Structure of the catalytic domain of the Clostridium thermocellum cellulase CelT.

Cellulases hydrolyze cellulose, a major component of plant cell walls, to oligosaccharides and monosaccharides. Several Clostridium species secrete multi-enzyme complexes (cellulosomes) containing cellulases. C. thermocellum CelT, a family 9 cellulase, lacks the accessory module(s) necessary for activity, unlike most other family 9 cellulases. Therefore, characterization of the CelT structure is essential in order to understand its catalytic mechanism. Here, the crystal structure of free CelTΔdoc, the catalytic domain of CelT, is reported at 2.1 Šresolution. Its structure differs in several aspects from those of other family 9 cellulases. CelTΔdoc contains an additional α-helix, α-helices of increased length and two additional surface-exposed ß-strands. It also contains three calcium ions instead of one as found in C. cellulolyticum Cel9M. CelTΔdoc also has two flexible loops at the open end of its active-site cleft. Movement of these loops probably allows the substrate to access the active site. CelT is stable over a wide range of pH and temperature conditions, suggesting that CelT could be used to convert cellulose biomass into biofuel.

Toc GTPases.

Chloroplasts import more than 90% of their protein constituents from the cytosol. The import is mediated by translocon complexes located in the chloroplast envelope and the stroma. This review focuses on the two GTPases in the Toc (translocon at the outer envelope membrane of chloroplasts) complex. Hypotheses are presented about gating across the outer membrane and the possible functional states of the GTPases.

Dimerization is important for the GTPase activity of chloroplast translocon components atToc33 and psToc159.

Arabidopsis Toc33 (atToc33) is a GTPase and a member of the Toc (translocon at the outer-envelope membrane of chloroplasts) complex that associates with precursor proteins during protein import into chloroplasts. By inference from the crystal structure of psToc34, a homologue in pea, the arginine at residue 130 (Arg(130)) has been implicated in the formation of the atToc33 dimer and in intermolecular GTPase activation within the dimer. Here we report the crystal structure at 3.2-A resolution of an atToc33 mutant, atToc33(R130A), in which Arg(130) was mutated to alanine. Both in solution and in crystals, atToc33(R130A) was present in its monomeric form. In contrast, both wild-type atToc33 and another pea Toc GTPase homologue, pea Toc159 (psToc159), were able to form dimers in solution. Dimeric atToc33 and psToc159 had significantly higher GTPase activity than monomeric atToc33, psToc159, and atToc33(R130A). Molecular modeling using the structures of psToc34 and atToc33(R130A) suggests that, in an architectural dimer of atToc33, Arg(130) from one monomer interacts with the beta-phosphate of GDP and several other amino acids of the other monomer. These results indicate that Arg(130) is critical for dimer formation, which is itself important for GTPase activity. Activation of GTPase activity by dimer formation is likely to be a critical regulatory step in protein import into chloroplasts.

Purification, crystallization and preliminary X-ray diffraction analysis of the catalytic domain of adenylyl cyclase Rv1625c from Mycobacterium tuberculosis.

The Rv1625c gene product is an adenylyl cyclase identified in the genome of Mycobacterium tuberculosis strain H37Rv. It shows sequence similarity to the mammalian nucleotide cyclases and functions as a homodimer, with two substrate-binding sites at the dimer interface. A mutant form of the catalytic domain of this enzyme, K296E/F363R/D365C (KFD-->ERC), was overexpressed in Escherichia coli cells in a soluble form. Crystals were obtained using the hanging-drop vapour-diffusion method with PEG 8000 as a precipitant. The protein crystallized in space group P4(1), with unit-cell parameters a = b = 71.25, c = 44.51 A. X-ray diffraction data were collected to a resolution of 3.4 A and the structure has been solved by the molecular-replacement method using a previously built theoretical model of the protein as the search molecule.