Cloning and identification of grass carp transcription factor HSF1 and its characterization involving the production of fish HSP70

HSF1 Mediates Palmitic Acid-Disrupted Lipid Metabolism and Inflammatory Response by Maintaining Endoplasmic Reticulum Homeostasis in Fish

Fish oil (FO) is being progressively replaced by palm oil (PO), which is rich in palmitic acid (PA). However, our understanding of the effects of PA on fish and the underlying molecular mechanisms remains limited. Heat shock transcription factor 1 (HSF1) is a critical transcription factor involved in stress response, but whether it responds to the effects of PA in fish remains unknown. In this study, in vitro and in vivo experiments were combined to investigate the molecular mechanisms by which HSF1 responds to PA. Our results indicated that PA induced fat accumulation, inflammation, and activation of protein processing in the endoplasmic reticulum (PPER) in the PaL cells. Moreover, the nuclear translocation of HSF1 was significantly increased by PA. After HSF1 was disrupted using small molecules (HSF1A and KRIBB11) or through HSF1A knockout, the PA-induced fat accumulation and expression levels of key genes related to PPER, lipid metabolism, and inflammation were significantly altered. Additionally, the analysis of CUT&Tag sequencing and dual-luciferase reporter showed that HSF1 protein can directly bind to the promoters of genes involved in PPER, lipid metabolism, and inflammatory response, thereby activating their transcriptional activity, especially HSC70, HSP90α, and HSP90β. Eicosapentaenoic acid (EPA) supplementation significantly improved the survival rate and growth performance of juvenile silver pomfret and reduced PA-induced adverse effects by inhibiting the activation of HSF1 in the liver. This study proves that HSF1 protein may respond to PA-induced lipid metabolism disorder and inflammatory response by maintaining endoplasmic reticulum stability in fish. Furthermore, EPA supplementation effectively counteracts PA-induced adverse effects.

Intermolecular Interactions between Cysteine and Aromatic Amino Acids with a Phenyl Moiety in the DNA-Binding Domain of Heat Shock Factor 1 Regulate Thermal Stress-Induced Trimerization

In this study, we investigated the trimerization mechanism and structure of heat shock factor 1 (HSF1) using western blotting, tryptophan (Trp) fluorescence spectroscopy, and molecular modeling. First, we examined the DNA-binding domains of human (Homo sapiens), goldfish (Carassius auratus), and walleye pollock (Gadus chalcogrammus) HSF1s by mutating key residues (36 and 103) that are thought to directly affect trimer formation. Human, goldfish, and walleye pollock HSF1s contain cysteine at residue 36 but cysteine (C), tyrosine (Y), and phenylalanine (F), respectively, at residue 103. The optimal trimerization temperatures for the wild-type HSF1s of each species were found to be 42, 37, and 20 °C, respectively. Interestingly, a mutation experiment revealed that trimerization occurred at 42 °C when residue 103 was cysteine, at 37 °C when it was tyrosine, and at 20 °C when it was phenylalanine, regardless of the species. In addition, it was confirmed that when residue 103 of the three species was mutated to alanine, trimerization did not occur. This suggests that in addition to trimerization via disulfide bond formation between the cysteine residues in human HSF1, trimerization can also occur via the formation of a different type of bond between cysteine and aromatic ring residues such as tyrosine and phenylalanine. We also confirmed that at least one cysteine is required for the trimerization of HSF1s, regardless of its position (residue 36 or 103). Additionally, it was shown that the trimer formation temperature is related to growth and survival in fish.

Cloning and characterization of heat shock transcription factor 1 and its functional role for Hsp70 production in the sea slug Onchidium reevesii

To investigate the regulatory role of heat shock transcription factor 1 of sea slug Onchidium reevesii (OrHSF1) on Hsp70 expression in the sea slug under stress , the OrHSF1 gene was cloned and bioinformatics analysis was performed, then the gene and protein expressions by RNA interference (RNAi) mediated knockdown of OrHSF1 expression were measured to clarify the regulatory relationship between OrHSF1 and Hsp70 under low-frequency noise (LFN) stress. Our study was the first to clone a 1572 bp sequence of the OrHSF1 gene, with the sequence coding for amino acids (CDS) being 729 bp, encoding 243 amino acids. O. reevesii shared a close evolutionary relationship with mollusks such as the Aplysia californica. OrHSF1 gene is widely expressed in different tissues of sea slugs, with the highest expression in the intestine and the lowest in the reproductive glands. Furthermore, we used RNA interference (RNAi) as a tool to silence the OrHSF1 gene in the central nervous system (CNS) and the results indicated that gene silencing was occurring systematically in the CNS and the suppression of OrHSF1 expression by RNAi-mediated gene silencing altered the expression of Hsp70; besides, the expression trends of OrHSF1 gene and Hsp70 were consistent in the 3 and 5-day RNAi experiment. Moreover, in sea slugs injected with siHSF1 and exposed to LFN, the mRNA expression and protein expression of Hsp70 in the CNS were significantly decreased compared to the low-frequency noise group (P < 0.05). This study demonstrated that OrHSF1 regulates Hsp70 expression in marine mollusks under low-frequency noise, and HSF1-Hsp70 axis plays a key role in stress response.