Thermotolerance

Thermotolerance is the ability of an organism to survive high temperatures. An organism's natural tolerance of heat is their basal thermotolerance.^[1] Meanwhile, acquired thermotolerance is defined as an enhanced level of thermotolerance after exposure to a heat stress.^[2]

In plants[edit]

Multiple factors contribute to thermotolerance including signaling molecules like abscisic acid, salicylic acid, and pathways like the ethylene signaling pathway and heat stress response pathway.^[3]

The various heat stress response pathways enhance thermotolerance.^[4] The heat stress response in plants is mediated by heat shock transcription factors (HSF) and is well conserved across eukaryotes. HSFs are essential in plants’ ability to both sense and respond to stress.^[5] The HSFs, which are divided into three families (A, B, and C), encode the expression of heat shock proteins (HSP). Past studies have found that transcriptional activators HsfA1 and HsfB1 are the main positive regulators of heat stress response genes in Arabidopsis thaliana.^[6] The general pathway to thermotolerance is characterized by sensing of heat stress, activation of HSFs, upregulation of heat response, and return to the non-stressed state.^[7]

In 2011, while studying heat stress A. thaliana, Ikeda et al. concluded that the early response is regulated by HsfA1 and the extended response is regulated by HsfA2. They used RT-PCR to analyze the expression of HS-inducible genes of mutant (ectopic and nonfunctional HsfB1) and wild type plants. Plants with mutant HsfB1 had lower acquired thermotolerance, based on both lower expression of heat stress genes and visibly altered phenotypes. With these results they concluded that class A HSFs positively regulated the heat stress response while class B HSFs repressed the expression of HSF genes. Therefore, both were necessary for plants to return to non-stressed conditions and acquired thermotolerance.^[8]

In animals[edit]

References[edit]

^ Bokszczanin, Kamila; Fragkostefanakis, Sotirios; Bostan, Hamed; Bovy, Arnaud; Chaturvedi, Palak; Chiusano, Maria; Firon, Nurit; Iannacone, Rina; Jegadeesan, Sridharan; Klaczynskid, Krzysztof; Li, Hanjing (2013). "Perspectives on deciphering mechanisms underlying plant heat stress response and thermotolerance". Frontiers in Plant Science. 4: 315. doi:10.3389/fpls.2013.00315. ISSN 1664-462X. PMC 3750488. PMID 23986766.
^ De Virgilio, Claudio; Piper, Peter; Boller, Thomas; Wiemken, Andres (1991-08-19). "Acquisition of thermotolerance in Saccharomyces cerevisiae without heat shock protein hsp104 and in the absence of protein synthesis". FEBS Letters. 288 (1–2): 86–90. doi:10.1016/0014-5793(91)81008-V. ISSN 0014-5793. PMID 1831771. S2CID 25550858.
^ Larkindale, Jane; Hall, Jennifer D.; Knight, Marc R.; Vierling, Elizabeth (2005). "Heat Stress Phenotypes of Arabidopsis Mutants Implicate Multiple Signaling Pathways in the Acquisition of Thermotolerance". Plant Physiology. 138 (2): 882–897. doi:10.1104/pp.105.062257. ISSN 0032-0889. JSTOR 4629891. PMC 1150405. PMID 15923322.
^ Sarkar, S.; Islam, A.K.M.Aminul; Barma, N.C.D.; Ahmed, J.U. (May 2021). "Tolerance mechanisms for breeding wheat against heat stress: A review". South African Journal of Botany. 262–277. doi:10.1016/j.sajb.2021.01.003.
^ Liu, Hsiang-chin; Charng, Yee-yung (2012-05-01). "Acquired thermotolerance independent of heat shock factor A1 (HsfA1), the master regulator of the heat stress response". Plant Signaling & Behavior. 7 (5): 547–550. Bibcode:2012PlSiB...7..547L. doi:10.4161/psb.19803. PMC 3419016. PMID 22516818.
^ Yoshida, Takumi; Ohama, Naohiko; Nakajima, Jun; Kidokoro, Satoshi; Mizoi, Junya; Nakashima, Kazuo; Maruyama, Kyonoshin; Kim, Jong-Myong; Seki, Motoaki; Todaka, Daisuke; Osakabe, Yuriko (2011-12-01). "Arabidopsis HsfA1 transcription factors function as the main positive regulators in heat shock-responsive gene expression". Molecular Genetics and Genomics. 286 (5): 321–332. doi:10.1007/s00438-011-0647-7. ISSN 1617-4623. PMID 21931939. S2CID 8284912.
^ Bäurle, Isabel (2016). "Plant Heat Adaptation: priming in response to heat stress". F1000Research. 5: F1000 Faculty Rev–694. doi:10.12688/f1000research.7526.1. ISSN 2046-1402. PMC 4837978. PMID 27134736.
^ Ikeda, Miho; Mitsuda, Nobutaka; Ohme-Takagi, Masaru (2011-11-01). "Arabidopsis HsfB1 and HsfB2b Act as Repressors of the Expression of Heat-Inducible Hsfs But Positively Regulate the Acquired Thermotolerance". Plant Physiology. 157 (3): 1243–1254. doi:10.1104/pp.111.179036. ISSN 0032-0889. PMC 3252156. PMID 21908690.

[1] Bokszczanin, Kamila; Fragkostefanakis, Sotirios; Bostan, Hamed; Bovy, Arnaud; Chaturvedi, Palak; Chiusano, Maria; Firon, Nurit; Iannacone, Rina; Jegadeesan, Sridharan; Klaczynskid, Krzysztof; Li, Hanjing (2013). "Perspectives on deciphering mechanisms underlying plant heat stress response and thermotolerance". Frontiers in Plant Science. 4: 315. doi:10.3389/fpls.2013.00315. ISSN 1664-462X. PMC 3750488. PMID 23986766.

[2] De Virgilio, Claudio; Piper, Peter; Boller, Thomas; Wiemken, Andres (1991-08-19). "Acquisition of thermotolerance in Saccharomyces cerevisiae without heat shock protein hsp104 and in the absence of protein synthesis". FEBS Letters. 288 (1–2): 86–90. doi:10.1016/0014-5793(91)81008-V. ISSN 0014-5793. PMID 1831771. S2CID 25550858.

[3] Larkindale, Jane; Hall, Jennifer D.; Knight, Marc R.; Vierling, Elizabeth (2005). "Heat Stress Phenotypes of Arabidopsis Mutants Implicate Multiple Signaling Pathways in the Acquisition of Thermotolerance". Plant Physiology. 138 (2): 882–897. doi:10.1104/pp.105.062257. ISSN 0032-0889. JSTOR 4629891. PMC 1150405. PMID 15923322.

[Sarkar_S.-4] Sarkar, S.; Islam, A.K.M.Aminul; Barma, N.C.D.; Ahmed, J.U. (May 2021). "Tolerance mechanisms for breeding wheat against heat stress: A review". South African Journal of Botany. 262–277. doi:10.1016/j.sajb.2021.01.003.

[5] Liu, Hsiang-chin; Charng, Yee-yung (2012-05-01). "Acquired thermotolerance independent of heat shock factor A1 (HsfA1), the master regulator of the heat stress response". Plant Signaling & Behavior. 7 (5): 547–550. Bibcode:2012PlSiB...7..547L. doi:10.4161/psb.19803. PMC 3419016. PMID 22516818.

[6] Yoshida, Takumi; Ohama, Naohiko; Nakajima, Jun; Kidokoro, Satoshi; Mizoi, Junya; Nakashima, Kazuo; Maruyama, Kyonoshin; Kim, Jong-Myong; Seki, Motoaki; Todaka, Daisuke; Osakabe, Yuriko (2011-12-01). "Arabidopsis HsfA1 transcription factors function as the main positive regulators in heat shock-responsive gene expression". Molecular Genetics and Genomics. 286 (5): 321–332. doi:10.1007/s00438-011-0647-7. ISSN 1617-4623. PMID 21931939. S2CID 8284912.

[7] Bäurle, Isabel (2016). "Plant Heat Adaptation: priming in response to heat stress". F1000Research. 5: F1000 Faculty Rev–694. doi:10.12688/f1000research.7526.1. ISSN 2046-1402. PMC 4837978. PMID 27134736.

[8] Ikeda, Miho; Mitsuda, Nobutaka; Ohme-Takagi, Masaru (2011-11-01). "Arabidopsis HsfB1 and HsfB2b Act as Repressors of the Expression of Heat-Inducible Hsfs But Positively Regulate the Acquired Thermotolerance". Plant Physiology. 157 (3): 1243–1254. doi:10.1104/pp.111.179036. ISSN 0032-0889. PMC 3252156. PMID 21908690.

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