G. Eggers-Schumacher scite author profile

Heat shock factors (HSFs) are transcriptional regulators of the heat shock response. The major target of HSFs are the genes encoding heat shock proteins (HSPs), which are known to have a protective function that counteracts cytotoxic effects. To identify other HSF target genes, which may be important determinants for the generation of stress tolerance in Arabidopsis, we screened a library enriched for genes that are up-regulated in HSF3 (AtHsfA1b)-overexpressing transgenic plants (TPs). Galactinol synthase1 (GolS1) is one of the genes that is heat-inducible in wild type, but shows constitutive mRNA levels in HSF3 TPs. The generation and analysis of TPs containing GolS1-promoter::b-glucuronidase-reporter gene constructs showed that, upon heat stress, the expression is transcriptionally controlled and occurs in all vegetative tissues. Functional consequences of GolS1 expression were investigated by the quantification of raffinose, stachyose, and galactinol contents in wild type, HSF3 TPs, and two different GolS1 knockout mutants (gols1-1 and gols1-2). This analysis demonstrates that (1) raffinose content in leaves increases upon heat stress in wild-type but not in the GolS1 mutant plants; and (2) the level of raffinose is enhanced and stachyose is present at normal temperature in HSF3 TPs. These data provide evidence that GolS1 is a novel HSF target gene, which is responsible for heat stress-dependent synthesis of raffinose, a member of the raffinose family oligosaccharides. The biological function of this osmoprotective substance and the role of HSF-dependent genes in this biochemical pathway are discussed.

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HSF3, a new heat shock factor from Arabidopsis thaliana, derepresses the heat shock response and confers thermotolerance when overexpressed in transgenic plants

Prändl¹,

Hinderhofer²,

et al. 1998

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Organisms synthesize heat shock proteins (HSPs) in response to sublethal heat stress and concomitantly acquire increased tolerance against a subsequent, otherwise lethal, heat shock. Heat shock factor (HSF) is essential for the transcription of many HSP genes. We report the isolation of two HSF genes, HSF3 and HSF4, from an Arabidopsis cDNA library. Transgenic Arabidopsis plants were generated containing constructs that allow expression of HSF3 and HSF4 or the respective translational beta-glucuronidase (GUS) fusions. Overexpression of HSF3 or HSF3-GUS, but not of HSF4 or HSF4-GUS, causes HSP synthesis at the non-heat-shock temperature of 25 degrees C in transgenic Arabidopsis. In transgenic plants bearing HSF3/HSF3-GUS, transcription of several heat shock genes is derepressed. Electrophoretic mobility shift assays suggest that derepression of the heat shock response is mediated by HSF3/HSF3-GUS functioning as transcription factor. HSF3/HSF3-GUS-overexpressing Arabidopsis plants show an increase in basal thermotolerance, indicating the importance of HSFs and HSF-regulated genes as determinants of thermoprotective processes. Plants transgenic for HSF3/HSF3-GUS exhibit no other obvious phenotypic alterations. Derepression of HSF activity upon overexpression suggests the titration of a negative regulator of HSF3 or an intrinsic constitutive activity of HSF3. We assume that stable overexpression of HSFs may be applied to other organisms as a means of derepressing the heat shock response.

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Two different heat shock transcription factors regulate immediate early expression of stress genes in Arabidopsis

et al. 2004

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Two different heat shock transcription factors regulate immediate early expression of stress genes in Arabidopsis

et al. 2003

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In order to assess the specific functional roles of different plant heat shock transcription factors (HSFs) we have isolated T-DNA insertion mutants in the AtHsf1 and AtHsf3 genes of Arabidopsis thaliana. Complete and selective loss of the promoter binding activities of AtHSF1 or AtHSF3, verified by immunoprecipitation assays, had no obvious effects on the heat shock (HS) response in the individual mutant lines. Only hsf1(-) /hsf3(-)double mutants were significantly impaired in HS gene expression. In these plants the inability to form high-molecular-weight HSE-binding complexes correlates with a dramatic change in the kinetics of mRNA accumulation from all HSF target genes tested, including members of the Hsp100, Hsp90, Hsp70 and small Hsp families, and genes for two heat-inducible class B-HSFs. After prolonged HS, the amounts of most heat shock mRNAs expressed, except transcripts of Hsp18.2, reached approximately the same levels as in wild type plants. Our data indicate that AtHSF1 and AtHSF3 are key regulators of the immediate stress-induced activation of HS gene transcription, and consequently determine the kinetics of the negative feed back loop that is responsible for the transience of HS gene expression in wild type.

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Stabilization of erythrocytes by aldehydes and suitability of chicken IgY for the detection of potato virus X (PVX) in avidin-biotin enhanced reverse passive haemagglutination

Grossmann

Eggers-Schumacher

Sander

1995

Journal of Immunological Methods

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