Plasmodium falciparum RuvB1 is an active DNA helicase and translocates in the 5′–3′ direction

RuvB family of protein contains two similar kinds of proteins i.e. RuvB1 and RuvB2 from yeast to human. These proteins belong to the AAA + class of proteins and are critical components of several multiprotein complexes involved in diverse cellular activities. There are two RuvB proteins annotated in the Plasmodium database but the identification of the third protein recently by our lab has raised the question why Plasmodium falciparum contains three RuvB proteins instead of two. Hence the biochemical characterizations of these proteins have become essential to understand the role of these proteins in the malaria parasite. Recently we have reported the characterization of the recombinant PfRuvB3, which contains ATPase activity but lacks DNA helicase activity. In the present study we report the phylogenetic analysis and detailed biochemical characterization of one of the other RuvB homologue RuvB1 from P. falciparum. PfRuvB1 shows considerable homology with human as well as yeast RuvB1 and contains Walker motif A and Walker motif B. The activity analysis of this protein revealed that PfRuvB1 is an ATPase and this activity increased significantly in the presence of ss-DNA. PfRuvB1 also contains DNA helicase activity and translocates preferentially in 5′ to 3′ direction. In vivo investigation of PfRuvB1 revealed that it is constitutively expressed during all the stages of intraerythrocytic cycle of P. falciparum and localizes mainly to the nucleus. These studies will make important contribution in understanding the role of RuvB protein in P. falciparum.     

An assay combining high-performance liquid chromatography and mass spectrometry to measure DNA interstrand cross-linking efficiency in oligonucleotides of varying sequences

The main method of evaluating the DNA interstrand cross-linking ability of cancer chemotherapeutic agents in naked DNA currently involves the electrophoresis of relatively long radiolabeled duplex DNA fragments (typically approximately 2000 bp) on neutral gels after incubation with the agent of interest. Denaturation by heating is carried out prior to loading, and a neutral gel allows reannealing of cross-linked DNA. To avoid the use of radioactivity we have developed a new method based on ion pair reversed phase liquid chromatography (RPLC) and mass spectrometry (MS) that allows characterization and quantitation of drug-DNA interstrand cross-links formed within short oligonucleotide duplexes (i.e., 12 bp). Advantages of this assay include rapid throughput, as compared to electrophoretic methods, and the use of readily available short nonradiolabeled oligonucleotides of any sequence, thereby facilitating investigation of sequence selectivity. A further advantage is that all species separated by the chromatographic process can be positively identified by MS. Using this new method, we have investigated the rate of DNA cross-linking and sequence selectivity of the interstrand cross-linking agent SJG-136, a pyrrolobenzodiazepine (PBD) dimer currently in phase I clinical trials. The assay was found to be sufficiently sensitive and selective to allow separation of the unbound and drug-bound oligonucleotide species by high-performance liquid chromatography (HPLC) and to allow positive identification of these individual species by MS. A further benefit, as compared with electrophoretic methods, is that kinetic information can be obtained and compared for different binding sequences.     

Caspase-3 immunohistochemical expression is a marker of apoptosis,increased grade and early recurrence in intracranial meningiomas

Caspase-3 is the ultimate executioner caspase that is essential for the nuclear changes associated with apoptosis. We investigated caspase-3 immunohistochemical expression in 58 primary intracranial meningiomas, using one monoclonal antibody detecting both precursor and cleaved caspase-3 (CPP32) and a second recognizing only the cleaved activated form (ASP175). Caspase-3 expression was analyzed in relation to baseline apoptosis—as illustrated by the expression of anti-single stranded DNA (ss-DNA), the antiapoptotic protein bcl-2, proliferation indices (Ki-67, PCNA, topoisomerase IIa, mitosin C), hormonal status (estrogen, progesterone, androgen receptors), standard clinicopathological parameters and patients’ disease-free survival. Caspase-3 immunostaining was observed in 62% of cases for CPP32 and in 24% for ASP175. In both instances, the labeling index (LI) was significantly correlated with ss-DNA LI (p=0.038 and p=0.018). CPP32 but not ASP175 LI positively correlated with the mitotic index (p=0.001) and PCNA LI (p=0.004). Both CPP32 and ASP175 LIs were increased in nonbenign meningiomas (p<0.0001 and p=0.0035 respectively). In univariate and multivariate survival analyses, caspase-3 predicted meningioma recurrence, independently affecting disease-free survival (p=0.011 and p=0.047 respectively for CPP32; p<0.0001 and p=0.012 respectively for ASP175). Caspase-3 may prove to be a useful predictor of early recurrence in a group of neoplasms characterized by the frequent discordance between histology and clinical behavior.     

Ter mutation and susceptibility to phi X174 phage in E. coli K12.

The Ter-15 mutant derived from E. coli K12 W2252-11U^? RC^str (wild type I) is found to be sensitive to φx174 phage infection. Lipopolysaccharide extracted from this mutant inactivates the phage, and has core oligosaccharides identical in amounts to those in the lipopolysaccharide from wild type cells.In contrast, the Ter-21 mutant derived from E. coli K12 W2252-11U^? RC^rel (wild type II) is not sensitive to this phage infection, and its lipopolysaccharide does not inactivate the phage. Its lipopolysaccharide sugars are found to be D-glucose and D-ribose, thus differing from the lipopolysaccharide sugars of the wild type cells.     

Prospects of nanoparticle–DNA binding and its implications in medical biotechnology

Bio-nanotechnology is a new interdisciplinary R&D area that integrates engineering and physical science with biology through the development of multifunctional devices and systems, focusing biology inspired processes or their applications, in particular in medical biotechnology. DNA based nanotechnology, in many ways, has been one of the most intensively studied fields in recent years that involves the use and the creation of bio-inspired materials and their technologies for highly selective biosensing, nanoarchitecture engineering and nanoelectronics. Increasing researches have been offered to a fundamental understanding how the interactions between the nanoparticles and DNA molecules could alter DNA molecular structure and its biochemical activities. This minor review describes the mechanisms of the nanoparticle–DNA binding and molecular interactions. We present recent discoveries and research progresses how the nanoparticle–DNA binding could vary DNA molecular structure, DNA detection, and gene therapy. We report a few case studies associated with the application of the nanoparticle–DNA binding devices in medical detection and biotechnology. The potential impacts of the nanoparticles via DNA binding on toxicity of the microorganisms are briefly discussed. The nanoparticle–DNA interactions and their impact on molecular and microbial functionalities have only drown attention in recent a few years. The information presented in this review can provide useful references for further studies on biomedical science and technology.     

A family of shuttle vectors for lactic acid bacteria and other gram-positive bacteria based on the plasmid pLF1311 replicon

A set of broad-host-range single-replicon shuttle vectors for cloning nucleotide sequences in gram-positive bacteria (lactobacilli, enterococci, lactococci, bacilli, etc.) was created. The vectors are based on the cryptic plasmid pLF 1311 fromLactobacillus fermentum VKM 1311, belonging to the family of the σ-type pE194-like plasmids. The vectors can replicate in gram-positive bacteria andEscherichia coli. They are stable in many gram-positive bacteria, have small sizes, and allow the selection of recombinants on media with X-Gal. The vectors that contain the region of initiation of the conjugal transfer of plasmid RP4 belonging to the incompatibility group IncPα can be mobilized in a great number of bacteria using a helper plasmid fromE. coli but not from gram-positive bacteria     

Human serum albumin supported lipid patterns for the targeted recognition of microspheres coated by membrane based on ss-DNA hybridization

Human serum albumin (HSA) patterns have been successfully fabricated for the deposition of lipid bilayer, 1,2-dimyristoyl-sglycerophosphate (DMPA), by making use of the micro-contact printing (microCP) technique and liposome fusion. Confocal laser scanning microscopy (CLSM) results indicate that lipid bilayer has been assembled in HSA patterns with a good stability. Such well-defined lipid patterns formed on HSA surface create possibility to incorporate specific components like channels or receptors for specific recognition. In view of this, microspheres coated with lipid membranes were immobilized in HSA-supported lipid patterns via the hybridization of complementary ss-DNAs. This procedure enables to transfer solid materials to a soft surface through a specific recognition.