Molecular phylogeny of C1 inhibitor depicts two immunoglobulin-like domains fusion in fishes and ray-finned fishes specific intron insertion after separation from zebrafish

C1 inhibitor (C1IN) is a multi-facet serine protease inhibitor in the plasma cascades, inhibiting several proteases, notably, regulates both complement and contact system activation. Despite huge advancements in the understanding of C1IN based on biochemical properties and its roles in the plasma cascades, the phylogenetic history of C1IN remains uncharacterized. To date, there is no comprehensive study illustrating the phylogenetic history of C1IN. Herein, we explored phylogenetic history of C1IN gene in vertebrates. Fishes have C1IN with two immunoglobulin like domains attached in the N-terminal region. The RCL regions of CIIN from fishes and tetrapod genomes have variations at the positions P2 and P1′. Gene structures of C1IN gene from selected ray-finned fishes varied in the Ig domain region with creation of novel intron splitting exon Im2 into Im2a and Im2b. This intron is limited to ray-finned fishes with genome size reduced below 1 Gb. Hence, we suggest that genome compaction and associated double-strand break repairs are behind this intron gain. This study reveals the evolutionary history of C1IN and confirmed that this gene remains the same locus for ∼450 MY in 52 vertebrates analysed, but it is not found in frogs and lampreys.     

mPGES-1 as a target for cancer suppression : A comprehensive invited review “Phospholipase A2 and lipid mediators”

Prostaglandin E₂ (PGE₂) is a bioactive lipid that can elicit a wide range of biological effects associated with inflammation and cancer. The physiological roles of PGE₂ are diverse, mediated in part through activation of key downstream signaling cascades via transmembrane EP receptors located on the cell surface. Elevated levels of COX-2 and concomitant overproduction of PGE₂ are often found in human cancers. These observations have led to the use of non-steroidal anti-inflammatory drugs (NSAIDs) as chemopreventive agents, particularly for colorectal cancer (CRC). Their long-term use, however, may be associated with gastrointestinal toxicity and increased risk of adverse cardiovascular events, prompting the development of other enzymatic targets in this pathway. This review will focus on recent efforts to target the terminal synthase, mPGES-1, for cancer chemoprevention. The role of mPGES-1 in the pathogenesis of various cancers is discussed. In addition, an overview of recent efforts to develop small molecule inhibitors that target the protein with high selectivity is also be reviewed.     

Effects of Manduca sexta allatostatin and an analogue on the peach-potato aphid Myzus persicae (hemiptera: aphididae) and degradation by enzymes in the aphid gut

The oral toxicity of the C‐type allatostatin, Manduca sexta allatostatin (Manse‐AS) and the analogue δR³δR⁵Manse‐AS, where R residues were replaced by their D‐isomers, were tested against the peach‐potato aphid Myzus persicae by incorporation into an artificial diet. Both peptides had significant dose‐dependent effects on mortality, growth, and fecundity compared with control insects. The analogue, δR³δR⁵Manse‐AS, had an estimated LC₅₀ of 0.31 µg/µl diet and was more potent than Manse‐AS (estimated LC₅₀ of 0.58 µg/µl diet). At a dose of 0.35 µg δR³δR⁵Manse‐AS/µl diet, 76% of the aphids were dead after 6 days and all were dead after 10 days. In comparison, three times the dose of Manse‐AS was required to achieve 74% mortality after 8 days and 98% mortality after 16 days. The degradation of both peptides by extracts prepared from the gut of M. persicae was investigated. The estimated half‐life of Manse‐AS, when incubated with the gut extract from M. persicae, was 31 min. Degradation was due to a cathepsin L‐like cysteine protease, carboxypeptidase‐like activity, endoprotease activity with glutamine specificity, pyroglutamate aminopeptidase activity, and possibly trypsin‐like proteases. The half‐life of the δR³δR⁵ Manse‐AS analogue was enhanced (73 min) with the D‐isomers of R appearing to prevent cleavage around the R residues by cathepsin L‐like cysteine proteases or from trypsin‐like proteases. The greater stability of the analogue may explain its increased potency in M. persicae. This work demonstrates the potential use of Manse‐AS and analogues, with greater resistance to enzymatic attack, in aphid control strategies. © 2010 Wiley Periodicals, Inc.     

Carbonic anhydrase IX: Biochemical and crystallographic characterization of a novel antitumor target

Isoform IX of the zinc enzyme carbonic anhydrase (CA, EC 4.2.1.1), CA IX, is a transmembrane protein involved in solid tumor acidification through the HIF-1α activation cascade. CA IX has a very high catalytic activity for the hydration of carbon dioxide to bicarbonate and protons, even at acidic pH values (of around 6.5), typical of solid, hypoxic tumors, which are largely unresponsive to classical chemo- and radiotherapy. Thus, CA IX is used as a marker of tumor hypoxia and as a prognostic factor for many human cancers. CA IX is involved in tumorigenesis through many pathways, such as pH regulation and cell adhesion control. The X-ray structure of the catalytic domain of CA IX has been recently reported, being shown that CA IX has a typical α-CA fold. However, the CA IX structure differs significantly from the other CA isozymes when the protein quaternary structure is considered. Thus, two catalytic domains of CA IX associate to form a dimer, which is stabilized by the formation of an intermolecular disulfide bond. The active site clefts and the proteoglycan (PG) domains are located on one face of the dimer, while the C-termini are located on the opposite face to facilitate protein anchoring to the cell membrane. As all mammalian CAs, CA IX is inhibited by several main classes of inhibitors, such as the inorganic anions, the sulfonamides and their bioisosteres (sulfamates, sulfamides, etc.), the phenols, and the coumarins. The mechanism of inhibition with all these classes of compounds is understood at the molecular level, but the sulfonamides and their congeners have important applications. It has been recently shown that both in vitro, in cell cultures, as well as in animals with transplanted tumors, CA IX inhibition with sulfonamides lead to a return of the extracellular pH to more normal values, which leads to a delay in tumor growth. As a consequence, CA IX represents a promising antitumor target for the development of anticancer agents with an alternative mechanism of action.     

NEMO-binding domain peptide promotes osteoblast differentiation impaired by tumor necrosis factor alpha

Osteogenesis associated with persistent inflammation or infection exists in a broad range of conditions including rheumatoid arthritis and traumatic bone fracture. The poor outcomes of these conditions will benefit from more effective treatments. Here we investigated the molecular mechanisms and tested NEMO-binding domain peptide as a new approach of circumventing TNF-α inhibition of osteoblast differentiation. Our results showed: TNF-α markedly decreased BMP-2-induced alkaline phosphatase activity in the multipotent myoblast C2C12 cells in a dose dependent manner; stepwise experiments demonstrated that BMP-2-induced Smad1 activity was abrogated by addition of exogenous TNF-α or overexpression of NF-κB, and it was significantly elevated by overexpression of IκBα, an inhibitor of NF-κB; Western blotting showed that TNF-α markedly decreased the amount of phospho-Smad1 in BMP-2-activated C2C12 cells, but it did not alter Smad1 mRNA abundance as measured by real-time PCR; addition of a functional cell-permeable NEMO-binding domain (NBD) peptide antagonized NF-κB activity and ameliorated TNF-α inhibition of osteoblast differentiation. Taken together, our study reveals for the first time that NF-κB activation inhibits osteoblast differentiation by attenuating Smad1 activity and application of NBD peptide ameliorates this inhibitory effect. This could lead to new therapeutic drugs that circumvent the inflammatory inhibition of osteogenesis for treatment of traumatic open fractures with infection, rheumatoid arthritis and other bone loss disorders.     

Moderate Exercise and Fibrinolytic Potential in Obese Sedentary Men with Metabolic Syndrome

Objective: To investigate the impact of 30‐minute walking exercise at 70% Vo _2max on tissue plasminogen activator (t‐PA) Ag and plasminogen activator inhibitor type 1 (PAI‐1) Ag in obese sedentary males. Research Methods and Procedures: A controlled observational study of the effect of a 30‐minute acute exercise bout at 70% Vo _2max on plasma t‐PA antigen and PAI‐1 antigen in 10 obese sedentary males matched for age, ethnic origin, and smoking status with 10 nonobese sedentary male controls. Results: The obese group remained hypofibrinolytic compared with the nonobese group at all time‐points before, during, and after exercise. t‐PA increased in both groups with exercise before returning to baseline values 30 minutes after exercise. PAI‐1 did not significantly change in either group with exercise but rose significantly 30 minutes after exercise in the obese group. Discussion: The reduction in fibrinolytic potential in the obese group represents an increase in acute thrombotic risk and could account for the increased incidence of exercise‐associated myocardial infarction observed in sedentary obese groups.     

Zinc-mediated Reversible Multimerization of Hsp31 Enhances the Activity of Holding Chaperone

Hsp31 protein, belonging to the DJ-1/ThiJ/PfpI superfamily, increases the survival of Escherichia coli under various stresses. While it was reported as a holding chaperone, Hsp31 was also shown to exhibit the glyoxalase III activity in subsequent study. Here, we describe our finding that Hsp31 undergoes a Zn^+ 2-mediated multimerization (HMW_Zinc), resulting in an enhanced chaperone activity. Furthermore, it was shown that the formation of HMW_Zinc is reversible such that the oligomer dissociates into the native dimer by EDTA incubation. We attempted to determine the structural change involving the transition between the native dimer and HMW_Zinc by adding Ni^+ 2, which is Zn^+ 2-mimetic, producing a potential intermediate structure. An analysis of this intermediate revealed a structure with hydrophobic interior exposed, due to an unfolding of the N-terminal loop and the C-terminal β-to-α region. A treatment with hydrogen peroxide accelerated HMW_Zinc formation, so that the Hsp31^C185E mutant rendered the formation of HMW_Zinc even at 45 °C. However, the presence of Zn^+ 2 in the catalytic site antagonizes the oxidation of C185, implying a negative role. Our results suggest an unprecedented mechanism of the enhancing chaperone activity by Hsp31, in which the reversible formation of HMW_Zinc occurs in the presence of heat and Zn^+ 2 ion.     

How can organellar protein N-terminal sequences be dual targeting signals? In silico analysis and mutagenesis approach

Organellar nuclear-encoded proteins can be mitochondrial, chloroplastic or localized in both mitochondria and chloroplasts. Most of the determinants for organellar targeting are localized in the N-terminal part of the proteins, which were therefore analyzed in Arabidopsis thaliana. The mitochondrial, chloroplastic and dual N-terminal sequences have an overall similar composition. However, Arg is rare in the first 20 residues of chloroplastic and dual sequences, and Ala is more frequent at position 2 of these two types of sequence as compared to mitochondrial sequences. According to these observations, mutations were performed in three dual targeted proteins and analyzed by in vitro import into isolated mitochondria and chloroplasts. First, experiments performed with wild-type proteins suggest that the binding of precursor proteins to mitochondria is highly efficient, whereas the import and processing steps are more efficient in chloroplasts. Moreover, different processing sites are recognized by the mitochondrial and chloroplastic processing peptidases. Second, the mutagenesis approach shows the positive role of Arg residues for enhancing mitochondrial import or processing, as expected by the in silico analysis. By contrast, mutations at position 2 have dramatic and unpredicted effects, either enhancing or completely abolishing import. This suggests that the nature of the second amino acid residue of the N-terminal sequence is essential for the import of dual targeted sequences.