Differential protein expression in Colletotrichum acutatum: changes associated with reactive oxygen species and nitrogen starvation implicated in pathogenicity on strawberry

The cellular outcome of changes in nitrogen availability in the context of development and early stages of pathogenicity was studied by quantitative analysis of two-dimensional gel electrophoresis of Colletotrichum acutatum infecting strawberry. Significant alterations occurred in the abundance of proteins synthesized during appressorium formation under nitrogen-limiting conditions compared with a complete nutrient supply. Proteins that were up- or down-regulated were involved in energy metabolism, nitrogen and amino acid metabolism, protein synthesis and degradation, response to stress and reactive oxygen scavenging. Members belonging to the reactive oxygen species (ROS) scavenger machinery, superoxide dismutase and glutathione peroxidase, were up-regulated at the appressorium formation stage, as well as under nitrogen-limiting conditions relative to growth with a complete nutrient supply, whereas abundance of bifunctional catalase was up-regulated predominantly at the appressorium formation stage. Fungal ROS were detected within germinating conidia during host pre-penetration, penetration and colonization stages, accompanied by plant ROS, which were abundant in the apoplastic space. Application of exogenous antioxidants quenched ROS production and reduced the frequency of appressorium formation. Up-regulation in metabolic activity was detected during appressorium formation and nutrient deficiency compared with growth under complete nutrient supply. Enhanced levels of proteins related to the glyoxylate cycle and lipid metabolism (malate dehydrogenase, formate dehydrogenase and acetyl-CoA acetyltransferase) were observed at the appressorium formation stage, in contrast to down-regulation of isocitrate dehydrogenase. The present study demonstrates that appressoria formation processes, occurring under nutritional deprivation, are accompanied by metabolic shifts, and that ROS production is an early fungal response that may modulate initial stages of pathogen development.     

Subcloning,expression, purification,and characterization of recombinant human leptin-binding domain

A subdomain of the human leptin receptor encoding part of the extracellular domain (amino acids 428 to 635) was subcloned, expressed in a prokaryotic host, and purified to homogeneity, as evidenced by SDS-PAGE, with over 95% monomeric protein. The purified leptin-binding domain (LBD) exhibited the predicted beta structure, was capable of binding human, ovine, and chicken leptins, and formed a stable 1:1 complex with all mammalian leptins. The binding kinetics, assayed by surface plasmon resonance methodology, showed respective k(on) and k(off) values (mean +/- S.E.) of 1.20 +/- 0.23 x 10(-5) mol(-1) s(-1) and 1.85 +/- 0.30 x 10(-3) s(-1) and a K(d) value of 1.54 x 10(-8) m. Similar results were achieved with conventional binding experiments. LBD blocked leptin-induced, but not interleukin-3-induced, proliferation of BAF/3 cells stably transfected with the long form of human leptin receptor. The modeled LBD structure and the known three-dimensional structure of human leptin were used to construct a model of 1:1 LBD.human leptin complex. Two main residues, Phe-500, located in loop L3, and Tyr-441, located in L1, are suggested to contribute to leptin binding.     

High-resolution species-distribution model based on systematic sampling and indirect observations

Species distribution models (SDMs) are often limited by the use of coarse-resolution environmental variables and by the number of observations required for their calibration. This is particularly true in the case of elusive animals. Here, we developed a SDM by combining three elements: a database of explanatory variables, mapped at a fine resolution; a systematic sampling scheme; and an intensive survey of indirect observations. Using MaxEnt, we developed the SDM for the population of the Asiatic wild ass (Equus hemionus), a rare and elusive species, at three spatial scales: 10, 100, and 1000 m per pixel. We used indirect observations of feces mounds. We constructed 14 layers of explanatory variables, in five categories: water, topography, biotic conditions, climatic variables and anthropogenic variables. Woody vegetation cover and slopes were found to have the strongest effect on the distribution of wild ass and were included as the main predictors in the SDM. Model validation revealed that an intensive survey of feces mounds and high-resolution predictor layers resulted in a highly accurate and informative SDM. Fine-grain (10 and 100 m) SDMs can be utilized to: (1) characterize the variables influencing species distribution at high resolution and local scale, including anthropogenic effects and geomorphologic features; (2) detect potential population activity centers; (3) locate potential corridors of movement and possible isolated habitat patches. Such information may be useful for the conservation efforts of the Asiatic wild ass. This approach could be applied to other elusive species, particularly large mammals.     

BchY-Based Degenerate Primers Target All Types of Anoxygenic Photosynthetic Bacteria in a Single PCR

To detect anoxygenic bacteria containing either type 1 or type 2 photosynthetic reaction centers in a single PCR, we designed a degenerate primer set based on the bchY gene. The new primers were validated in silico using the GenBank nucleotide database as well as by PCR on pure strains and environmental DNA.Anoxygenic photosynthetic bacteria are diverse and important members of microbial communities (11, 13, 17, 20). There are five bacterial phyla containing anoxygenic phototrophs: Proteobacteria (purple bacteria), Chlorobi (green sulfur bacteria), Chloroflexi (green nonsulfur bacteria), Acidobacteria (“Candidatus Chloracidobacterium thermophilum” [7]), and Firmicutes (heliobacteria). While Heliobacterium modesticaldum, Chlorobi, and “Ca. Chloracidobacterium thermophilum” have a type 1 reaction center (RC1) similar to photosystem I in Cyanobacteria and higher plants, Chloroflexi and Proteobacteria possess a type 2 reaction center (RC2) similar to photosystem II of oxygenic phototrophs (7, 16).Primers based on pufM, the gene encoding the M subunit of RC2, have been widely used to detect phototrophic purple bacteria (1, 4, 12, 19). However, phototrophic bacteria that do not possess RC2 are not retrieved when pufM is used as the target. Achenbach and coworkers (1) developed primers targeting rRNA genes of Chlorobi, Chloroflexi, and heliobacteria, while Alexander and coworkers (2) have developed primers to specifically detect green sulfur bacteria (Chlorobi) by using 16S rRNA and fmoA as gene targets and applied these primers in environmental studies (3). No currently available primer set can simultaneously target phototrophs containing either RC1 or RC2.Since it is well established that both RC1- and RC2-containing anoxygenic phototrophs synthesize bacteriochlorophylls (BChls), we searched for a universal anoxygenic photosynthesis gene marker among all enzymes involved in BChl biosynthetic pathways. All known pathways for chlorophyll and BChl biosynthesis branch from the heme biosynthesis pathway at protoporphyrin IX and continue to chlorophyllide a (Chlide a) through the same intermediates (9). Chlide a is the branching point that separates chlorophyll and BChl biosynthetic pathways. Moreover, pathways for the synthesis of different BChls are also split at this stage: chlorophyllide oxidoreductase converts Chlide a to 3-vinyl-bacteriophyllide a, which is the precursor for BChls a, b, and g, while a yet unknown enzyme reduces Chlide a to 3-vinyl-bacteriophyllide d, a precursor for antenna BChls c, d, and e in Chlorobium spp. (9). Since 3-vinyl-bacteriophyllide a is the last common intermediate in the synthesis of BChl a and BChl g, and the latter is the only BChl in heliobacteria (14, 15), chlorophyllide oxidoreductase is the only enzyme that is (i) present in anoxygenic phototrophic bacteria and not in oxygenic phototrophs and (ii) common to all known anoxygenic phototrophic bacterial species (with the exception of “Ca. Chloracidobacterium thermophilum,” where the pathway for BChl synthesis is not yet known). Analyzing multiple alignments of the subunits of chlorophyllide oxidoreductase, we found that only the Y subunit (encoded by the BchY gene) had two conserved regions distinguishing this protein from its closest homologs; therefore, the bchY gene was chosen as a universal marker for anoxygenic photosynthesis.Due to likely codon variations coding identical amino acid sequences in different genomes (19), degenerate BchY primers were designed by reverse translation of two conserved regions of the BchY alignment (Fig. ​(Fig.1):1): bchY_fwd (5′-CCNCARACNATGTGYCCNGCNTTYGG-3′ [26 bases; 2,048 variants; corresponding amino acid sequence, PQTMCPAFG]) and bchY_rev (5′-GGRTCNRCNGGRAANATYTCNCC-3′ [23 bases; 4,096 variants; corresponding amino acid sequence, GE{I/M}FP{A/ V}DP]). Each primer had no more than two bases deviating from known bchY sequences in the GenBank nr database (except for H. modesticaldum) as well as to environmental BchY variants in the GenBank env_nr database. None of these deviations were located in the 3′ ends of the primers (see Tables S2 and S3 in the supplemental material). These primers, therefore, were predicted to amplify a wide diversity of bchY genes under nonstringent PCR conditions (50 to 52°C annealing temperature). The lengths of the expected PCR products were either 480 bp (for green sulfur, green nonsulfur bacteria, and heliobacteria) or 510 bp (for purple bacteria).Open in a separate windowFIG. 1.Multiple-amino-acid alignment of BchY proteins. Sequence abbreviations: R.den, Roseobacter denitrificans (gi|110677524); R.gel, Rubrivivax gelatinosus (gi|29893484); R.cap, Rhodobacter capsulatus (gi|114868); C.lit, Congregibacter litoralis KT 71 (gi|88706663); H.hal, Halorhodospira halophila (gi|121998388); C.aur, Chloroflexus aurantiacus (gi|163849328); C.tep, Chlorobium tepidum (gi|66576270); and H.mod, Heliobacterium modesticaldum (gi|167629410).In order to check primer specificity in silico, a screening procedure was developed. Putative primer sites (tags) for both the bchY_fwd and the bchY_rev primers were gathered from the GenBank nucleotide collection (nt) by BLAST with relaxed search conditions; the tags having mismatches at the 3′ end or more than five overall mismatches from their primer were filtered out, and the remaining tags were mapped to their sequences mimicking PCR primer annealing. Fragments ranging from 300 to 700 bp (virtual “PCR products”) were retrieved from GenBank and annotated (see Table S4 in the supplemental material). All bchY genes present in the GenBank nt database were virtually “amplified,” pointing to the robustness of the primers and our in silico PCR analysis. On the other hand, all nonspecific “amplicons” have major deviations from the primer sequences and would likely not be amplified by a real PCR. The same screening procedure was performed against the GenBank environmental nucleotide collection (env_nt) (see Table S5 in the supplemental material), and as in the case with the nt database, only bchY fragments were virtually “amplified.”The BchY primer set was validated using five key control organisms, including the RC2-containing the purple sulfur bacterium Allochromatium vinosum and the purple nonsulfur bacterium Rhodobacter capsulatus as well as the RC1-containing green sulfur bacterium Chlorobium limicola, green nonsulfur bacterium Chloroflexus aurantiacus, and the heliobacterium H. modesticaldum. Amplifications yielded the predicted products of 510 bp from the purple bacteria and 480 bp from the green sulfur and nonsulfur bacteria and H. modesticaldum. Negative-control Escherichia coli and Synechocystis sp. strain PCC 6803 did not yield amplification products when the bchY primers were used.The designed BchY primer set successfully amplified bchY genes from DNA obtained from both marine (East Mediterranean Sea) and freshwater (Lake Kinneret) environments (see Table S6 in the supplemental material for best BLASTX hits for selected sequenced fragments). These habitats were chosen for testing due to the previously reported wide diversity of their anoxygenic phototrophs (8, 10, 18, 19). A phylogenetic tree of bchY gene fragments amplified from both freshwater and marine DNA samples is shown in Fig. ​Fig.22.Open in a separate windowFIG. 2.BchY phylogenetic tree based on a maximum likelihood tree to which short sequences were added by ARB parsimony. The branches that appeared on the original maximum likelihood tree are shown with thicker lines. Bootstrap values greater than 50% are indicated next to the branches. Sequences obtained in this study are shown in bold. For reasons of clarity, not all BchY sequences retrieved are shown in the tree. For cases in which a BchY fragment was found in more than three clones, the numbers of clones are given in parentheses. Clones m21_2 and m21_3 are identical to the bchY gene of Hoeflea phototrophica strain DFL-43 (6); the m20_2 clone was identical to the bchY gene of Dinoroseobacter shibae (5).Our study underlines the utility of the bchY gene as a molecular marker for revealing genetic heterogeneity in phototrophic microbial populations. Using both wide-scale bioinformatic analysis and PCR on control strains and naturally occurring microbial community DNA, we have confirmed the specificity and coverage of the proposed degenerate BchY primers.     

Simple and efficient site-directed mutagenesis using two single-primer reactions in parallel to generate mutants for protein structure-function studies

Background  

In protein engineering, site-directed mutagenesis methods are used to generate DNA sequences with mutated codons, insertions or deletions. In a widely used method, mutations are generated by PCR using a pair of oligonucleotide primers designed with mismatching nucleotides at the center of the primers. In this method, primer-primer annealing may prevent cloning of mutant cDNAs. To circumvent this problem we developed an alternative procedure that does not use forward-reverse primer pair in the same reaction.     

Etk/Bmx Regulates Proteinase-Activated-Receptor1 (PAR1) in Breast Cancer Invasion: Signaling Partners,Hierarchy and Physiological Significance

Background

While protease-activated-receptor 1 (PAR₁) plays a central role in tumor progression, little is known about the cell signaling involved.

Methodology/Principal Findings

We show here the impact of PAR₁ cellular activities using both an orthotopic mouse mammary xenograft and a colorectal-liver metastasis model in vivo, with biochemical analyses in vitro. Large and highly vascularized tumors were generated by cells over-expressing wt hPar1, Y397Z hPar1, with persistent signaling, or Y381A hPar1 mutant constructs. In contrast, cells over-expressing the truncated form of hPar1, which lacks the cytoplasmic tail, developed small or no tumors, similar to cells expressing empty vector or control untreated cells. Antibody array membranes revealed essential hPar1 partners including Etk/Bmx and Shc. PAR₁ activation induces Etk/Bmx and Shc binding to the receptor C-tail to form a complex. Y/A mutations in the PAR₁ C-tail did not prevent Shc-PAR₁ association, but enhanced the number of liver metastases compared with the already increased metastases obtained with wt hPar1. We found that Etk/Bmx first binds via the PH domain to a region of seven residues, located between C378-S384 in PAR₁ C-tail, enabling subsequent Shc association. Importantly, expression of the hPar1-7A mutant form (substituted A, residues 378-384), which is incapable of binding Etk/Bmx, resulted in inhibition of invasion through Matrigel-coated membranes. Similarly, knocking down Etk/Bmx inhibited PAR₁-induced MDA-MB-435 cell migration. In addition, intact spheroid morphogenesis of MCF10A cells is markedly disrupted by the ectopic expression of wt hPar1. In contrast, the forced expression of the hPar1-7A mutant results in normal ball-shaped spheroids. Thus, by preventing binding of Etk/Bmx to PAR₁ -C-tail, hPar1 oncogenic properties are abrogated.

Conclusions/Significance

This is the first demonstration that a cytoplasmic portion of the PAR₁ C-tail functions as a scaffold site. We identify here essential signaling partners, determine the hierarchy of binding and provide a platform for therapeutic vehicles via definition of the critical PAR₁ -associating region in the breast cancer signaling niche.     

Stabilization of the α2 isoform of Na,K-ATPase by mutations in a phospholipid binding pocket

The α2 isoform of Na,K-ATPase plays a crucial role in Ca²⁺ handling, muscle contraction, and inotropic effects of cardiac glycosides. Thus, structural, functional, and pharmacological comparisons of α1, α2, and α3 are of great interest. In Pichia pastoris membranes expressing human α1β1, α2β1, and α3β1 isoforms, or using the purified isoform proteins, α2 is most easily inactivated by heating and detergent (α2 ≫ α3 > α1). We have examined an hypothesis that instability of α2 is caused by weak interactions with phosphatidylserine, which stabilizes the protein. Three residues, unique to α2, in trans-membrane segments M8 (Ala-920), M9 (Leu-955), and M10 (Val-981) were replaced by equivalent residues in α1, singly or together. Judged by the sensitivity of the purified proteins to heat, detergent, “affinity” for phosphatidylserine, and stabilization by FXYD1, the triple mutant (A920V/L955F/V981P, called α2VFP) has stability properties close to α1, although single mutants have only modest or insignificant effects. Functional differences between α1 and α2 are unaffected in α2VFP. A compound, 6-pentyl-2-pyrone, isolated from the marine fungus Trichoderma gamsii is a novel probe of specific phospholipid-protein interactions. 6-Pentyl-2-pyrone inactivates the isoforms in the order α2 ≫ α3 > α1, and α2VFP and FXYD1 protect the isoforms. In native rat heart sarcolemma membranes, which contain α1, α2, and α3 isoforms, a component attributable to α2 is the least stable. The data provide clear evidence for a specific phosphatidylserine binding pocket between M8, M9, and M10 and confirm that the instability of α2 is due to suboptimal interactions with phosphatidylserine. In physiological conditions, the instability of α2 may be important for its cellular regulatory functions.