Your search keyword '"Batarseh SN"' showing total 4 results

1. Role for Caspase-8 in the Release of IL-1β and Active Caspase-1 from Viable Human Monocytes during Toxoplasma gondii Infection.

Author

Pandori WJ, Matsuno SY, Shin JH, Kim SC, Kao TH, Mallya S, Batarseh SN, and Lodoen MB

Subjects

Humans, Caspase 1 metabolism, Gasdermins, Inflammasomes metabolism, Monocytes, NLR Family, Pyrin Domain-Containing 3 Protein metabolism, Caspase 8 metabolism, Interleukin-1beta metabolism, Toxoplasma, Toxoplasmosis metabolism

Abstract

Monocytes are actively recruited to sites of infection and produce the potent proinflammatory cytokine IL-1β. We previously showed that IL-1β release during Toxoplasma gondii infection of primary human monocytes requires the NLRP3 inflammasome and caspase-1 but is independent of gasdermin D and pyroptosis. To investigate mechanisms of IL-1β release, we generated caspase-1, -4, -5, or -8 knockout (KO) THP-1 monocytic cells. Genetic ablation of caspase-1 or -8, but not caspase-4 or -5, decreased IL-1β release during T. gondii infection without affecting cell death. In contrast, TNF-α and IL-6 secretion were unperturbed in caspase-8 KO cells during T. gondii infection. Dual pharmacological inhibition of caspase-8 and RIPK1 in primary monocytes also decreased IL-1β release without affecting cell viability or parasite infection. Caspase-8 was also required for the release of active caspase-1 from T. gondii-infected cells and for IL-1β release during infection with the related apicomplexan parasite Neospora caninum. Surprisingly, caspase-8 deficiency did not impair synthesis or cleavage of pro-IL-1β, but resulted in the retention of mature IL-1β within cells. Generation of gasdermin E KO and ATG7 KO THP-1 cells revealed that the release of IL-1β was not dependent on gasdermin E or ATG7. Collectively, our data indicate that during T. gondii Infection of human monocytes, caspase-8 functions in a novel gasdermin-independent mechanism controlling IL-1β release from viable cells. This study expands on the molecular pathways that promote IL-1β in human immune cells and provides evidence of a role for caspase-8 in the mechanism of IL-1β release during infection., (Copyright © 2024 by The American Association of Immunologists, Inc.)

Published

2024

2. Comparative genomics of the Liberibacter genus reveals widespread diversity in genomic content and positive selection history.

Author

Batarseh TN, Batarseh SN, Morales-Cruz A, and Gaut BS

Abstract

' Candidatus Liberibacter' is a group of bacterial species that are obligate intracellular plant pathogens and cause Huanglongbing disease of citrus trees and Zebra Chip in potatoes. Here, we examined the extent of intra- and interspecific genetic diversity across the genus using comparative genomics. Our approach examined a wide set of Liberibacter genome sequences including five pathogenic species and one species not known to cause disease. By performing comparative genomics analyses, we sought to understand the evolutionary history of this genus and to identify genes or genome regions that may affect pathogenicity. With a set of 52 genomes, we performed comparative genomics, measured genome rearrangement, and completed statistical tests of positive selection. We explored markers of genetic diversity across the genus, such as average nucleotide identity across the whole genome. These analyses revealed the highest intraspecific diversity amongst the ' Ca. Liberibacter solanacearum' species, which also has the largest plant host range. We identified sets of core and accessory genes across the genus and within each species and measured the ratio of nonsynonymous to synonymous mutations (dN/dS) across genes. We identified ten genes with evidence of a history of positive selection in the Liberibacter genus, including genes in the Tad complex, which have been previously implicated as being highly divergent in the ' Ca. L. capsica' species based on high values of dN., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Batarseh, Batarseh, Morales-Cruz and Gaut.)

Published

2023

3. Phenotypic and Genotypic Adaptation of Escherichia coli to Thermal Stress is Contingent on Genetic Background.

Author

Batarseh TN, Batarseh SN, Rodríguez-Verdugo A, and Gaut BS

Subjects

Adaptation, Physiological genetics, Phenotype, Genotype, Mutation, Genetic Background, Epistasis, Genetic, Escherichia coli genetics, Escherichia coli metabolism, Evolution, Molecular

Abstract

Evolution can be contingent on history, but we do not yet have a clear understanding of the processes and dynamics that govern contingency. Here, we performed the second phase of a two-phase evolution experiment to investigate features of contingency. The first phase of the experiment was based on Escherichia coli clones that had evolved at the stressful temperature of 42.2 °C. The Phase 1 lines generally evolved through two adaptive pathways: mutations of rpoB, which encodes the beta subunit of RNA polymerase, or through rho, a transcriptional terminator. We hypothesized that epistatic interactions within the two pathways constrained their future adaptative potential, thus affecting patterns of historical contingency. Using ten different E. coli Founders representing both adaptive pathways, we performed a second phase of evolution at 19.0 °C to investigate how prior genetic divergence or adaptive pathway (rpoB vs. rho) affects evolutionary outcomes. We found that phenotype, as measured by relative fitness, was contingent on founder genotypes and pathways. This finding extended to genotypes, because E. coli from different Phase 1 histories evolved by adaptive mutations in distinct sets of genes. Our results suggest that evolution depends critically on genetic history, likely due to idiosyncratic epistatic interactions within and between evolutionary modules., (© The Author(s) 2023. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published

2023

4. Genetic Mutations That Drive Evolutionary Rescue to Lethal Temperature in Escherichia coli.

Author

Batarseh TN, Hug SM, Batarseh SN, and Gaut BS

Subjects

Gene Expression, Hot Temperature, Acclimatization genetics, Biological Evolution, Escherichia coli genetics, Genetic Fitness, Mutation

Abstract

Evolutionary rescue occurs when adaptation restores population growth against a lethal stressor. Here, we studied evolutionary rescue by conducting experiments with Escherichia coli at the lethal temperature of 43.0 °C, to determine the adaptive mutations that drive rescue and to investigate their effects on fitness and gene expression. From hundreds of populations, we observed that ∼9% were rescued by genetic adaptations. We sequenced 26 populations and identified 29 distinct mutations. Of these populations, 21 had a mutation in the hslVU or rpoBC operon, suggesting that mutations in either operon could drive rescue. We isolated seven strains of E. coli carrying a putative rescue mutation in either the hslVU or rpoBC operon to investigate the mutations' effects. The single rescue mutations increased E. coli's relative fitness by an average of 24% at 42.2 °C, but they decreased fitness by 3% at 37.0 °C, illustrating that antagonistic pleiotropy likely affected the establishment of rescue in our system. Gene expression analysis revealed only 40 genes were upregulated across all seven mutations, and these were enriched for functions in translational and flagellar production. As with previous experiments with high temperature adaptation, the rescue mutations tended to restore gene expression toward the unstressed state, but they also caused a higher proportion of novel gene expression patterns. Overall, we find that rescue is infrequent, that it is facilitated by a limited number of mutational targets, and that rescue mutations may have qualitatively different effects than mutations that arise from evolution to nonlethal stressors., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2020