Hyperthermic pre-treatment protects rat IPC-81 leukaemia cells against heat- and hydrogen peroxide-induced apoptosis.

It is well known that hyperthermia causes a transient tolerance of cells to a second heat challenge (acquired thermotolerance). The present study addresses the question of whether hyperthermic pre-treatment also increases the tolerance against heat- and hydrogen peroxide-induced apoptosis in rat IPC-81 leukaemia cells. This cell line exhibits an aberrant heat shock response which is characterized by a lack of the inducible Hsp70 isoform, even under conditions of heat or hydrogen peroxide stress, while the constitutively expressed Hsc70 and the inducible isoform of hemoxygenase (HO-1) are strongly enhanced by heat stress (43.5 degrees C; 30 min). In spite of this Hsp70 deficiency, hyperthermic pre-treatment protects IPC-81 leukaemia cells against apoptotic cell death induced by heat or hydrogen peroxide, but is less effective against necrosis induced by higher doses of the applied stressors. Addition of hydrogen peroxide (25 microM) enhances the amount of bax mRNA, while the level of bcl-2 mRNA remains unchanged. No increase of bax mRNA, in contrast, could be detected in heat shock-primed IPC-81 cells when treated with hydrogen peroxide after a 12h recovery. These results indicate that hyperthermic pre-treatment may exert its anti-apoptotic function not only by enhanced expression of constitutive as well as inducible HSPs but also by lowering the level of bax transcripts and thereby increasing the Bcl-2/Bax ratio.

The grp78 promoter of Neurospora crassa: constitutive, stress and differentiation-dependent protein-binding patterns.

In order to characterize the transcriptional regulation of the grp78 (glucose-regulated protein 78 kDa) gene of Neurospora crassa, a 1.65-kb genomic fragment upstream of the protein-coding region was sequenced and analysed. A single transcription start point was mapped 160 nt upstream of the first codon. Several distinct protein-DNA binding sites were identified in the promoter region by non-radioactive scanning electrophoretic mobility shift analysis during growth, stress treatment and differentiation of conidia. A protein DNA binding complex induced by tunicamycin was linked to a promoter motif similar to the unfolded protein response element consensus of yeast. Another binding complex in differentiating aerial hyphae was found, which differs from the known cis-elements involved in conidiation-dependent gene expression.

Biological timing and the clock metaphor: oscillatory and hourglass mechanisms.

Living organisms have developed a multitude of timing mechanisms--"biological clocks." Their mechanisms are based on either oscillations (oscillatory clocks) or unidirectional processes (hourglass clocks). Oscillatory clocks comprise circatidal, circalunidian, circadian, circalunar, and circannual oscillations--which keep time with environmental periodicities--as well as ultradian oscillations, ovarian cycles, and oscillations in development and in the brain, which keep time with biological timescales. These clocks mainly determine time points at specific phases of their oscillations. Hourglass clocks are predominantly found in development and aging and also in the brain. They determine time intervals (duration). More complex timing systems combine oscillatory and hourglass mechanisms, such as the case for cell cycle, sleep initiation, or brain clocks, whereas others combine external and internal periodicities (photoperiodism, seasonal reproduction). A definition of a biological clock may be derived from its control of functions external to its own processes and its use in determining temporal order (sequences of events) or durations. Biological and chemical oscillators are characterized by positive and negative feedback (or feedforward) mechanisms. During evolution, living organisms made use of the many existing oscillations for signal transmission, movement, and pump mechanisms, as well as for clocks. Some clocks, such as the circadian clock, that time with environmental periodicities are usually compensated (stabilized) against temperature, whereas other clocks, such as the cell cycle, that keep time with an organismic timescale are not compensated. This difference may be related to the predominance of negative feedback in the first class of clocks and a predominance of positive feedback (autocatalytic amplification) in the second class. The present knowledge of a compensated clock (the circadian oscillator) and an uncompensated clock (the cell cycle), as well as relevant models, are briefly re viewed. Hourglass clocks are based on linear or exponential unidirectional processes that trigger events mainly in the course of development and aging. An important hourglass mechanism within the aging process is the limitation of cell division capacity by the length of telomeres. The mechanism of this clock is briefly reviewed. In all clock mechanisms, thresholds at which "dependent variables" are triggered play an important role.

The Goodwin model: simulating the effect of light pulses on the circadian sporulation rhythm of Neurospora crassa.

The Goodwin oscillator is a minimal model that describes the oscillatory negative feedback regulation of a translated protein which inhibits its own transcription. Now, over 30 years later this scheme provides a basic description of the central components in the circadian oscillators of Neurospora, Drosophila, and mammals. We showed previously that Neurospora's resetting behavior by pulses of temperature, cycloheximide or heat shock can be simulated by this model, in which degradation processes play an important role for determining the clock's period and its temperature-compensation. Another important environmental factor for the synchronization is light. In this work, we show that on the basis of a light-induced transcription of the frequency (frq) gene phase response curves of light pulses as well as the influence of the light pulse length on phase shifts can be described by the Goodwin oscillator. A relaxation variant of the model predicts that directly after a light pulse inhibition in frq -transcription occurs, even when the inhibiting factor Z (FRQ) has not reached inhibitory concentrations. This has so far not been experimentally investigated for frq transcription, but it complies with a current model of light-induced transcription of other genes by a phosphorylated white-collar complex. During long light pulses, the relaxational model predicts that the sporulation rhythm is arrested in a steady state of high frq -mRNA levels. However, experimental results indicate the possibility of oscillations around this steady state and more in favor of the results by the original Goodwin model. In order to explain the resetting behavior by two light pulses, a biphasic first-order kinetics recovery period of the blue light receptor or of the light signal transduction pathway has to be assumed.

Heat shock and oxidative stress-induced exposure of hydrophobic protein domains as common signal in the induction of hsp68.

The hypothesis of a common signal for heat shock (HS) and oxidative stress (OS) was analyzed in C6 cells with regard to the induction of heat shock proteins (Hsps). The synthesis rate and level of the strictly inducible Hsp68 was significantly higher after HS (44 degrees C) compared with OS (2 mm H2O2). This difference corresponded to higher and lower activation of the heat shock factor (HSF) by HS and OS, respectively. OS, on the other hand, showed stronger cytotoxicity compared with HS as indicated by drastic lipid peroxidation and inhibition of protein synthesis as well as of mitochondrial and endocytotic activity. Lactic dehydrogenase also revealed stronger inhibition of enzyme activity by OS than by HS as shown in cells and in vitro experiments. Conformational analysis of lactic dehydrogenase by the fluorophore 1-anilinonaphtalene-8-sulfonic acid, however, showed stronger exposure of hydrophobic domains after HS than after OS which correlates positively with the Hsp68 response. Treatment of cells with deoxyspergualin, which exhibits high affinity to Hsps, the putative inhibitors of HSF, strongly increased only OS-induced hsp68 expression. In conclusion, the results suggest that exposure of hydrophobic domains of cytosolic proteins represents the common first signal in the multistep activation pathway of HSF.

Chaperones in cell cycle regulation and mitogenic signal transduction: a review.

Chaperones/heat shock proteins (HSPs) of the HSP90 and HSP70 families show elevated levels in proliferating mammalian cells and a cell cycle-dependent expression. They transiently associate with key molecules of the cell cycle control system such as Cdk4, Wee-1, pRb, p53, p27/Kip1 and are involved in the nuclear localization of regulatory proteins. They also associate with viral oncoproteins such as SV40 super T, large T and small t antigen, polyoma large and middle S antigen and EpsteinBarr virus nuclear antigen. This association is based on a J-domain in the viral proteins and may assist their targeting to the pRb/E2F complex. Small HSPs and their state of phosphorylation and oligomerization also seem to be involved in proliferation and differentiation. Chaperones/HSPs thus play important roles within cell cycle processes. Their exact functioning, however, is still a matter of discussion. HSP90 in particular, but also HSP70 and other chaperones associate with proteins of the mitogen-activated signal cascade, particularly with the Src kinase, with tyrosine receptor kinases, with Raf and the MAP-kinase activating kinase (MEK). This apparently serves the folding and translocation of these proteins, but possibly also the formation of large immobilized complexes of signal transducing molecules (scaffolding function).

Heat shock-induced arrests in different cell cycle phases of rat C6-glioma cells are attenuated in heat shock-primed thermotolerant cells.

The response kinetics of rat C6 glioma cells to heat shock was investigated by means of flow cytometric DNA measurements and western blot analysis of HSP levels. The results showed that the effects on cell cycle progression are dependent on the cell cycle phase at which heat shock is applied, leading to either G1 or G2/M arrest in randomly proliferating cells. When synchronous cultures were stressed during G0 they were arrested with G1 DNA content and showed prolongation of S and G2 phases after release from the block. In proliferating cells, HSC70 and HSP68 were induced during the recovery and reached maximum levels just before cells were released from the cell cycle blocks. Hyperthermic pretreatment induced thermotolerance both in asynchronous and synchronous cultures as evidenced by the reduced arrest of cell cycle progression after the second heat shock. Thermotolerance development was independent of the cell cycle phase. Pre-treated cells already had high HSP levels and did not further increase the amount of HSP after the second treatment. However, as in unprimed cells, HSP reduction coincided with the release from the cell cycle blocks. These results imply that the cell cycle machinery can be rendered thermotolerant by heat shock pretreatment and supports the assumption that HSP70 family members might be involved in thermotolerance development.

Induction of Hsp68 by oxidative stress involves the lipoxygenase pathway in C6 rat glioma cells.

The induction of Hsp68 by heat shock (HS) and oxidative stress (OS) involves different pathways in C6 rat glioma cells. The pathways were analyzed by specific inhibitors of signal transduction cascades. Quercetin (inhibitor of PLA(2) and lipoxygenase) inhibited only the OS-induced but not the HS-induced expression of Hsp68. Preincubation with quinacrine (inhibitor of PLA(2)) before stress also suppressed the expression of Hsp68 only after oxidative stress. Moreover, another inhibitor of lipoxygenase (alpha-tocopherol) exclusively suppressed OS-induced Hsp68 expression. This different regulation was confirmed by exposing the cells to arachidonic acid (AA) during stress which strongly increased the induction of Hsp68 only after OS. PGE(2) (metabolite of cyclooxygenase) and indomethacin (inhibitor of cyclooxygenase) had no influence on Hsp68 expression in response to both stressors. The results suggest that the induction of Hsp68 by oxidative stress is mainly transmitted by the lipoxygenase pathway in C6 rat glioma cells.

Heat shock effects on cell cycle progression.

In mammalian cells, short-term (acute) exposure to a moderate heat shock leads to a transient arrest of cells at mainly two cell cycle checkpoints, the G1/S and G2/M transitions. This is documented by the more or less synchronous resumption of cell cycle progression from these checkpoints during recovery. The reason for the accumulation of cells at these checkpoints may be found in activity thresholds of cyclin-dependent kinases (Cdks) at both transitions which are determined by (i) the amounts of the responsible cyclins, (ii) regulatory phosphorylation of the Cdks and (iii) the inhibition of Cdks by associated regulatory proteins (Ckis). All three regulatory systems may be subject to heat-shock-dependent changes, the amounts of Ckis, in particular, being increased. Cdk-dependent phosphorylation of the retinoblastoma protein and the subsequent release of active S-phase-specific transcription factors E2F/DP are considered as major heat-sensitive steps in cell cycle progression. Furthermore, high acute heat shock and long-term (chronic) heat treatment may lead to cell-type-specific forms of cell death. All types of responses to heat treatment are subject to adaptation after a 'priming' treatment, probably due to higher levels of heat shock proteins.

Interaction of the Neurospora crassa heat shock factor with the heat shock element during heat shock and different developmental stages.

The interaction of the heat shock factor (HSF) with the heat shock element (HSE) was determined by a non-radioactive electrophoretic mobility shift assay, in order to analyze HSF regulation in Neurospora crassa. HSF binds to HSE under normal, non-stress conditions and is thus constitutively trimerized. Upon heat shock, the HSF-HSE complex shows a retarded mobility. This was also observed in Saccharomyces cerevisiae, where this mobility shift was shown to be due to HSF phosphorylation [Sorger and Pelham (1988) Cell 54, 855-864]. In N. crassa, HSE-dependent electrophoretic mobility shift is temperature- and time-dependent. Under normal growth conditions, the HSF is located in the cytoplasm as well as in the nucleus. In germinating conidia the HSF shows a retarded mobility typical for heat shock even at normal growth temperatures. No HSF-dependent mobility shift was detectable in aerial hyphae.

A non-stop antisense reading frame in the grp78 gene of Neurospora crassa is homologous to the Achlya klebsiana NAD-gdh gene but is not being transcribed.

A long non-stop reading frame exists on the antisense strand of the grp78 gene (cDNA and genomic DNA) of Neurospora crassa. Computer analysis revealed a strong similarity of the putative antisense protein to the 10th exon of the NAD-dependent glutamate dehydrogenase gene (NAD-gdh) of Achlya klebsiana, which is itself located on the complementary strand of a transcribed hsc70 gene homologue. In Neurospora, no grp78 antisense mRNA was detected by Northern blot and reverse transcription-coupled polymerase chain reaction analyses, indicating that this long reading frame is not being transcribed. Hypotheses for the presence of such unexpressed non-stop reading frames are discussed.

Changes in cell morphology and actin organization during heat shock in Dictyostelium discoideum: does HSP70 play a role in acquired thermotolerance?

In response to heat shock (34 degrees C, 30 min), cell morphology and actin organization in Dictyostelium discoideum are drastically changed. Loss of pseudopodia and disappearance of F-actin-containing structures were observed by using fluorescence microscopy. These changes were paralleled by a rapid decrease of the F-actin content measured by a TRITC-phalloidin binding assay. The effects of heat shock on cell morphology and actin organization are transient: After heat shock (34 degrees C) or during a long-term heat treatment (30 degrees C), cell morphology, F-actin patterns and F-actin content recovered/adapted to a state which is characteristic for untreated cells. Because F-actin may be stabilized by increased amounts of heat shock proteins, their response and interaction with F-actin was analyzed. After a 1 h heat treatment (34 degrees C), the major heat shock protein of D. discoideum (HSP70) showed maximally increased synthesis rates and levels. During recovery from a 34 degrees C shock or during a continuous heat treatment at 30 degrees C, the HSP70 content first increased and then declined slowly toward normal levels. Pre-treatment of cells with a short heat shock of 30 min at 34 degrees C stabilized the F-actin content when the cells were exposed to a second heat shock. Furthermore, a transient colocalization of HSP70 and actin was observed at the beginning of heat treatment (30 degrees C) using immunological detection of HSP70 in the cytoskeletal actin fraction.

Different constitutive heat shock protein 70 expression during proliferation and differentiation of rat C6 glioma cells.

Analysis of constitutive heat shock protein 70 (HSC70) concentration in unstressed proliferating and differentiated rat C6 glioma cells revealed a striking reduction in the amount of HSC70 in differentiated cells. Proliferating cells showed a significantly higher HSC70 concentration, particularly observable during S phase in synchronous cultures. The activity of the cAMP/PKA signaling pathway was enhanced in differentiated cells. cAMP-elevating treatments both inhibited growth and reduced HSC70 concentration. Inactivation of PKA by H-89 upregulated the reduced HSC70 expression in differentiated cells and stimulated proliferation. Treatment with an inhibitor of MAP kinase activation (PD98059) reduced the HSC70 concentration. We assume that cAMP does not directly inhibit HSC70 expression by transcriptional repression, but by its inhibitory effect on the MAP kinase pathway.

Heat shock induction of a 65 kDa ATP-binding proteinase in rat C6 glioma cells.

The 45, 55, 65 and 100 kDa ATP-binding proteinases (ATP-BPases) of the heat-shocked (44 degrees C for 30 min, recovery for 12 h) rat C6 glioma cells were purified by DEAE-ionexchange and ATP-affinity chromatography. Their molecular masses, isoelectric points (pI), pH-optima and other properties were analyzed by native proteinase gels. It was shown that the 65 kDa ATP-BPase is specifically induced by heat shock and not detectable in control cells. Its N-terminal 1-9 amino acid sequence was determined by Edman degradation, but no homologies to other proteins in the protein data bases were found. 30 and 31 kDa proteinases can be cleaved from the 45, 55 and 65 kDa proteinases to which they are linked. A possible relationship of the heat-induced 65 kDa ATP-BPase with the ATP-dependent proteinases (ATP-DPases) in prokaryotes and eukaryotes is discussed.

The Goodwin model: simulating the effect of cycloheximide and heat shock on the sporulation rhythm of Neurospora crassa.

The Goodwin model is a negative feedback oscillator which describes rather closely the putative molecular mechanism of the circadian clock of Neurospora and Drosophila. An essential feature is that one or two clock proteins are synthesized and degraded in a rhythmic fashion. When protein synthesis in N. crassa (wild-type frq+and long-period mutant frq7) was inhibited by continuous incubation with increasing concentrations of cycloheximide (CHX) the period of the circadian sporulation rhythmicity is only slightly increased. The explanation of this effect may be seen in the inhibition of protein synthesis and protein degradation. In the model, increasing inhibition of both processes led to very similar results with respect to period length. That protein degradation is, in fact, inhibited by CHX is shown by determining protein degradation in N. crassa by means of pulse chase experiments. Phase response curves (PRCs) of the N. crassa sporulation rhythm toward CHX which were reported in the literature and investigated in this paper revealed significant differences between frq+and the long period mutants frq7and csp -1 frq7. These PRCs were also convincingly simulated by the model, if a transient inhibition of protein degradation by CHX is assumed as well as a lower constitutive degradation rate of FRQ-protein in the frq7/ csp -1 frq7mutants. The lower sensitivities of frq7and csp -1 frq7towards CHX may thus be explained by a lower degradation rate of clock protein FRQ7. The phase shifting by moderate temperature pulses (from 25 to 30 degrees C) can also be simulated by the Goodwin model and shows large phase advances at about CT 16-20 as observed in experiments. In case of higher temperature pulses (from 35 to 42 or 45 degrees C=heat shock) the phase position and form of the PRC changes as protein synthesis is increasingly inhibited. It is known from earlier experiments that heat shock not only inhibits the synthesis of many proteins but also inhibits protein degradation. Taking this into account, the Goodwin model also simulates the PRCs of high temperature (heat shock) pulses.

The Goodwin oscillator: on the importance of degradation reactions in the circadian clock.

This article focuses on the Goodwin oscillator and related minimal models, which describe negative feedback schemes that are of relevance for the circadian rhythms in Neurospora, Drosophila, and probably also in mammals. The temperature behavior of clock mutants in Neurospora crassa and Drosophila melanogaster are well described by the Goodwin model, at least on a semi-quantitative level. A similar semi-quantitative description has been found for Neurospora crassa phase response curves with respect to moderate temperature pulses, heat shock pulses, and pulses of cycloheximide. A characteristic feature in the Goodwin and related models is that degradation of clock-mRNA and clock protein species plays an important role in the control of the oscillator's period. As predicted by this feature, recent experimental results from Neurospora crassa indicate that the clock (FRQ) protein of the long period mutant frq7 is degraded approximately twice as slow as the corresponding wild-type protein. Quantitative RT-PCR indicates that experimental frq7-mRNA concentrations are significantly higher than wild-type levels. The latter findings cannot be modeled by the Goodwin oscillator. Therefore, a threshold inhibition mechanism of transcription is proposed.

Differential stress gene expression during the development of Neurospora crassa and other fungi.

Stress genes are differentially expressed during the development of Neurospora crassa and other fungi. Large amounts of constitutive heat shock protein 70 (HSC70) are found in dormant conidia of N. crassa, whereas little mRNA of the related glucose-regulated protein (grp78) is detected. It is, however, not generally clear whether heat shock protein or mRNA is preferentially stored in dormant spores. Germinating spores of N. crassa increase the level of grp mRNA. During this developmental stage, the induction of inducible heat shock protein (hsp) genes can be elicited by heat shock only at certain times after the beginning of germination. Exponential growth (proliferation) is paralleled by increased levels of HSCs. The stationary state is characterized by decreased levels of some HSCs and increased levels of others. Conidiation in N. crassa is accompanied by a strong enhancement of the synthesis and levels of HSCs but also of HSPs after heat shock. This increase may serve a need for additional rounds of replication, for the expression and transport of sporulation-specific proteins or for stabilization of macromolecules in the spores and their preservation for germination. The control mechanisms involved in the differential expression of hsc genes are currently not known.

Temperature adaptation of house keeping and heat shock gene expression in Neurospora crassa.

Adaptation of house keeping and heat shock gene expression was determined in Neurospora crassa during continuous exposure to different temperatures. Steady-state values of total protein synthesis differed little after incubation for 24 h at temperatures between 15 and 42 degreesC. Adaptation kinetics at 42 degreesC showed an initial, transient inhibition of total protein synthesis. Similar kinetics were observed with actin synthesis and tubulin mRNA. A priming 1-h heat shock of 42 degreesC 2 h prior to a second continuous exposure to 42 degreesC abolished the inhibitory effect of the second treatment and resulted in "acquired translational tolerance." Steady-state values of HSP70 synthesis rates revealed increasing levels with increasing temperatures after incubation for 24 h at different temperatures. Adaptation kinetics of the synthesis rates of different HSPs in vivo revealed maximal rates after 2 h and then a decrease to the elevated steady-state levels. The total amount of the major constitutive and inducible HSP70 isoform as determined by Western blots reached a maximum 2 h after the beginning of 42 degreesC exposure and only a slight decrease (25%) of the maximal value after 24 h. The inducible isoform of HSP70, in contrast, reached a maximum after 4-8 h and then decreased strongly after 24 h. HSP mRNAs reached maximal amounts 45-60 min after the beginning of 42 degreesC exposure and then declined after 8 h as determined by in vitro translation. Northern blots revealed maximal mRNA amounts of the inducible HSP70 after 30 min and zero amounts after 4 h exposure to 42 degreesC. After a shift to 42 degreesC HSP70 isoforms were immediately translocated into the nucleus and reshuttled into the cytoplasm during the following 6 h. The nuclear content of HSP70 remained elevated during the adapted steady state at 24 h. It is concluded that the adapted state after 24 h is based on enhanced amounts of constitutive isoforms in the cytoplasm and in the nucleus, whereas the inducible isoforms of HSP70 show faster adaptation kinetics.

Heat shock effects on second messenger systems of Neurospora crassa.

Exposure of growing hyphae of Neurospora crassa to heat shock (44 degrees C) or ethanol (2.6 M) for 1 h induced a significant increase in the cAMP level, which reached a maximum approximately 2 min after the beginning of treatment and then decreased to control values despite continued heat or ethanol exposure. A 10-s heat shock or a 5-s ethanol shock also resulted in a transient cAMP increase 2 min after the pulse. Heat shock or ethanol treatment led to an increase in the amount of catalytic subunits of the cAMP-dependent protein kinase A in the nucleus almost synchronously with the increase of cAMP in the cytoplasm. The concentration of cGMP decreased a few seconds after the beginning of heat shock (44 degrees C) or ethanol treatment (2.6 M) to approximately 50% of the control level. Exposure to heat shock (44 degrees C, 1 h) led to an increase in the amount of inositol phosphates 0.5-2 min after the onset of heat shock. Thereafter, inositol phosphate levels dropped to control values despite continued heat exposure. Incubation of growing hyphae with cAMP or 8-Br-cAMP led to a two- to threefold increase of inositol phosphates 10-300 s after the beginning of incubation. Heat treatment furthermore caused a rapid release of calcium from vacuoles as determined by Fura-2 measurement of the calcium content released from isolated vacuoles. These heat-shock-dependent second messenger changes may play a role in the heat-shock-induced phase shifts of the circadian clock and heat-shock-induced conidiation.

Nuclear translocation of stress protein Hsc70 during S phase in rat C6 glioma cells.

The expression and the nuclear translocation of the constitutive heat shock protein 70 (Hsc70) were determined during the cell cycle in synchronized rat astrocytomic C6 glioma cells. Cells were first shifted to the G0 by serum starvation. Twelve hours after a subsequent growth stimulation by transfer to 20% newborn calf serum, about 50% of the cells entered S phase. Western blot analysis with different monoclonal antibodies showed that only the constitutively expressed and moderately stress-activated Hsc70 is induced during serum stimulation. Maximal cellular Hsc70 content (170% of the control) was observed in early to mid S phase followed by a drastic decline while cells pass through G2/M (20% of the control). Hsp70, the major heat-inducible heat shock protein in C6 cells, is not detected in either asynchronously proliferating, serum-starved or in serum-stimulated C6 cells. Analysis of the nuclear and cytoplasmic protein fractions showed a significant increase of Hsc70 translocation into the nucleus during early S phase. These results indicate a role for Hsc70 but not for Hsp70 in the process of S phase entry and/or progression in C6 cells under physiological conditions.