Functional coupling between a distal interaction and the cleavage site in bacterial RNase-P-RNA-mediated cleavage

Bacterial RNase P consists of one protein and one RNA [RNase P RNA (RPR)]. RPR can process tRNA precursors correctly in the absence of the protein. Here we have used model hairpin loop substrates corresponding to the acceptor, T-stem, and T-loop of a precursor tRNA to study the importance of the T-loop structure in RPR-alone reaction. T-stem/loop (TSL) interacts with a region in RPR [TSL binding site (TBS)], forming TSL/TBS interaction. Altering the T-loop structure affects both cleavage site selection and rate of cleavage at the correct site + 1 and at the alternative site − 1. The magnitude of variation depended on the structures of the T-loop and the TBS region, with as much as a 150-fold reduction in the rate of cleavage at + 1. Interestingly, for one T-loop structure mutant, no difference in the rate at − 1 was detected compared to cleavage of the substrate with an unchanged T-loop, indicating that, in this case, the altered T-loop structure primarily influences events required for efficient cleavage at the correct site + 1. We also provide data supporting a functional link between a productive TSL/TBS interaction and events at the cleavage site. Collectively, our findings emphasize the interplay between separate regions upon formation of a productive RPR substrate that leads to efficient and accurate cleavage. These new data provide support for an induced-fit mechanism in bacterial RPR-mediated cleavage at the correct site + 1.     

Efficient insertional mutagenesis system for the dimorphic pathogenic fungus Sporothrix schenckii using Agrobacterium tumefaciens

Sporothrix schenckii is a dimorphic pathogenic fungus that causes human and animal sporotrichosis globally. Here we developed and optimized an Agrobacterium tumefaciens-mediated transformation (ATMT) system of S. schenckii for insertional mutagenesis. The transformation efficiency reached more than 600 transformants per 10⁶ conidia. Using this protocol enabled us to obtain a large number of T-DNA insertional mutants within a short experimental period. Several mutants with altered phenotypes were obtained during the transformation experiments. The mutants displayed mitotic stability. Transferred DNA (T-DNA) flanking sequences were cloned by thermal asymmetric interlaced PCR (TAIL-PCR). Our results demonstrated that the ATMT system can be an effective tool for insertional mutagenesis in S. schenckii. This is the first report of a suitable mutagenesis system which may provide valuable mutants and information for both forward and reverse genetics research in the future for this medically important fungus.     

Structure of the catalytic domain of glucuronoyl esterase Cip2 from Hypocrea jecorina

The structure of the catalytic domain of glucuronoyl esterase Cip2 from the fungus H. jecorina was determined at a resolution of 1.9 ?. This is the first structure of the newly established carbohydrate esterase family 15. The structure has revealed the residues Ser278-His411-Glu301 present in a triad arrangement as the active site. Ser278 is present in the novel consensus sequence GCSRXG reported earlier in the members of CE-15 family. The active site is exposed on the surface of the protein which has implications for the ability of the enzyme to hydrolyze ester bonds of large substrates. Efforts are underway to obtain crystals of Cip2_GE complexed with inhibitor and synthetic substrates. The activity of the glucuronoyl esterase could play a significant role in plant biomass degradation as its expected role is to separate the lignin from hemicelluloses by hydrolysis of the ester bond between 4-O-methyl-D-glucuronic acid moieties of glucuronoxylans and aromatic alcohols of lignin.     

Structure-based identification of catalytic residues

The identification of catalytic residues is an essential step in functional characterization of enzymes. We present a purely structural approach to this problem, which is motivated by the difficulty of evolution-based methods to annotate structural genomics targets that have few or no homologs in the databases. Our approach combines a state-of-the-art support vector machine (SVM) classifier with novel structural features that augment structural clues by spatial averaging and Z scoring. Special attention is paid to the class imbalance problem that stems from the overwhelming number of non-catalytic residues in enzymes compared to catalytic residues. This problem is tackled by: (1) optimizing the classifier to maximize a performance criterion that considers both Type I and Type II errors in the classification of catalytic and non-catalytic residues; (2) under-sampling non-catalytic residues before SVM training; and (3) during SVM training, penalizing errors in learning catalytic residues more than errors in learning non-catalytic residues. Tested on four enzyme datasets, one specifically designed by us to mimic the structural genomics scenario and three previously evaluated datasets, our structure-based classifier is never inferior to similar structure-based classifiers and comparable to classifiers that use both structural and evolutionary features. In addition to the evaluation of the performance of catalytic residue identification, we also present detailed case studies on three proteins. This analysis suggests that many false positive predictions may correspond to binding sites and other functional residues. A web server that implements the method, our own-designed database, and the source code of the programs are publicly available at http://www.cs.bgu.ac.il/～meshi/functionPrediction.     

Mechanisms of RNA catalysis

Ribozymes are RNA molecules that act as chemical catalysts. In contemporary cells, most known ribozymes carry out phosphoryl transfer reactions. The nucleolytic ribozymes comprise a class of five structurally-distinct species that bring about site-specific cleavage by nucleophilic attack of the 2'-O on the adjacent 3'-P to form a cyclic 2',3'-phosphate. In general, they will also catalyse the reverse reaction. As a class, all these ribozymes appear to use general acid-base catalysis to accelerate these reactions by about a million-fold. In the Varkud satellite ribozyme, we have shown that the cleavage reaction is catalysed by guanine and adenine nucleobases acting as general base and acid, respectively. The hairpin ribozyme most probably uses a closely similar mechanism. Guanine nucleobases appear to be a common choice of general base, but the general acid is more variable. By contrast, the larger ribozymes such as the self-splicing introns and RNase P act as metalloenzymes.     

Asymmetric reduction of β-ketoesters and chiral β-iminoesters: impact of a α-quaternary stereocenter

Diastereomeric reduction of nonactivated, hindered β-keto and chiral β-iminoesters are described. The influence of a α-stereocontrolled center on the efficiency and stereoselectivity of the reduction was studied. Reaction conditions were optimized to synthesize β-hydroxy- and β-aminoesters in good yields. In the case of chiral β-iminoesters, influence of matched/mismatched diastereomeric pairs has been assessed.     

Antibody-mediated sialidase activity in blood serum of patients with multiple myeloma

Cell surface sialylation is known to be tightly connected with tumorigenicity, invasiveness, metastatic potential, clearance of aged cells, while the sialylation of IgG molecules determines their anti-inflammatory properties. Four sialidases - hydrolytic enzymes responsible for cleavage of sialic residues - were described in different cellular compartments. However, sialidases activity in body fluids, and specifically in blood serum, remains poorly studied. Here, we characterize first known IgG antibodies possessing sialidase-like activity in blood serum of multiple myeloma (MM) patients. Ig fractions were precipitated with ammonium sulfate (50% of saturation) from blood serum of 12 healthy donors and 14 MM patients, and screened for the presence of sialidase activity by using 4-MUNA (2'-(4-methylumbelliferyl)-α-D-N-acetylneuraminic acid) as substrate. High level of sialidase activity was detected in the MM patients, but not in healthy donors. Subsequent antibody purification by protein-G affinity chromatography and HPLC size exclusion chromatography at acidic conditions demonstrated that sialidase activity was attributable to IgG molecules. Sialidase activity was also specific for (Fab)(2) fragment of IgG and blocked by sialidase inhibitor DANA. Sialidase activity of IgG molecule was also confirmed by in gel assay for cleavage of sialidase substrate. Kinetic parameters of the catalysis reaction were described by Michaelis-Menten equation with K(m) = 44.4-108 μM and k(cat) = 2.7-23.1 min(-1). The action of IgG possessing sialidase-like activity towards human red blood cells resulted in a subsequent increase in their agglutination by the peanut agglutinin, that confirms their desialylation by the studied IgG. This is the first demonstration of the intrinsic sialidase activity of IgG isolated from blood serum of MM patients.     

Generation, characterization, and docking studies of DNA-hydrolyzing recombinant F(ab) antibodies

Previously we established a series of catalytic antibodies (catAbs) capable of hydrolyzing DNA prepared by hybridoma technology. A group of these catAbs exhibited high reactivity and substrate specificity. To determine the molecular basis for these catAbs, we cloned, sequenced, and expressed the variable regions of this group of antibodies as functional F(ab) fragments. The nucleotide and deduced amino acid sequences of the expressed light chain (Vκ) germline gene assignments confidently belonged to germline family Vκ1A, gene bb1.1 and GenBank accession number EF672207 while heavy chain variable region V(H) genes belonged to V(H) 1/V(H) J558, gene V130.3 and GenBank accession number EF672221. A well-established expression system based on the pARA7 vector was examined for its ability to produce catalytically active antibodies. Recombinant F(ab) (rF(ab) ) fragments were purified and their hydrolyzing activity was analyzed against supercoiled pUC19 plasmid DNA (scDNA). The study of rF(ab) provides important information about the potential catalytic activities of antibodies whose structure allows us to understand their basis of catalysis. Molecular surface analysis and docking studies were performed on the molecular interactions between the antibodies and poly(dA9), poly(dG9), poly(dT9), and poly(dC9) oligomers. Surface analysis identified the important sequence motifs at the binding sites, and different effects exerted by arginine and tyrosine residues at different positions in the light and heavy chains. This study demonstrates the potential usefulness of the protein DNA surrogate in the investigation of the origin of anti-DNA antibodies. These studies may define important features of DNA catAbs.     

Observation of hyperpositive non-linear effect in catalytic asymmetric organozinc additions to aldehydes

Asymmetric amplification is a phenomenon that is believed to play a key role in the emergence of homochirality in life. In asymmetric catalysis, theoretical and experimental models have been investigated to provide an understanding of how chiral amplification is possible, in particular based on non-linear effects. Interestingly, it has been proposed a quarter century ago that chiral catalysts, when not enantiopure might even be more enantioselective than their enantiopure counterparts. We show here that such hyperpositive non-linear effect in asymmetric catalysis is indeed possible. An in-depth study into the underlying mechanism was carried out, and the scheme we derive differs from the previous proposed models.     

Activity identification of ribozyme and U1 snRNA chimeric ribozyme against TGFβ1 in cell-free system and in hepatic stellate cells

Transforming growth factorβ1 (TGFβ1) is known to be intimately involved in many cellular processes. To explore the mechanism of TGFβ1 in these processes, the non-chimeric hammer-head ribozyme and U1 snRNA chimeric ribozyme against TGFβ1 were designed to down-regulate TGFβ1 expression. The activity of non-chimeric ribozyme and U1 snRNA chimeric ribozyme against TGFβ1 in vitro and in activated hepatic stellate cells (HSCs) was detected. Cleavage reactions of both ribozymes in vitro demonstrated that non-chimeric ribozyme possessed better cleavage activity in vitro than U1 snRNA chimeric ribozyme. The further study showed U1 snRNA chimeric ribozyme inhibited TGFβ1 expression more efficiently than non-chimeric ribozyme in transfected HSC cells. So it indicates that the U1 snRNA chimeric ribozyme provides an alternative approach for the research on the precise mechanism of TGFβ1 in many cellular processes and a potential therapeutic candidate for TGFβ1-related diseases.