction studies of alpha-amylase from the antarctic psychrophile Alteromonas haloplanctis A23.

A cold-active alpha-amylase was purified from culture supernatants of the antarctic psychrophile Alteromonas haloplanctis A23 grown at 4 degrees C. In order to contribute to the understanding of the molecular basis of cold adaptations, crystallographic studies of this cold-adapted enzyme have been initiated because a three-dimensional structure of a mesophilic counterpart, pig pancreatic alpha-amylase, already exists. alpha-Amylase from A. haloplanctis, which shares 53% sequence identity with pig pancreatic alpha-amylase, has been crystallized and data to 1.85 A have been collected. The space group is found to be C222(1) with a = 71.40 A, b = 138.88 A, and c = 115.66 A. Until now, a three-dimensional structure of a psychrophilic enzyme is lacking.

A flexible loop at the dimer interface is a part of the active site of the adjacent monomer of Escherichia coli orotate phosphoribosyltransferase.

Orotate phosphoribosyltransferase (OPRTase) is involved in the biosynthesis of pyrimidine nucleotides. Alpha-D-ribosyldiphosphate 5-phosphate (PRPP) and orotate are utilized to form pyrophosphate and orotidine 5'-monophosphate (OMP) in the presence of divalent cations, preferably Mg2+. OMP is thereafter converted to uridine 5'-monophosphate by OMP decarboxylase. We have determined the 2.4 angstrom structure of Escherichia coli OPRTase, ligated with sulfate, by molecular replacement and refined the structure to an R-factor of 18.3% for all data. In the structure of the E. coli enzyme we have determined the fold of a flexible loop region with a highly conserved amino acid sequence among OPRTases, a region known to take part in catalysis. The structure of this region was not determined in the model used for molecular replacement, and it involves interactions at the dimer interface through a bound sulfate ion. Crystalline E. coli OPRTase is a homodimer, with sulfate ions inhibiting enzyme activity bound in the dimer interface close to the flexible loop region. Although this loop is very close in space to the sulfate binding site, and sulfate is found in both interfaces of the homodimer, the loop structure is only traceable in one monomer. We expect that the mobility of this loop is important for catalysis, and, on the basis of the reported structure and the structure of Salmonella typhimurium OPRTase.OMP, we propose that the movement of this loop in association with the movement of OMP is vital to catalysis. Apart from the flexible loop region and a solvent-exposed loop (residues 158-164), the most significant differences in structure between S. typhimurium OPRTase.OMP and E. coli OPRTase are found in the substrate binding regions: the 5'-phosphate binding region (residues 120-131), the binding region for the orotate part of OMP (residues 25-27), and the pyrophosphate binding region (residues 71-73).

Crystallization and preliminary X-ray diffraction studies on the Apo form of orotate phosphoribosyltransferase from Escherichia coli.

Three different crystal forms of the apoenzyme orotate phosphoribosyltransferase, with M(r) = 23,552 from Escherichia coli have been grown. The crystals, which are all suitable for X-ray diffraction analysis, have been grown by the hanging drop vapour diffusion method. The first form crystallizes in the orthorhombic space group P2(1)2(1)2, with cell dimensions: a = 136.34 A, b = 75.98 A and c = 40.32 A; the second form in the monoclinic space group P2, with unit cell dimensions: a = 101.61 A, b = 40.49 A, c = 79.05 A and beta = 87.33 degrees; and the third form in P2(1)2(1)2(1), the cell dimensions being a = 70.27 A, b = 103.53 A, c = 53.83 A.