Molecular cloning, characterization and expression analysis of two apoptosis genes, caspase and nm23, involved in the antibacterial response in Chinese mitten crab, Eriocheir sinensis

Apoptosis is a central regulatory feature of the immune system, and the most common form of death among immunological cells. However, the function of apoptosis, within the innate immune system of invertebrates, remains largely unknown. For this reason, we investigated the immune functionality of two apoptosis genes, caspase and nm23, in the Chinese mitten crab (Eriocheir sinensis), which is a commercially important and disease vulnerable aquaculture species. The entire length caspase and nm23 cDNA genes were cloned using PCR, based on an initial expressed sequence tag (EST) isolated from a hepatopancreatic cDNA library. The caspase cDNA contained an 1119 bp open reading frame that encoded a putative 372 amino acid protein, while nm23 cDNA contained a 456 bp open reading frame that encoded a putative 151 amino acid protein. Comparison, with other reported invertebrate and vertebrate sequences, revealed the presence of conserved enzyme active sites that were common among caspase and nm23 superfamilies. In brief, caspase and nm23 mRNA expression in E. sinensis were (a) both detected in all tissues, including the hemocytes, heart, hepatopancreas, gill, stomach, muscle, intestine, brain and eyestalk, and (b) responsive in hemocytes, gill and hepatopancreas to a Vibrio anguillarum immuno-challenge all appeared sharp increase. Collectively, the data presented here demonstrate the successful isolation of caspase and nm23 apoptosis genes from the Chinese mitten crab, and their role in the innate immune system of an invertebrate.     

Protein Microarray Characterization of the S-Nitrosoproteome

Nitric oxide (NO) mediates a substantial part of its physiologic functions via S-nitrosylation, however the cellular substrates for NO-mediated S-nitrosylation are largely unknown. Here we describe the S-nitrosoproteome using a high-density protein microarray chip containing 16,368 unique human proteins. We identified 834 potentially S-nitrosylated human proteins. Using a unique and highly specific labeling and affinity capture of S-nitrosylated proteins, 138 cysteine residues on 131 peptides in 95 proteins were determined, defining critical sites of NO''s actions. Of these cysteine residues 113 are novel sites of S-nitrosylation. A consensus sequence motif from these 834 proteins for S-nitrosylation was identified, suggesting that the residues flanking the S-nitrosylated cysteine are likely to be the critical determinant of whether the cysteine is S-nitrosylated. We identify eight ubiquitin E3 ligases, RNF10, RNF11, RNF41, RNF141, RNF181, RNF208, WWP2, and UBE3A, whose activities are modulated by S-nitrosylation, providing a unique regulatory mechanism of the ubiquitin proteasome system. These results define a new and extensive set of proteins that are susceptible to NO regulation via S-nitrosylation. Similar approaches could be used to identify other post-translational modification proteomes.It is known that NO regulates the majority of its physiologic function through S-nitrosylation (1). Protein-assisted or small molecule, S-nitrosoglutathione (GSNO)¹ trans-nitrosylation, oxidative S-nitrosation, and metalloprotein-catalyzed S-nitrosylation are the prominent cellular mechanisms that are utilized to S-nitrosylate proteins (2). A number of proteins are known to be S-nitrosylated and this post-translational modification can either activate or inactivate a protein''s biologic activity (1, 3). A number of attempts at probing tissue-specific S-nitrosoproteomes have been made, but the results of these are limited to proteins that are S-nitrosylated to a great degree and which are present at high concentrations (2, 4–6). Recently, to investigate determinants of S-nitrosylation, yeast and human target protein microarrays have been studied. However, these assay were limited because of the small number of proteins present on the chip (7). In addition, many proteins that are known to be S-nitrosylated have been studied through a targeted and biased approach (8). To overcome these shortcomings, we report the use of a 16,368 human protein microarray chip to better define the human S-nitrosoproteome.Ubiquitin is a 76-amino-acid long polypeptide that can be covalently added to lysine residues on targeted proteins either as single monomers or in chains. Ubiquitination of proteins can dramatically alter their function or localization depending on the number of ubiquitin attached and the nature of their linkages. The most well characterized ubiquitin-mediated process is targeting of the protein for degradation by the 26S proteasome, which occurs via poly-ubiquitination linked together through lysine 48 on the ubiquitin monomers. Ubiquitination occurs in a three-step enzymatic process in which the third enzyme, the ubiquitin protein ligase (E3) determines protein target specificity (9). NO S-nitrosylates the RING finger E3 ligases, parkin and XIAP, modifying their function (10, 11). In the case of parkin, S-nitrosylation transiently activates its E3 ligase activity, but ultimately inhibits its activity (12). In contrast, XIAP''s E3 ligase activity is unaffected by S-nitrosylation, but its anti-apoptotic function is compromised (11). Using the 16,368 human protein microarray, we identify a number of NO-regulated E3 ligases, the majority of which are activated by NO-dependent S-nitrosylation.     

Discovery of novel selective inhibitors for EGFR-T790M/L858R

Through a receptor-based and ligand-based combined virtual screening protocol, 21 novel compounds covering 15 scaffolds were identified as novel inhibitors for EGFR-T790M/L858R, among which, 12 of them were identified as selective inhibitors for EGFR-T790M/L858R to wild-type EGFR, and 5 of them exhibited 'dual-effective' to wild-type and mutant EGFR. Meanwhile, their antiproliferative effects toward EGFR high-expressing human lung cancer cell (A549), epidermoid carcinoma cell (A431), and the mutant EGFR-dependent cell (NCI-H1975) were also evaluated.     

The role of T56 in controlling the flexibility of the distal histidine in dehaloperoxidase-hemoglobin from Amphitrite ornata

The activation of dehaloperoxidase-hemoglobin (DHP) to form a ferryl intermediate requires the distal histidine, H55, to act as an acid base catalyst. The lack of ancillary amino acids in the distal pocket to assist in this process makes H55 even more important to the formation of active intermediates than in conventional peroxidases. Therefore, one can infer that the precise conformation H55 may greatly affect the enzymatic activity. Using site-direct mutagenesis at position T56, immediately adjacent to H55, we have confirmed that subtle changes in the conformation of H55 affect the catalytic efficiency of DHP. Mutating T56 to a smaller amino acid appears to permit H55 to rotate with relatively low barriers between conformations in the distal pocket, which may lead to an increase in catalytic activity. On the other hand, larger amino acids in the neighboring site appear to restrict the rotation of H55 due to the steric hindrance. In the case of T56V, which is an isosteric mutation, H55 appears less mobile, but forced to be closer to the heme iron than in wild type. Both proximity to the heme iron and flexibility of motion in some of the mutants can result in an increased catalytic rate, but can also lead to protein inactivation due to ligation of H55 to the heme iron, which is known as hemichrome formation. A balance of enzymatic rate and protein stability with respect to hemichrome formation appears to be optimum in wild type DHP (WT-DHP).     

Tissue-specific expression of Populus C19 GA 2-oxidases differentially regulate above- and below-ground biomass growth through control of bioactive GA concentrations

? Here, we studied the poplar C(19) gibberellin 2-oxidase (GA2ox) gene subfamily. We show that a set of paralogous gene pairs differentially regulate shoot and root development. ? PtGA2ox4 and its paralogous gene PtGA2ox5 are primarily expressed in aerial organs, and overexpression of PtGA2ox5 produced a strong dwarfing phenotype characteristic of GA deficiency. Suppression of PtGA2ox4 and PtGA2ox5 led to increased biomass growth, but had no effect on root development. By contrast, the PtGA2ox2 and PtGA2ox7 paralogous pair was predominantly expressed in roots, and when these two genes were RNAi-suppressed it led to a decrease of root biomass. ? The morphological changes in the transgenic plants were underpinned by tissue-specific increases in bioactive GAs that corresponded to the predominant native expression of the targeted paralogous gene pair. Although RNAi suppression of both paralogous pairs led to changes in wood development, they were much greater in the transgenics with suppressed PtGA2ox4 and PtGA2ox5. The degree of gene suppression in independent events was strongly associated with phenotypes, demonstrating dose-dependent control of growth by GA2ox RNA concentrations. ? The expression and transgenic modifications reported here show that shoot- and leaf-expressed PtGA2ox4 and PtGA2ox5 specifically restrain aerial shoot growth, while root-expressed PtGA2ox2 and PtGA2ox7 promote root development.     

Genome Sequences of the Primary Endosymbiont “Candidatus Portiera aleyrodidarum” in the Whitefly Bemisia tabaci B and Q Biotypes

“Candidatus Portiera aleyrodidarum” is the obligate primary endosymbiotic bacterium of whiteflies, including the sweet potato whitefly Bemisia tabaci, and provides essential nutrients to its host. Here we report two complete genome sequences of this bacterium from the B and Q biotypes of B. tabaci.     

Bacterial Diversity and Function of Aerobic Granules Engineered in a Sequencing Batch Reactor for Phenol Degradation

Aerobic granules are self-immobilized aggregates of microorganisms and represent a relatively new form of cell immobilization developed for biological wastewater treatment. In this study, both culture-based and culture-independent techniques were used to investigate the bacterial diversity and function in aerobic phenol- degrading granules cultivated in a sequencing batch reactor. Denaturing gradient gel electrophoresis (DGGE) analysis of PCR-amplified 16S rRNA genes demonstrated a major shift in the microbial community as the seed sludge developed into granules. Culture isolation and DGGE assays confirmed the dominance of β-Proteobacteria and high-G+C gram-positive bacteria in the phenol-degrading aerobic granules. Of the 10 phenol-degrading bacterial strains isolated from the granules, strains PG-01, PG-02, and PG-08 possessed 16S rRNA gene sequences that matched the partial sequences of dominant bands in the DGGE fingerprint belonging to the aerobic granules. The numerical dominance of strain PG-01 was confirmed by isolation, DGGE, and in situ hybridization with a strain-specific probe, and key physiological traits possessed by PG-01 that allowed it to outcompete and dominate other microorganisms within the granules were then identified. This strain could be regarded as a functionally dominant strain and may have contributed significantly to phenol degradation in the granules. On the other hand, strain PG-08 had low specific growth rate and low phenol degradation ability but showed a high propensity to autoaggregate. By analyzing the roles played by these two isolates within the aerobic granules, a functional model of the microbial community within the aerobic granules was proposed. This model has important implications for rationalizing the engineering of ecological systems.     

AEBP1 upregulation confers acquired resistance to BRAF (V600E) inhibition in melanoma

An activating BRAF (V600E) kinase mutation occurs in approximately half of melanomas. Recent clinical studies have demonstrated that vemurafenib (PLX4032) and dabrafenib, potent and selective inhibitors of mutant v-raf murine sarcoma viral oncogene homolog B1 (BRAF), exhibit remarkable activities in patients with V600 BRAF mutant melanomas. However, acquired drug resistance invariably develops after the initial treatment. Identification of acquired resistance mechanisms may inform the development of new therapies that elicit long-term responses of melanomas to BRAF inhibitors. Here we report that increased expression of AEBP1 (adipocyte enhancer-binding protein 1) confers acquired resistance to BRAF inhibition in melanoma. AEBP1 is shown to be highly upregulated in PLX4032-resistant melanoma cells because of the hyperactivation of the PI3K/Akt-cAMP response element-binding protein (CREB) signaling pathway. This upregulates AEBP1 expression and thus leads to the activation of NF-κB via accelerating IκBa degradation. In addition, inhibition of the PI3K/Akt-CREB-AEBP1-NF-κB pathway greatly reverses the PLX4032-resistant phenotype of melanoma cells. Furthermore, increased expression of AEBP1 is validated in post-treatment tumors in patients with acquired resistance to BRAF inhibitor. Therefore, these results reveal a novel PI3K/Akt-CREB-AEBP1-NF-κB pathway whose activation contributes to acquired resistance to BRAF inhibition, and suggest that this pathway, particularly AEBP1, may represent a novel therapeutic target for treating BRAF inhibitor-resistant melanoma.     

Highly efficient genome editing in Xanthomonas oryzae pv. oryzae through repurposing the endogenous type I-C CRISPR-Cas system

Efficient and modular genome editing technologies that manipulate the genome of bacterial pathogens will facilitate the study of pathogenesis mechanisms. However, such methods are yet to be established for Xanthomonas oryzae pv. oryzae (Xoo), the causal agent of rice bacterial blight. We identified a single type I-C CRISPR-Cas system in the Xoo genome and leveraged this endogenous defence system for high-efficiency genome editing in Xoo. Specifically, we developed plasmid components carrying a mini-CRISPR array, donor DNA, and a phage-derived recombination system to enable the efficient and programmable genome editing of precise deletions, insertions, base substitutions, and gene replacements. Furthermore, the type I-C CRISPR-Cas system of Xoo cleaves target DNA unidirectionally, and this can be harnessed to generate large genomic deletions up to 212 kb efficiently. Therefore, the genome-editing strategy we have developed can serve as an excellent tool for functional genomics of Xoo, and should also be applicable to other CRISPR-harbouring bacterial plant pathogens.