Proteome-level robustness and the role of a histone-like protein during acute heat shock in the hyperthermophilic archaeon Pyrococcus furiosus

The hyperthermophilic archaeon Pyrococcus furiosus thrives in extreme temperatures and exhibits a complex response to heat shock. However, the regulatory dynamics of genetic information during heat shock remain poorly understood. In this study, we exposed P. furiosus (cultured at 90°C) to acute heat shock by boiling (101–102°C) and analyzed its transcriptomic and proteomic responses. The levels of 16 S and 23 S rRNAs and of total tRNA were decreased by approximately 50%, and pre-tRNA splicing was inhibited, indicating suppression of translation. By contrast, approximately 90% of the proteome remained stable, underscoring the robustness of existing proteins. However, the transcriptome exhibited widespread alterations with limited correlation to the proteome (correlation coefficient r = 0.32), except for a few key proteins. These proteins included PF1883 (small heat shock protein), PF1385 (uracil-DNA glycosylase), and PF1616 (inositol-1-phosphate synthase), which are involved in protein chaperoning, stress-related metabolite synthesis, and DNA repair, respectively. Additionally, PF0624, previously annotated as a hypothetical protein, was identified as a putative histone motif-containing protein. Experimental evidence suggests that PF0624 may contribute to chromatin formation via archaeal histones in P. furiosus . In summary, our findings reveal that P. furiosus responds to acute heat shock by maintaining protein stability, suppressing translation, limiting genomic damage, and potentially compacting genomic DNA into archaeal chromatin.