Proteome-wide analysis of stress response to temperature in Sulfolobus islandicus.

Sulfolobus islandicus is thermophilic archaea that live in an extreme environment of 75 °C-80 °C and pH 2-3. Currently, the molecular mechanism of archaeal adaptation to high temperatures and the stability of proteins at high temperatures are still unclear. This study utilizes proteomics to analyze the differential expression of S. islandicus proteins at different temperatures. We found that ribosomes, glycolysis, nucleotide metabolism, RNA metabolism, transport system, and sulfur metabolism are all affected by temperature. Methylation modification of some proteins changed with temperature. Thermal proteome profiling (TPP) was used to analyze the thermal stability of proteins under 65 °C-85 °C growth conditions. It is suggested that the Tm values of proteins are mainly distributed around the optimum growth temperature (OGT). The proteins in the glycolysis pathway had high thermal stability. Meanwhile, proteins related to DNA replication and translation showed low thermal stability. The protein thermal stability of S. islandicus cultured under 65 °C and 85 °C was higher than that of 75 °C. Our study reveals that S. islandicus may adapt to temperature changes by regulating protein synthesis and carbon metabolism pathways, changing post-translational modifications, and improving protein stability at the same time. SIGNIFICANCE: The molecular mechanism of archaeal adaptation to high temperatures and the stability of proteins at high temperatures are still unclear. Our proteomics study identified 477 differentially expressed proteins of S. islandicus at different temperatures, suggesting that ribosomes, glycolysis, nucleotide metabolism, RNA metabolism, transport system, and sulfur metabolism are affected by temperature. Meanwhile, we found that methylation modification of some proteins changed with temperature. To evaluate the thermal stability of the proteome, we performed thermal proteome profiling to analyze the Tm of proteins under 65 °C-85 °C growth conditions. Tm values of proteins are mainly distributed around the optimum growth temperature. The proteins in the glycolysis pathway had high thermal stability. Meanwhile, proteins related to DNA replication and translation showed low thermal stability. Our study reveals that S. islandicus may adapt to temperature changes by regulating protein synthesis and carbon metabolism pathways, changing post-translational modifications, and improving protein stability at the same time.

Black Phosphorus Nanosheet Encapsulated by Zeolitic Imidazole Framework-8 for Tumor Multimodal Treatments.

Black phosphorus (BP) nanosheet is easily oxidized by oxygen and water under ambient environment, thus, reliable BP passivation techniques for biomedical applications is urgently needed. A simple and applicable passivation strategy for biomedical applications was established by encapsulating BP nanosheet into zeolitic imidazole framework-8 (ZIF-8). The resulted BP nanosheet in ZIF-8 (BP@ZIF-8) shows not only satisfied chemical stability in both water and phosphate buffered saline (PBS), but also excellent biocompatibility. Notably, BP nanosheet endows the prepared BP@ZIF-8 with prominent photothermal conversion efficiency (31.90%). Besides passivation BP, ZIF-8 provides the BP@ZIF-8 with high drug loading amount (1353.3 mg g-1). Moreover, the loaded drug can be controlled release by pH stimuli. Both in vitro and in vivo researches verified the resulted BP@ZIF-8 an ideal candidate for tumor multimodal treatments.