Heat-induced Gene Expression Research Articles

Electric signaling and pin2 gene expression on different abiotic stimuli depend on a distinct threshold level of endogenous abscisic acid in several abscisic acid-deficient tomato mutants

Experiments were performed on three abscisic acid (ABA)-deficient tomato (Lycopersicon esculentum Mill.) mutants, notabilis, flacca, and sitiens, to investigate the role of ABA and jasmonic acid (JA) in the generation of electrical signals and Pin2 (proteinase inhibitor II) gene expression. We selected these mutants because they contain different levels of endogenous ABA. ABA levels in the mutant sitiens were reduced to 8% of the wild type, in notabilis they were reduced to 47%, and in flacca they were reduced to 21%. In wild-type and notabilis tomato plants the induction of Pin2 gene expression could be elicited by heat treatment, current application, or mechanical wounding. In flacca and sitiens only heat stimulation induced Pin2 gene expression. JA levels in flacca and sitiens plants also accumulated strongly upon heat stimulation but not upon mechanical wounding or current application. Characteristic electrical signals evolved in the wild type and in the notabilis and flacca mutants consisting of a fast action potential and a slow variation potential. However, in sitiens only heat evoked electrical signals; mechanical wounding and current application did not change the membrane potential. In addition, exogenous application of ABA to wild-type tomato plants induced transient changes in membrane potentials, indicating the involvement of ABA in the generation of electrical signals. Our data strongly suggest the presence of a minimum threshold value of ABA within the plant that is essential for the early events in electrical signaling and mediation of Pin2 gene expression upon wounding. In contrast, heat-induced Pin2 gene expression and membrane potential changes were not dependent on the ABA level but, rather, on the accumulation of JA.

Effects of Protein Kinase Inhibitors on Heat-Induced hsp72 Gene Expression in a Human Glioblastoma Cell Line

We examined the effects of several kinds of protein kinase inhibitors against calcium/phospholipid–dependent protein kinase (PKC) and cAMP-dependent protein kinase (PKA) on heat-induced hsp72 gene expression in a human glioblastoma cell line (T98G) as a source of insight into the type of protein kinase contributing to its gene expression. When the cells were treated with 1-(5′-isoquinolinesulphonyl)-2-methylpiperazine [(H7) a potent inhibitor of PKC, PKA, and others], the suppression of heat-induced Hsp72 accumulation was observed. Heat-induced Hsp72 accumulation was also suppressed by staurosporine (a potent inhibitor of PKC and PKA) or calphostin C [(CAL) a potent inhibitor of PKC] at high concentration (10 × IC 50) but not at low concentration (1 × IC 50). N-[2-( p-Bromocinnamylamino)ethyl]-5-isoquinolinesulphonamide [(H89) a potent inhibitor of PKA] did not affect heat-induced Hsp72 accumulation at either low (1 × IC 50) or high concentrations (10 × IC 50). Combination treatment with CAL and H89 suppressed the heat-induced Hsp72 accumulation more strongly than did treatment with either inhibitor alone. Furthermore, the heat-induced DNA-binding activation of heat-shock factor (HSF) was suppressed by CAL at high concentration (10 × IC 50), and combination treatment with CAL and H89 showed stronger suppression. In the H7 treatment, the clear suppression of HSF activation was observed even at low concentration (1 × IC 50). In addition, the cellular content of Hsp72 increased after the treatment of PKC or PKA activator. These results suggest that not only PKC, but also PKA may play an important role in heat-induced hsp72 gene expression.

Metabolic roles of a Rhodobacter sphaeroides member of the sigma32 family.

We report the role of a gene (rpoH) from the facultative phototroph Rhodobacter sphaeroides that encodes a protein (sigma37) similar to Escherichia coli sigma32 and other members of the heat shock family of eubacterial sigma factors. R. sphaeroides sigma37 controls genes that function during environmental stress, since an R. sphaeroides deltaRpoH mutant is approximately 30-fold more sensitive to the toxic oxyanion tellurite than wild-type cells. However, the deltaRpoH mutant lacks several phenotypes characteristic of E. coli cells lacking sigma32. For example, an R. sphaeroides deltaRpoH mutant is not generally defective in phage morphogenesis, since it plates the lytic virus RS1, as well as its wild-type parent. In characterizing the response of R. sphaeroides to heat, we found that its growth temperature profile is different when cells generate energy by aerobic respiration, anaerobic respiration, or photosynthesis. However, growth of the deltaRpoH mutant is comparable to that of a wild-type strain under each of these conditions. The deltaRpoH mutant mounted a heat shock response when aerobically grown cells were shifted from 30 to 42 degrees C, but it exhibited altered induction kinetics of approximately 120-, 85-, 75-, and 65-kDa proteins. There was also reduced accumulation of several presumed heat shock transcripts (rpoD P(HS), groESL1, etc.) when aerobically grown deltaRpoH cells were placed at 42 degrees C. Under aerobic conditions, it appears that another sigma factor enables the deltaRpoH mutant to mount a heat shock response, since either RNA polymerase preparations from an deltaRpoH mutant, reconstituted Esigma37, or a holoenzyme containing a 38-kDa protein (sigma38) each transcribed E. coli Esigma32-dependent promoters. The lower growth temperature profile of photosynthetic cells is correlated with a difference in heat-inducible gene expression, since neither wild-type cells or the deltaRpoH mutant mount a typical heat shock response after such cultures were shifted from 30 to 37 degrees C.

Ultraviolet light attenuates heat-inducible gene expression.

Ultraviolet light (UV) induces a stress response mediated through transcription factors such as NF-kB and AP-1, yet little is known about its effect on other transactivators of stress gene expression such as heat shock factor (HSF1). Analysis of UV-treated HeLa cells unexpectedly revealed uncoupling of the heat shock response. UV weakly induced HSF1 into its DNA bound state and markedly attenuated heat-inducible gene expression. HSF1 was further analyzed as a potential target for the uncharacteristic uncoupling of the thermal stress response by another type of stress. Heat-inducible multimerization and nuclear translocation of HSF1 were found to be intact in UV-treated cells; however, the monomeric rather than the multimeric form of HSF1 become hyperphosphorylated by UV. This effect could be partially abolished by the antioxidant N-acetyl cysteine with partial reconstitution of hs gene expression. The reported role of a MAP kinase blockade of HSF1 transactivating properties could not be confirmed by an inhibitor of the MAP kinase pathway. Fibroblasts defective in SAP kinase activity also did not exhibit resistance to UV-inducible phosphorylation of HSF1. Two-dimensional phosphopeptide mapping of HSF1 revealed a single tryptic peptide to be affected by UV, but no new pattern of phosphorylation was evident relative to tryptic phosphopeptide profile observed in control cells. These data suggest that UV uncoupling of the hs response possibly involves steps in addition to those associated with phosphorylation the monomeric form of HSF1.

Ultraviolet light attenuates heat‐inducible gene expression

Ultraviolet light (UV) induces a stress response mediated through transcription factors such as NF-kB and AP-1, yet little is known about its effect on other transactivators of stress gene expression such as heat shock factor (HSF1). Analysis of UV-treated HeLa cells unexpectedly revealed uncoupling of the heat shock response. UV weakly induced HSF1 into its DNA bound state and markedly attenuated heat-inducible gene expression. HSF1 was further analyzed as a potential target for the uncharacteristic uncoupling of the thermal stress response by another type of stress. Heat-inducible multimerization and nuclear translocation of HSF1 were found to be intact in UV-treated cells; however, the monomeric rather than the multimeric form of HSF1 become hyperphosphorylated by UV. This effect could be partially abolished by the antioxidant N-acetyl cysteine with partial reconstitution of hs gene expression. The reported role of a MAP kinase blockade of HSF1 transactivating properties could not be confirmed by an inhibitor of the MAP kinase pathway. Fibroblasts defective in SAP kinase activity also did not exhibit resistance to UV-inducible phosphorylation of HSF1. Two-dimensional phosphopeptide mapping of HSF1 revealed a single tryptic peptide to be affected by UV, but no new pattern of phosphorylation was evident relative to tryptic phosphopeptide profile observed in control cells. These data suggest that UV uncoupling of the hs response possibly involves steps in addition to those associated with phosphorylation the monomeric form of HSF1. J. Cell. Physiol. 172:314–322, 1997. © 1997 Wiley-Liss, Inc.

Localized Wounding by Heat Initiates the Accumulation of Proteinase Inhibitor II in Abscisic Acid-Deficient Plants by Triggering Jasmonic Acid Biosynthesis.

To test whether the response to electrical current and heat treatment is due to the same signaling pathway that mediates mechanical wounding, we analyzed the effect of electric-current application and localized burning on proteinase inhibitor II (Pin2) gene expression in both wild-type and abscisic acid (ABA)-deficient tomato (Lycopersicon esculentum Mill.) and potato (Solanum phureja) plants. Electric-current application and localized burning led to the accumulation of Pin2 mRNA in potato and tomato wild-type plants. Among the treatments tested, only localized burning of the leaves led to an accumulation of Pin2 mRNA in the ABA-deficient plants. Electric-current application, like mechanical injury, was able to initiate ABA and jasmonic acid (JA) accumulation in wild-type but not in ABA-deficient plants. In contrast, heat treatment led to an accumulation of JA in both wild-type and ABA-deficient plants. Inhibition of JA biosynthesis by aspirin blocked the heat-induced Pin2 gene expression in tomato wild-type leaves. These results suggest that electric current, similar to mechanical wounding, requires the presence of ABA to induce Pin2 gene expression. Conversely, burning of the leaves activates Pin2 gene expression by directly triggering the biosynthesis of JA by an alternative pathway that is independent of endogenous ABA levels.

Signals involved in wound-induced proteinase inhibitor II gene expression in tomato and potato plants.

Chemical and physical signals have been reported to mediate wound-induced proteinase inhibitor II (Pin2) gene expression in tomato and potato plants. Among the chemical signals, phytohormones such as abscisic acid (ABA) and jasmonic acid (JA) and the peptide systemin represent the best characterized systems. Furthermore, electrical and hydraulic mechanisms have also been postulated as putative Pin2-inducing systemic signals. Most of the chemical agents are able to induce Pin2 gene expression without any mechanical wounding. Thus, ABA, JA, and systemin initiate Pin2 mRNA accumulation in the directly treated leaves and in the nontreated leaves (systemic) that are located distal to the treated ones. ABA-deficient tomato and potato plants do not respond to wounding by accumulation of Pin2 mRNA, therefore providing a suitable model system for analysis of the signal transduction pathway involved in wound-induced gene activation. It was demonstrated that the site of action of JA is located downstream to the site of action of ABA. Moreover, systemin represents one of the initial steps in the signal transduction pathway regulating the wound response. Recently, it was reported that heat treatment and mechanical injury generate electrical signals, which propagate throughout the plant. These signals are capable of inducing Pin2 gene expression in the nontreated leaves of wounded plants. Furthermore, electrical current application to tomato leaves leads to an accumulation of Pin2 mRNA in local and systemic tissues. Examination of photosynthetic parameters (assimilation and transpiration rate) on several types of stimuli suggests that heat-induced Pin2 gene expression is regulated by an alternative pathway from that mediating the electrical current and mechanical wound response.

Thermal Regulation of Active Oxygen-Scavenging Enzymes in Crithidia luciliae thermophila

ABSTRAcr: The insect hemoflagellate Crithidia luciliae thermophila can be maintained in culture within a range of temperatures from 15 to 37 C. In an attempt to determine the biochemical basis of its unusual thermal tolerance, we measured the specific activities of active oxygen-scavenging enzymes in C. luciliae thermophila maintained at 25 C and at 37 C. Hyperthermia is associated with an 82% increase in the specific activity of superoxide dismutase without a qualitative change in the spectrum of isoenzymes, a 54% decrease in catalase, and a 34% increase in NADPH-dependent hydrogen peroxide consumption. Our results suggest that the superoxide dismutase present in C. luciliae thermophila is an iron-containing superoxide dismutase and that increased superoxide-scavenging ability accounts in part for survival at elevated temperatures. In the related trypanosomes and leishmanias, active oxygen scavenging contributes to the capacity to withstand oxidant-mediated phagocyte killing and resistance to some anti-parasitic drugs. The thermotolerance of C. luciliae thermophila recommends it as a model for investigating heat-induced gene expression in relation to parasite survival.

Determinants for the DNase I-hypersensitive chromatin structure 5′ to a human hsp70 gene

A DNase I hypersensitive site was detected in chromatin formed over a human hsp70 gene segment after amplification in COS7 cells. Deletion mutant analysis was used to evaluate the sequence requirements for this chromatin structure. Determinants sufficient to form the hypersensitive site are contained in a 280 base-pair sequence corresponding approximately to the region that is hypersensitive. Deletion of sequences from either end of this region resulted in reduced hypersensitivity, suggesting that multiple genetic elements contribute to the formation of this chromatin structure. As has been reported for other heat shock genes, the hypersensitive chromatin structure is present prior to heat treatment and does not change in intensity or position after heat shock, in spite of the fact that hsp70 gene expression is completely dependent on heat induction. Sequence requirements for hypersensitivity were generally similar to those for heat-induced gene expression when mutant plasmids were tested at low copy number (e.g. in HeLa cells or in COS cells without amplification); however, deletion of sequences between −223 and −162 with respect to the start of transcription abolished the hypersensitive site but had no effect on gene expression. A barrier to exonuclease III digestion was detected within this region (near an imperfect inverted repeat sequence centered at position −202), suggesting that proteins are tightly bound to the DNA at this location.

Determinants of heat shock-induced chromosome puffing

Modified Drosophila heat shock genes were introduced into the germ line by P element transformation. The genes were altered such that several factors could be tested for their influence upon chromosome puffing. Deletion of promoter sequences upstream of position −73 of an hsp7O-lacZ hybrid gene was sufficient to abolish puffing. Analysis of progressive 5′ deletions defines a 16 bp interval that contains sequences required for both heat-induced puffing and gene expression. An internal deletion of the hsp70-lacZ gene that reduces the transcript size from 9 kb to 0.8 kb results in a dramatic reduction in puff size. The chromosomal insertion sites of 26 variant hsp70 or hsp26 genes fall to influence puffing greatly with one marked exception. This transformant possesses an insert that falls to puff and exhibits a tissue-restricted pattern of expression. These results indicate that variation in either promoter strength or transcript length have profound effects on puffing.