Low-coverage massively parallel pyrosequencing of cDNAs enables proteomics in non-model species: comparison of a species-specific database generated by pyrosequencing with databases from related species for proteome analysis of pea chloroplast envelopes

Proteomics is a valuable tool for establishing and comparing the protein content of defined tissues, cell types, or subcellular structures. Its use in non-model species is currently limited because the identification of peptides critically depends on sequence databases. In this study, we explored the potential of a preliminary cDNA database for the non-model species Pisum sativum created by a small number of massively parallel pyrosequencing (MPSS) runs for its use in proteomics and compared it to comprehensive cDNA databases from Medicago truncatula and Arabidopsis thaliana created by Sanger sequencing. Each database was used to identify proteins from a pea leaf chloroplast envelope preparation. It is shown that the pea database identified more proteins with higher accuracy, although the sequence quality was low and the sequence contigs were short compared to databases from model species. Although the number of identified proteins in non-species-specific databases could potentially be increased by lowering the threshold for successful protein identifications, this strategy markedly increases the number of wrongly identified proteins. The identification rate with non-species-specific databases correlated with spectral abundance but not with the predicted membrane helix content, and strong conservation is necessary but not sufficient for protein identification with a non-species-specific database. It is concluded that massively parallel sequencing of cDNAs substantially increases the power of proteomics in non-model species.     

Alteration of superoxide- and nitric oxide-mediated antimicrobial function of macrophages by in vivo cocaine exposure

Cocaine is a popular drug of abuse and despite impressive advances in the understanding of its physiological, pharmacological, and toxic effects, its mechanism of immunosuppression at the cellular level is not well understood. In this paper we report the role of effector molecules like superoxide and nitric oxide in the antibacterial function of macrophages exposed to acute and chronic doses of cocaine in vivo. Bacterial killing by acute cocaine-exposed macrophages (ACE-Mphis) increased significantly, with a concomitant rise in respiratory burst and generation of superoxide and nitric oxide, compared with control macrophages. In contrast, chronic cocaine-exposed macrophages (CCE-Mphis) exhibited limited antimicrobial activity, which correlated closely with diminished respiratory burst and reduced production of superoxide and nitric oxide. Further, a killing assay was carried out in the presence of N(G)-methyl-L-arginine acetate, an inhibitor of iNOS, to evaluate the role of nitric oxide in the killing process. The results obtained indicate that while about 30% killing of input bacteria by control and ACE-Mphis was attributable to NO-mediated killing, only about 6% killing from NO was found with CCE-Mphis. The findings indicate that acute exposure to cocaine possibly caused upregulation of enzymes responsible for the generation of ROI (reactive oxygen intermediates) and RNI (reactive nitrogen intermediates), leading to enhanced antimicrobial function. On the other hand, chronic exposure to cocaine impaired the oxygen-dependent microbicidal capacity of macrophages, possibly through impaired expression of enzymes responsible for ROI and RNI formation. Proinflammatory cytokines may play a key role in cocaine-mediated immunosuppression, since exposure of macrophages to cocaine impairs the ability of the cells to produce these cytokines.     

Biological control of bacterial spot disease and plant growth-promoting effects of lactic acid bacteria on pepper

In our previous studies, we observed the biological control effect of lactic acid bacteria strains (LABs) KLF01, KLC02 and KPD03 against different plant pathogenic bacteria in vitro against Ralstonia solanacearum, and strains KLF01 and KLC02 against Pectobacterium carotovorum under greenhouse and field experiments, respectively. In this study, we observed the efficacy of these bacteria against bacterial spot pathogen (Xanthomonas campestris pv. vesicatoria) and their plant growth-promoting activities in pepper (Capsicum annuum L. var. annuum), under greenhouse and field conditions. LABs significantly (P < 0.05) reduced bacterial spot on pepper plants in comparison to untreated plants in both the greenhouse and the field experiments. The plant growth-promoting effect of LABs on pepper varied; some strains had a significant effect on growth promotion (P < 0.05) compared with untreated plants, while some showed no significant effect in the greenhouse and field experiments. Additionally, LABs were able to colonise roots, produce indole-3-acetic acid (IAA), siderophores and solubilise phosphate. These findings indicate that application of LABs could provide a promising alternative for the management of bacterial spot disease in pepper plants and could therefore be used as a healthy plant growth-promoting agent.     

Epigenetic variation in OPRM1 gene in opioid‐exposed mother‐infant dyads

Neonatal abstinence syndrome (NAS) due to in‐utero opioid exposure has significant variability of severity. Preliminary studies have suggested that epigenetic variation within the μ‐opioid receptor (OPRM1) gene impacts NAS. We aimed to determine if DNA methylation in OPRM1 within opioid‐exposed mother‐infant dyads is associated with differences in NAS severity in an independent cohort. Full‐term opioid‐exposed newborns and their mothers (N = 68 pairs) were studied. A DNA sample was obtained and then assessed for level of DNA methylation at 20 CpG sites within the OPRM1 promoter region by next‐generation sequencing. Infants were monitored for NAS and treated with replacement opioids according to institutional protocol. The association between DNA methylation level at each CpG site with NAS outcome measures was evaluated using linear and logistic regression models. Higher methylation levels within the infants at the ?18 (11.4% vs 4.4%, P = .0001), ?14 (46.1% vs 24.0%, P = .002) and +23 (26.3% vs 12.9%, P = .008) CpG sites were associated with higher rates of infant pharmacologic treatment. Higher levels of methylation within the mothers at the ?169 (R = 0.43, P = .008), ?152 (R = 0.40, P = .002) and +84 (R = 0.44, P = .006) sites were associated point‐wise with longer infant length of stay. Maternal associations remained significant point‐wise for ?169 (β = 0.07, P = .007) and on an experiment‐wise level for +84 (β = ?0.10, P = .003) using regression models. These results suggest an association of higher levels of OPRM1 methylation at specific CpG sites and increased NAS severity, replicating prior findings. These findings have important implications for personalized treatment regimens for infants at high risk for severe NAS.