Differential expression of heat-shock proteins and spontaneous synthesis of HSP70 during the life cycle of Blastocladiella emersonii (original) (raw)
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Acta Physiologiae Plantarum, 2011
Tissue-specific variation in Hsp70 and Hsp90 expression was studied in vegetative (leaf) and reproductive organs (floral tube, ovary and stamen) of Iris pumila plants originating from a sun-exposed and a shaded natural population, which experienced similar growth conditions in an experimental garden. Western blot analysis revealed the presence of both the Hsps in all examined tissues, but at different amounts. In addition to Hsp90a and Hsp90b that were previously detected in vegetative tissues, three new immunospecific bands, designated herein as Hsp90c, Hsp90d and Hsp90e, were recognized with the same anti-Hsp90 antibody in the reproductive tissues. Apart from showing tissue-specific differences in the relative amount of Hsp70 and Hsp90, our study provides evidence that the degree of Hsps expression within the same tissue also depended on the habitat type that the I. pumila plants were derived from.
Environmental and Experimental Botany, 2018
The roles of three different classes of HSP genes were investigated over control and salt stress conditions. Methodologically, the endogenous HSP genes of N. benthamiana transiently silenced by corresponding heterologous sequences isolated from Capparis spinosa L. using a virus system of gene silencing. Silencing of HSP70, compared to other two HSPs, resulted in stronger negative effects on growth and physiological parameters especially under salinity conditions. Loss of function of molecular chaperones following gene silencing might be partially compensated with a higher accumulation of proline to protect membranes and proteins from stress-related damages. Heat shock proteins (HSPs) have vital roles during plant adaptation to biotic and abiotic stresses, as well as stress-free conditions. In the present study, we used a heterologous strategy of virus induced gene silencing to investigate the role of different classes of HSPs in Nicotiana benthamiana. Different growth and physiological parameters in silenced plants were evaluated under both control and salt stress conditions. Among the treatments, silencing of HSP70, especially under salinity regime, was found to have stronger impacts on growth, protein concentration, the accumulation of photosynthetic pigments, proline and total soluble carbohydrates content, malondialdehyde, the activity of antioxidant enzymes, performance index, relative water content and the ratio of K + /Na + , suggesting a more prominent role for HSP70 in both stressful and stress-free life cycle of the plants. Principal component analysis and hierarchical clustering indicated that HSP70 gene was silenced, the plants might effectively respond to stress by a higher accumulation of compatible solutes, like proline to protect the cell membranes and proteins from damage.
Tsitologiia, 2014
The influence of geldanamycin (GA), which is a specific inhibitor of heat shock protein Hsp90 activities, on synthesis of Hsp70 and Hsp90 and thermotolerance of Arabidopsis thaliana seedlings has been studied. Incubation of seedlings with GA was shown to induce synthesis of these stress proteins under normal conditions. Treatment of seeds with the Hsp90 inhibitor resulted in the elevated constitutive levels of Hsp70 and Hsp90 in seedlings as well as increased induction of their synthesis under heat shock, at that the effect of GA increased with its concentration. These up-regulation of Hsp promoted thermotolerance of seedlings. The obtained results are considered as evidence for autoregulation of heat shock protein synthesis and regulation of plant tolerance by Hsp90.
Molecular Ecology, 2008
The Hsp100/ClpB heat shock protein family is ancient and required for high temperature survival, but natural variation in expression and its phenotypic effects is unexplored in plants. In controlled environment experiments, we examined the effects of variation in the Arabidopsis cytosolic AtHsp101 (hereafter Hsp101). Ten wild-collected ecotypes differed in Hsp101 expression responses across a 22 to 40 °C gradient. Genotypes from low latitudes expressed the least Hsp101. We tested fitness and pleiotropic consequences of varying Hsp101 expression in 'control' vs. mild thermal stress treatments (15/25 °C D/N vs. 15/25° D/N plus 3 h at 35 °C 3 days/week). Comparing wild type and null mutants, wt Columbia (Col) produced ~33% more fruits compared to its Hsp101 homozygous null mutant. There was no difference between Landsberg erecta null mutant NIL (Ler) and wt Ler; wt Ler showed very low Hsp101 expression. In an assay of six genotypes, fecundity was a saturating function of Hsp101 content, in both experimental treatments. Thus, in addition to its essential role in acquired thermal tolerance, Hsp101 provides a substantial fitness benefit under normal growth conditions. Knocking out Hsp101 decreased fruit production, days to germination and days to bolting, total dry mass, and number of inflorescences; it increased transpiration rate and allocation to root mass. Root : total mass ratio decayed exponentially with Hsp101 content. This study shows that Hsp101 expression is evolvable in natural populations. Our results further suggest that Hsp101 is primarily an emergency high-temperature tolerance mechanism, since expression levels are lower in low-latitude populations from warmer climates. Hsp101 expression appears to carry an important trade-off in reduced root growth. This trade-off may select for suppressed expression under chronically high temperatures.
Comprehensive Expression Profile Analysis of the Arabidopsis Hsp70 Gene Family
PLANT PHYSIOLOGY, 2001
We isolated cDNA clones for two nuclear-encoded, organellar members of the Arabidopsis hsp70 gene family, mtHsc70-2 (AF217458) and cpHsc70-2 (AF217459). Together with the completion of the genome sequence, the hsp70 family in Arabidopsis consists of 14 members unequally distributed among the five chromosomes. To establish detailed expression data of this gene family, a comprehensive reverse transcriptase-polymerase chain reaction analysis for 11 hsp70s was conducted including analysis of organ-specific and developmental expression and expression in response to temperature extremes. All hsp70s showed 2-to 20-fold induction by heat shock treatment except cpHsc70-1 and mtHsc70-1, which were unchanged or repressed. The expression profiles in response to low temperature treatment were more diverse than those evoked by heat shock treatment. Both mitochondrial and all cytosolic members of the family except Hsp70b were strongly induced by low temperature, whereas endoplasmic reticulum and chloroplast members were not induced or were slightly repressed. Developmentally regulated expression of the heat-inducible Hsp70 in mature dry seed and roots in the absence of temperature stress suggests prominent roles in seed maturation and root growth for this member of the hsp70 family. This reverse transcriptase-polymerase chain reaction analysis establishes the complex differential expression pattern for the hsp70s in Arabidopsis that portends specialized functions even among members localized to the same subcellular compartment.
Characterization of orchardgrass p23, a flowering plant Hsp90 cohort protein
Cell Stress and Chaperones, 2009
p23 is a heat shock protein 90 (Hsp90) cochaperone and stabilizes the Hsp90 heterocomplex in mammals and yeast. In this study, we isolated a complementary DNA (cDNA) encoding p23 from orchardgrass (Dgp23) and characterized its functional roles under conditions of thermal stress. Dgp23 is a 911 bp cDNA with an open reading frame predicted to encode a 180 amino acid protein. Northern analysis showed that expression of Dgp23 transcripts was heat inducible. Dgp23 has a well-conserved p23 domain and interacted with an orchardgrass Hsp90 homolog in vivo, like mammalian and yeast p23 homologs. Recombinant Dgp23 is a small acidic protein with a molecular mass of approximately 27 kDa and pI 4.3. Dgp23 was also shown to function as a chaperone protein by suppression of malate dehydrogenase thermal aggregation. Differential scanning calorimetry thermograms indicated that Dgp23 is a heat-stable protein, capable of increasing the T m of lysozyme. Moreover, overexpression of Dgp23 in a yeast p23 homolog deletion strain, Δsba1, increased cell viability. These results suggest that Dgp23 plays a role in thermal stress-tolerance and functions as a co-chaperone of Hsp90 and as a chaperone.
Cytoplasmic HSP70 homologues of pea: differential expression in vegetative and embryonic organs
Plant Molecular Biology, 1995
Eukaryotes express several cytoplasmic HSP70 genes, and their encoded proteins participate in diverse cellular processes. Three cDNAs encoding highly expressed cytoplasmic H SP70 homologues from Pisum sativum were cloned and characterized. They were designated PsHSP71.2, PsHSC71.0, and PsHSP70b. These HSP70 genes have different expression profiles in leaves: PsHSP71.2 is observed only in response to heat stress, PsHSC71.0 is present constitutively, and PsHSP70b is weakly constitutively expressed, but induced strongly in response to heat stress. In addition to being heat induced, the PsH SP71.2 mRNA is also expressed in zygotic, but not maternal organs of developing pea seeds, while PsHSC71.0 and PsHSP70b mRNAs are present in maternal and zygotic organs throughout seed development. Immunoblot analysis of parallel protein samples detects a 70 kDa polypeptide in all samples, and a 72 kDa polypeptide that corresponds to the PsHSP71.2 gene product is observed in cotyledons beginning at mid-maturation and in axes beginning between late maturation and desiccation. This polypeptide is not detected in the seed coat. The 72 kDa polypeptide remains abundant in both cotyledons and axes through germination, but declines substantially between 48 and 72 h after the onset of imbibition. Differential control of HSP70 expression during heat stress, seed maturation, and germination is consistent with the hypothesis that there are functional distinctions between cytoplasmic HSP70s.
Journal of Plant Biochemistry and Biotechnology, 2013
Tissue-specific variation in Hsp70 and Hsp90 expression was studied in vegetative (leaf) and reproductive organs (floral tube, ovary and stamen) of Iris pumila plants originating from a sun-exposed and a shaded natural population, which experienced similar growth conditions in an experimental garden. Western blot analysis revealed the presence of both the Hsps in all examined tissues, but at different amounts. In addition to Hsp90a and Hsp90b that were previously detected in vegetative tissues, three new immunospecific bands, designated herein as Hsp90c, Hsp90d and Hsp90e, were recognized with the same anti-Hsp90 antibody in the reproductive tissues. Apart from showing tissue-specific differences in the relative amount of Hsp70 and Hsp90, our study provides evidence that the degree of Hsps expression within the same tissue also depended on the habitat type that the I. pumila plants were derived from.