Insight into the redox partner interaction mechanism in cytochrome P450BM‐3 using molecular dynamics simulations

Flavocytochrome P450BM‐3 is a soluble bacterial reductase composed of two flavin (FAD/FMN) and one HEME domains. In this article, we have performed molecular dynamics simulations on both the isolated FMN and HEME domains and their crystallographic complex, with the aim to study their binding modes and to garner insight into the interdomain electron transfer (ET) mechanism. The results evidenced an interdomain conformational rearrangement that reduces the average distance between the FMN and HEME cofactors from 1.81 nm, in the crystal structure, to an average value of 1.41 ± 0.09 nm along the simulation. This modification is in agreement with previously proposed hypotheses suggesting that the crystallographic FMN/HEME complex is not in the optimal arrangement for favorable ET rate under physiological conditions. The calculation of the transfer rate along the simulation, using the Pathways Path method, demonstrated the occurrence of seven ET pathways between the two redox centers, with three of them providing ET rates (K_ET) comparable with the experimental one. The sampled ET pathways comprise the amino acids N319, L322, F390, K391, P392, F393, A399, C400, and Q403 of the HEME domain and M490 of the FMN domain. The values of K_ET closer to the experiment were found along the pathways FMN(C7) → F390 → K391 → P392 → HEME(Fe) and FMN(C8) → M490 → F393 → HEME(Fe). Finally, the analysis of the collective modes of the protein complex evidences a clear correlation of the first two essential modes with the activation of the most effective ET pathways along the trajectory. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 197–209, 2014.     

γ-Irradiation induces P2X7 receptor-dependent ATP release from B16 melanoma cells

Background

Ionizing irradiation causes not only growth arrest and cell death, but also release of growth factors or signal transmitters, which promote cancer malignancy. Extracellular ATP controls cancer growth through activation of purinoceptors. However, there is no report of radiation-induced ATP release from cancer cells. Here, we examined γ-irradiation-induced ATP release and its mechanism in B16 melanoma.

Methods

Extracellular ATP was measured by luciferin–luciferase assay. To investigate mechanism of radiation-induced ATP release, we pharmacologically inhibited the ATP release and established stable P2X₇ receptor-knockdown B16 melanoma cells using two short hairpin RNAs targeting P2X₇ receptor.

Results

Cells were exposed to 0.5–8 Gy of γ-rays. Extracellular ATP was increased, peaking at 5 min after 0.5 Gy irradiation. A selective P2X₇ receptor channel antagonist, but not anion transporter inhibitors, blocked the release of ATP. Further, radiation-induced ATP release was significantly decreased in P2X₇ receptor-knockdown cells. Our results indicate that γ-irradiation evokes ATP release from melanoma cells, and P2X₇ receptor channel plays a significant role in mediating the ATP release.

General Significance

We suggest that extracellular ATP could be a novel intercellular signaling molecule released from cancer cells when cells are exposed to ionizing radiation.     

Polypyrimidine tract‐binding protein homologues from Arabidopsis underlie regulatory circuits based on alternative splicing and downstream control

Alternative splicing (AS) of precursor mRNAs is a widespread phenomenon in plants; however, many questions, especially regarding its regulation and functional implications, remain to be elucidated. In vertebrates, polypyrimidine tract‐binding proteins (PTBs) have been identified as key splicing factors influencing splice site selection and orchestrating coordinated splicing programmes during developmental processes. Here, we analysed three PTB homologues from Arabidopsis thaliana and provide evidence for their gene regulatory potential based on AS and a splicing‐independent mechanism. Our data reveal that Arabidopsis PTB homologues are subject to extensive auto‐ and cross‐regulation via AS‐coupled nonsense‐mediated decay, thereby establishing a basis for interlinking their expression. Furthermore, the multiple modes of action of Arabidopsis PTB homologues are reflected in their subcellular localization in the nucleus, cytosol and processing bodies. This work provides insight into the regulation of AS in plants and highlights the regulatory potential of the multifunctional plant PTB homologues, which might have important implications in diverse biological processes.     

Polerovirus protein P0 prevents the assembly of small RNA‐containing RISC complexes and leads to degradation of ARGONAUTE1

RNA silencing plays an important role in plants in defence against viruses. To overcome this defence, plant viruses encode suppressors of RNA silencing. The most common mode of silencing suppression is sequestration of double‐stranded RNAs involved in the antiviral silencing pathways. Viral suppressors can also overcome silencing responses through protein–protein interaction. The poleroviral P0 silencing suppressor protein targets ARGONAUTE (AGO) proteins for degradation. AGO proteins are the core component of the RNA‐induced silencing complex (RISC). We found that P0 does not interfere with the slicer activity of pre‐programmed siRNA/miRNA containing AGO1, but prevents de novo formation of siRNA/miRNA containing AGO1. We show that the AGO1 protein is part of a high‐molecular‐weight complex, suggesting the existence of a multi‐protein RISC in plants. We propose that P0 prevents RISC assembly by interacting with one of its protein components, thus inhibiting formation of siRNA/miRNA–RISC, and ultimately leading to AGO1 degradation. Our findings also suggest that siRNAs enhance the stability of co‐expressed AGO1 in both the presence and absence of P0.     

A green fluorescent protein solubility screen in E. coli reveals domain boundaries of the GTP-binding domain in the P element transposase

Guanosine triphosphate (GTP) binding and hydrolysis events often act as molecular switches in proteins, modulating conformational changes between active and inactive states in many signaling molecules and transport systems. The P element transposase of Drosophila melanogaster requires GTP binding to proceed along its reaction pathway, following initial site‐specific DNA binding. GTP binding is unique to P elements and may represent a novel form of transpositional regulation, allowing the bound transposase to find a second site, looping the transposon DNA for strand cleavage and excision. The GTP‐binding activity has been previously mapped to the central portion of the transposase protein; however, the P element transposase contains little sequence identity with known GTP‐binding folds. To identify soluble, active transposase domains, a GFP solubility screen was used testing the solubility of random P element gene fragments in E. coli. The screen produced a single clone spanning known GTP‐binding residues in the central portion of the transposase coding region. This clone, amino acids 275–409 in the P element transposase, was soluble, highly expressed in E.coli and active for GTP‐binding activity, therefore is a candidate for future biochemical and structural studies. In addition, the chimeric screen revealed a minimal N‐terminal THAP DNA‐binding domain attached to an extended leucine zipper coiled‐coil dimerization domain in the P element transposase, precisely delineating the DNA‐binding and dimerization activities on the primary sequence. This study highlights the use of a GFP‐based solubility screen on a large multidomain protein to identify highly expressed, soluble truncated domain subregions.     

Asymmetric synthesis of (S)-ethyl-4-chloro-3-hydroxy butanoate using a Saccharomyces cerevisiae reductase: Enantioselectivity and enzyme–substrate docking studies

Ethyl (S)-4-chloro-3-hydroxy butanoate (ECHB) is a building block for the synthesis of hypercholesterolemia drugs. In this study, various microbial reductases have been cloned and expressed in Escherichia coli. Their reductase activities toward ethyl-4-chloro oxobutanoate (ECOB) have been assayed. Amidst them, Baker's yeast YDL124W, YOR120W, and YOL151W reductases showed high activities. YDL124W produced (S)-ECHB exclusively, whereas YOR120W and YOL151W made (R)-form alcohol. The homology models and docking models with ECOB and NADPH elucidated their substrate specificities and enantioselectivities. A glucose dehydrogenase-coupling reaction was used as NADPH recycling system to perform continuously the reduction reaction. Recombinant E. coli cell co-expressing YDL124W and Bacillus subtilis glucose dehydrogenase produced (S)-ECHB exclusively.     

Beta sheet 2–alpha helix C loop of cytochrome P450 reductase serves as a docking site for redox partners

As a promiscuous redox partner, the biological role of cytochrome P450 reductase (CPR) depends significantly on protein–protein interactions. We tested a hypothesized CPR docking site by mutating D113, E115, and E116 to alanine and assaying activity toward various electron acceptors as a function of ionic strength. Steady-state cytochrome c studies demonstrated the mutations improved catalytic efficiency and decreased the impact of ionic strength on catalytic parameters when compared to wild type. Based on activity toward 7-ethoxy-4-trifluoro-methylcoumarin, CYP2B1 and CPR favored formation of an active CYP2B1•CPR complex and inactive (CYP2B1)₂•CPR complex until higher ionic strength whereby only the binary complex was observed. The mutations increased dissociation constants only for the binary complex and suppressed the ionic strength effect. Studies with a non-binding substrate, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) suggest changes in activity toward cytochrome c and CYP2B1 reflect alterations in the route of electron transfer caused by the mutations. Electrostatic modeling of catalytic and binding parameters confirmed the importance of D113 and especially the double mutant E115 and E116 as mediators in forming charge–charge interactions between CPR and complex partners.     

Protein disulfide isomerase-P5, down-regulated in the final stage of boar epididymal sperm maturation,catalyzes disulfide formation to inhibit protein function in oxidative refolding of reduced denatured lysozyme

In mammalian spermiogenesis, sperm mature during epididymal transit to get fertility. The pig sharing many physiological similarities with humans is considered a promising animal model in medicine. We examined the expression profiles of proteins from boar epididymal caput, corpus, and cauda sperm by two-dimensional gel electrophoresis and peptide mass fingerprinting. Our results indicated that protein disulfide isomerase-P5 (PDI-P5) human homolog was down-regulated from the epididymal corpus to cauda sperm, in contrast to the constant expression of protein disulfide isomerase A3 (PDIA3) human homolog. To examine the functions of PDIA3 and PDI-P5, we cloned and sequenced cDNAs of pig PDIA3 and PDI-P5 protein precursors. Each recombinant pig mature PDIA3 and PDI-P5 expressed in Escherichia coli showed thiol-dependent disulfide reductase activities in insulin turbidity assay. Although PDIA3 showed chaperone activity to promote oxidative refolding of reduced denatured lysozyme, PDI-P5 exhibited anti-chaperone activity to inhibit oxidative refolding of lysozyme at an equimolar ratio. SDS-PAGE and Western blotting analysis suggested that disulfide cross-linked and non-productively folded lysozyme was responsible for the anti-chaperone activity of PDI-P5. These results provide a molecular basis and insights into the physiological roles of PDIA3 and PDI-P5 in sperm maturation and fertilization.