Project description:Bacterial community of weathered rock in Heshang Cave

Project description:Fungal community of weathered rock in Heshang Cave

Project description:Bacterial and Archaeal Diversity in Sulfide-bearing Waste Rock at Faro Mine Complex, Yukon Territory, Canada

Project description:Microbial communities from weathered outcrops of a sulfide-rich ultramafic intrusion

Project description:The microbiome of rock grains weathered in the soil environment.

Project description:Tire-wear particles (TWPs) are considered among the largest contributors of microplastics to the environment. They are subject to break-down due to environmental weathering, which allows for potentially toxic chemicals to be leached from and sorbed onto the particles. In this study, leachate generated from “weathered” and “un-weathered” TWPs were used for sublethal toxicity tests with Americamysis bahia.

Project description:To investigate the virological properties of SARS-CoV-2 variants, we amplified the clinical isolates of an early pandemic D614G-bearing isolate (B.1.1 lineage, strain TKYE610670; GISAID ID: EPI_ISL_479681), a Delta isolate (B.1.617.2 lineage, strain TKYTK1734; GISAID ID: EPI_ISL_2378732) and an Omicron isolate (BA.1 lineage, strain TY38-873; GISAID ID: EPI_ISL_7418017) and prepared the working viruses.

Project description:The effect of sulfide stress on Desulfovibrio vulgaris Hildenborough (DvH) gene expression was determined by comparing the gene expression profiles of DvH under conditions in which sulfide was allowed to accumulate (high sulfide, average concentration 10 mM) against DvH cells grown under conditions in which sulfide was removed by continuous gassing (low sulfide, average concentration 1 mM). High sulfide significantly decreased the instantaneous growth rate constant and final cell density of the culture indicating a decreased bioenergetic fitness. Changes in gene expression caused by exposure to high sulfide were determined using full-genome DvH microarrays. The transcription of ribosomal protein-encoding genes was decreased, in agreement with the lower growth rate of DvH under high sulfide conditions. Interestingly, expression of the gene for DsrD, located downstream of the genes for dissimilatory sulfite reductase (DsrAB) was also strongly down-regulated. In contrast, the expression of many genes involved in iron accumulation, stress response and proteolysis, and chemotaxis were increased. This indicates that high sulfide represents a significant stress condition, in which the bioavailability of metals like iron may be lowered and in which proteins (e.g. metalloenzymes) may need to be refolded, or proteolytically degraded. Overall this leads to a reduced growth rate and less efficient biomass production with available resources. For each condition 2 unique biological samples were hybridized to 4 arrays that each contained duplicate spots. Genomic DNA was used as universal reference.

Project description:The effect of sulfide stress on Desulfovibrio vulgaris Hildenborough (DvH) gene expression was determined by comparing the gene expression profiles of DvH under conditions in which sulfide was allowed to accumulate (high sulfide, average concentration 10 mM) against DvH cells grown under conditions in which sulfide was removed by continuous gassing (low sulfide, average concentration 1 mM). High sulfide significantly decreased the instantaneous growth rate constant and final cell density of the culture indicating a decreased bioenergetic fitness. Changes in gene expression caused by exposure to high sulfide were determined using full-genome DvH microarrays. The transcription of ribosomal protein-encoding genes was decreased, in agreement with the lower growth rate of DvH under high sulfide conditions. Interestingly, expression of the gene for DsrD, located downstream of the genes for dissimilatory sulfite reductase (DsrAB) was also strongly down-regulated. In contrast, the expression of many genes involved in iron accumulation, stress response and proteolysis, and chemotaxis were increased. This indicates that high sulfide represents a significant stress condition, in which the bioavailability of metals like iron may be lowered and in which proteins (e.g. metalloenzymes) may need to be refolded, or proteolytically degraded. Overall this leads to a reduced growth rate and less efficient biomass production with available resources.

Project description:Weathered Oil Microbiome Metagenome