Project description:To validate the oligo array and to investigate the impact of the environmental stressors on dolphin health at transcriptomic level

Project description:Purpose: Gestational exposure to environmental toxins and socioeconomic stressors are epidemiologically linked to neurodevelopmental disorders with strong male-bias, such as autism. We modeled these prenatal risk factors in mice, by co-exposing pregnant dams to an environmental pollutant and limited-resource stress, which robustly activated the maternal immune system. Only male offspring displayed long-lasting behavioral abnormalities and alterations in the activity of brain networks encoding social interactions. Cellularly, prenatal stressors diminished microglial function within the anterior cingulate cortex, a central node of the social coding network, in males during early postnatal development. Genetic ablation of microglia during the same critical period mimicked the impact of prenatal stressors on a male-specific behavior, indicating that environmental stressors alter neural circuit formation in males via impairing microglia function during development.

Project description:Many clinically relevant bacterial pathogens are encapsulated, as exemplified by Salmonella enterica serovar Typhi. S. Typhi, the causative agent of the life-threatening systemic disease enteric fever, expresses Vi as the outermost surface glycan that protects the bacteria from host immune responses. Multidrug-resistant (MDR) and extensively drug-resistant (XDR) S. Typhi strains, as well as Vi variants, are widespread globally. Our WGS analyses indicate that almost all S. Typhi clinical isolates are susceptible to rifamycins and azithromycin. Rifampin, even at sub-MIC levels, eliminates the protective capsule Vi, a process referred to as ‘decapsulation’, thereby enhancing bacterial clearance. Antibiotic-mediated decapsulation of S. Typhi appears specific to rifamycins, since azithromycin does not decapsulate S. Typhi. Rifampin mediated decapsulation occurs at the transcriptional level, where both high AT content and specific RpoB residues play a crucial role. Rifampin also effectively decapsulates Vi variants, which accounts for 1 in 5 S. Typhi isolates at the global level. A mechanistic explanation for rifampin mediated decapsulation of S. Typhi appears to be applicable to other encapsulated pathogens, including S. Paratyphi C.

Project description:To validate the oligo array and to investigate the impact of the environmental stressors on dolphin health at transcriptomic level Collection of blood samples from wild animals in 4 different geographic locations of the South East of the United States

Project description:Multi-species interactions are a major force in the evolution and dynamics of ecosystems. These interactions may occur either when species affect each other directly or when they interact indirectly via an intermediary species. Direct interactions between species are best understood, but indirect interactions may also often be strong enough to alter the evolutionary trajectories of the target species. Little is known about the genetic basis of direct interactions within an ecosystem and even less data is available for indirect interactions. This experiment uses a simple model ecosystem to build a view at the transcriptome level of how interactions between plants (Arabidopsis) and rhizosphere bacteria (Pseudomonas) are altered by biotic stressors (insect herbivores) and abiotic stressors (UV-B). Keywords: stress response

Project description:Lubomirskia baikalensis response to environmental stressors

Project description:Circumventing or overwhelming the bacterial adaptation capabilities is key to combatting multidrug-resistant pathogens like Pseudomonas aeruginosa. We investigated the physiological stress exerted by approved antibiotics (ciprofloxacin, levofloxacin, rifampicin, gentamicin, tobramycin, azithromycin, tigecycline, polymyxin B, colistin, ceftazidime, meropenem, piperacillin/tazobactam), experimental antibiotics (CHIR-090) and NSAIDs (acetylsalicylic acid (aspirin), diclofenac, ibuprofen), and studied the bacterial response on the proteome level. Radioactive pulse-labeling of newly synthesized proteins followed by 2D-PAGE was used to monitor the acute response of P. aeruginosa to antibiotic treatment. Subsequently, marker proteins were excised from non-radioactive gels and identified by mass spectrometry. We generated a reference library of P. aeruginosa proteomic responses and implemented a mathematical comparison of the profiles. Proteomic signatures were derived for clinically relevant target areas.

Project description:Alternative splicing (AS) is a widely observed phenomenon in eukaryotes that plays a critical role in development and stress responses. In plants, the large number of RNA-seq datasets in response to different environmental stressors can provide clues for identification of condition-specific and/or common AS variants for preferred agronomic traits. We report RNA-seq datasets (350.7 Gb) from Capsicum annuum inoculated with one of three bacteria, one virus, or one oomycete and obtained additional existing transcriptome datasets. In this study, we investigated the landscape of AS in response to environmental stressors, signaling molecules, and tissues from 425 total samples comprising 841.49 Gb. In addition, we identified genes that undergo AS under specific and shared stress conditions to obtain potential genes that may be involved in enhancing tolerance to stressors. We uncovered 1,642,007 AS events and identified 4,354 differential alternative splicing (DAS) genes related to environmental stressors, tissues, and signaling molecules. This information and approach provide useful data for basic-research focused on enhancing tolerance to environmental stressors in hot pepper or establishing breeding programs.

Project description:Multi-species interactions are a major force in the evolution and dynamics of ecosystems. These interactions may occur either when species affect each other directly or when they interact indirectly via an intermediary species. Direct interactions between species are best understood, but indirect interactions may also often be strong enough to alter the evolutionary trajectories of the target species. Little is known about the genetic basis of direct interactions within an ecosystem and even less data is available for indirect interactions. This experiment uses a simple model ecosystem to build a view at the transcriptome level of how interactions between plants (Arabidopsis) and rhizosphere bacteria (Pseudomonas) are altered by biotic stressors (insect herbivores) and abiotic stressors (UV-B). Experiment Overall Design: Arabidopsis plants were established and then split into two cohorts at 15 days. One group were innoculated with Pseudomonas aeruginosa strain 7NR and the other not. 21 days later half of each of these groups were subjected to UV-B treatment for seven days. After this period each of the four groups of plants were further subdivided and infested with aphids, caterpillars or left alone. 24 hours after infestation the plants were harvested, individuals pooled and total RNA extracted giving 12 unique conditions. Five replicates were performed in series, yielding a total of 60 samples.

Project description:Azithromycin binds to the nascent peptide exit tunnel (NPET) close to the peptidyltransferase center (PTC) of the ribosome, which obstructs the NPET and subsequently induces ribosome stalling and depletion of intracellular pools of tRNAs. To understand the mechanism through which azithromycin represses the transcription of mutation promoting genes, we utilized ribosome profiling to analyze azithromycin caused redistribution of ribosomes on the cellular mRNAs. Wild type PA14 was treated with 16 mg/L azithromycin for 3 hours.