Human cyclophilin 40 is a heat shock protein that exhibits altered intracellular localization following heat shock

The unactivated steroid receptors are chaperoned into a conformation that is optimal for binding hormone by a number of heat shock proteins, including Hsp90, Hsp70, Hsp40, and the immunophilin, FKBP52 (Hsp56). Together with its partner cochaperones, cyclophilin 40 (CyP40) and FKBP51, FKBP52 belongs to a distinct group of structurally related immunophilins that modulate steroid receptor function through their association with Hsp90. Due to the structural similarity between the component immunophilins, FKBP52 and cyclophilin 40, we decided to investigate whether CyP40 is also a heat shock protein. Exposure of MCF-7 breast cancer cells to elevated temperatures (42 degrees C for 3 hours) resulted in a 75-fold increase in CyP40 mRNA levels, but no corresponding increase in CyP40 protein expression, even after 7 hours of heat stress. The use of cycloheximide to inhibit protein synthesis revealed that in comparison to MCF-7 cells cultured at 37 degrees C, those exposed to heat stress (42 degrees C for 3 hours) displayed an elevated rate of degradation of both CyP40 and FKBP52 proteins. Concomitantly, the half-life of the CyP40 protein was reduced from more than 24 hours to just over 8 hours following heat shock. As no alteration in CyP40 protein levels occurred in cells exposed to heat shock, an elevated rate of degradation would imply that CyP40 protein was synthesized at an increased rate, hence the designation of human CyP40 as a heat shock protein. Application of heat stress elicited a marked redistribution of CyP40 protein in MCF-7 cells from a predominantly nucleolar localization, with some nuclear and cytoplasmic staining, to a pattern characterized by a pronounced nuclear accumulation of CyP40, with no distinguishable nucleolar staining. This increase in nuclear CyP40 possibly resulted from a redistribution of cytoplasmic and nucleolar CyP40, as no net increase in CyP40 expression levels occurred in response to stress. Exposure of MCF-7 cells to actinomycin D for 4 hours resulted in the translocation of the nucleolar marker protein, B23, from the nucleolus, with only a small reduction in nucleolar CyP40 levels. Under normal growth conditions, MCF-7 cells exhibited an apparent colocalization of CyP40 and FKBP52 within the nucleolus.     

Synthesis of trypanosome hsp70 mRNA is resistant to disruption of trans-splicing by heat shock

Synthesis of mRNA in trypanosomes involves an apparent trans-splicing reaction whereby a common 39-nucleotide mini-exon sequence is joined to the protein-coding exon of a mRNA precursor. We have previously shown (Muhich, M. L., and Boothroyd, J. C. (1988) Mol. Cell. Biol. 8, 3837-3846) that the trans-splicing pathway of Trypanosoma brucei is sensitive to disruption by severe heat shock. Here we demonstrate that the synthesis of heat shock protein 70 (hsp 70) mRNA in T. brucei is apparently resistant to the heat-induced disruption of splicing. The 5'-ends of hsp 70 mRNAs are shown to be identical for molecules synthesized at either normal or heat shock temperatures, and in both cases, the 5'-terminal mini-exon sequence is present. These results suggest that T. brucei has evolved a mechanism which directly compensates for the deleterious effects of heat shock on trans-splicing, one which allows for the continued mini-exon-dependent trans-splicing of selected pre-mRNAs.     

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.     

The respiratory response to heat shock in Neurospora crassa

A sharp decrease in oxygen uptake occurred in Neurospora crassa cells that were transferred from 30 degrees C to 45 degrees C, and the respiration that resumed later at 45 degrees C was cyanide-insensitive. Energization of mitochondria, measured in vivo with fluorescence microscopy and a carbocyanine dye, also declined sharply in cells at 45 degrees C. Electron microscopy showed no changes in mitochondrial complexity; however, the cytoplasm of heat-shocked cells was deficient in glycogen granules.     

Heat shock response in Neurospora crassa: purification and some properties of HSP 80

The heat shock response of Neurospora crassa was investigated. A 80-kilodalton heat shock protein (HSP 80) was purified to near homogeneity from heat-shocked mycelial extracts employing ammonium sulphate fractionation, gel filtration, and ion-exchange and affinity chromatography. It was observed to migrate as a single band on one-dimensional sodium dodecyl sulphate--polyacrylamide gels, with a molecular mass of approximately 83 kilodaltons (kDa). On two-dimensional gels it resolved into four polypeptide species with isoelectric points in the acidic range, which on staining with periodic acid--Schiff method were demonstrated to be glycosylated. In the native state, HSP 80 had a molecular size of approximately 610 kDa.     

Analysis of interactions between domains of a small heat shock protein,Hsp30 of Neurospora crassa

The alpha-crystallin-related, small heat shock proteins (sHsps), despite their overall variability in sequence, have discrete regions of conserved sequence that are involved in structural organization, as well as nonconserved regions that may perform similar roles in each protein. Recent X-ray diffraction analyses of an archeal and a plant sHsp have revealed both similarities and differences in how they are organized, suggesting that there is variability, particularly in the oligomeric organization of sHsps. As an adjunct to crystallographic analysis of sHsp structure, we employed the yeast 2-hybrid system to detect interactions between peptide regions of the sHsp of Neurospora crassa, Hsp30. We found that the conserved alpha-crystallin domain can be divided into N-terminal and C-terminal subdomains that interact strongly with one another. This interaction likely represents the tertiary contacts of the monomer that were visualized in the crystallographic structures of MjHsp16.5 and wheat Hsp16.9. The conserved sHsp monomeric fold is apparently determined by these regions of conserved sequence. We found that the C-terminal portion of the alpha-crystallin domain also interacts with itself in 2-hybrid assays; however, this interaction requires peptide extension into the semiconserved carboxyl tail. This C-terminal association may represent a principal contact site between dimers that contributes to higher-order assembly, as seen for the crystallized sHsps.     

Gene disruption by transformation in Neurospora crassa.

To establish conditions which might permit deliberate gene disruptions in Neurospora crassa, we studied transformation with linear DNA fragments. The transformation frequency observed was increased about twofold in comparison with that obtained with circular plasmid DNA. However, only a low proportion, approximately 10%, of the integration events occurred at the homologous site, whereas most integrations of transforming DNA took place in nonhomologous regions. It was also found that multiple integration events frequently occurred in individual transformants. A plasmid, designated pJP12, was constructed that contains the N. crassa am+ gene interrupted by insertion into its coding region of a DNA segment carrying a functional Neurospora qa-2+ gene. A fragment of Neurospora DNA that contains this am qa-2+ construction was obtained from plasmid pJP12 and used to transform an am+ qa-2 strain in an attempt to disrupt the resident am+ gene. After the initial qa-2+ transformants were converted to homokaryons by appropriate crosses, 10 independent transformants with an am mutant phenotype were found among 117 examined. Each of these qa-2+ am transformants showed the loss of a hybridization band in Southern blots of genomic DNA that corresponded to the normal am+ gene and the presence of a new hybridization band, consistent with an alteration in the am+ region.     

Glucose transport by osmotic shock and vanadate is impaired by glucosamine

In 3T3-L1 adipocytes, we previously reported that glucosamine impairs insulin stimulation of glucose transport, which is accompanied by impaired insulin stimulation of serine/threonine kinase Akt. To examine the role of Akt in glucosamine-induced insulin resistance, we investigated time course for insulin stimulation of Akt activity and glucose transport during recovery from glucosamine-induced insulin resistance. After induction of insulin resistance by glucosamine, we washed cells to remove glucosamine and incubated them for various times. After one hour, insulin stimulated-glucose transport was significantly increased and continued to increase up to 6-24 h. Insulin stimulation of Akt, however, did not increase after 1-3 h and began to slightly increase after 6 h. Next, we investigated effects of osmotic shock and vanadate on glucose transport in glucosamine-treated cells and found that glucosamine completely inhibited their actions in these cells. These data suggest that an Akt-independent mechanism is operative in glucosamine-induced insulin resistance and glucosamine impairs glucose transport stimulated by various stimuli involving and not involving Akt activation.     

Cycloheximide and heat shock induce new polypeptide synthesis in Neurospora crassa.

Treatment of Neurospora crassa with 0.1 microgram of cycloheximide per ml, a concentration which inhibited protein synthesis by about 70%, resulted in the greatly enhanced synthesis of at least three polypeptide bands with estimated molecular weights of 88,000, 30,000, and 28,000. A temperature shift from 25 to 37 degrees C resulted in the appearance of a single new polypeptide band of 70,000 daltons, the same size as the major heat shock-induced proteins observed in species of Drosophila and Dictyostelium. Synthesis of the cycloheximide-stimulated polypeptide bands was on cytoplasmic ribosomes rather than on mitochondrial ribosomes, as incorporation of isotope into the polypeptide bands was inhibited by 1.0 microgram of cycloheximide per ml but not by 1 mg of chloramphenicol per ml. In a mutant with cycloheximide-resistant ribosomes, 0.1 microgram of cycloheximide per ml failed to alter the pattern of protein synthesis from that of the controls. It is suggested that the new synthesis of the polypeptide bands reflects specific mechanisms of adaptation to different kinds of environmental stress, including inhibition of protein synthesis and temperature increases.     

Development of thermotolerance in Neurospora crassa by heat shock and other stresses eliciting peroxidase induction.

Hyperthermia, CdCl2, sodium arsenite, and H2O2 led to the rapid appearance of high levels of peroxidase in Neurospora crassa cultures and induced tolerance toward normally lethal temperatures in 60-h-old colonies. Intracellular superoxide dismutase levels did not correlate with the development of thermotolerance.     

Effects of heat shock on the induction of mutations by chemical mutagens in Neurospora crassa

Preheating of Neurospora conidia increased their susceptibility to mutation induction by chemical mutagens. Optimal conditions of heat shock for enhanced mutagenesis were determined in 2.5 X 10(7) conidia/ml 0.067 M KH2PO4-Na2HPO4 (pH 7.0) buffer to be treatment at 43 degrees C for 60 min. When protein synthesis during heat stock was eliminated by cycloheximide or by use of the temperature-sensitive mutation psi-1, induction of thermotolerance was inhibited while induction of the enhanced state of mutability was not. Therefore, inducible protein synthesis is not involved in this process. To discover whether DNA-repair systems are altered by heat shock and, as a result, whether reversion frequencies increase, DNA-repair mutants (upr-1, uvs-2, uvs-3, uvs-6, mus-7, mus-16) were heated and their reversion frequencies at the ad-8 locus were measured. All the DNA-repair mutants showed higher reversion frequencies with MNNG treatment after heat shock than in non-heated control. It therefore seems that DNA repair is not involved in the enhancement of chemical mutagenesis by heat shock. Heat shock does not increase frequencies of reversion induced by ultraviolet light, and heat shock after treatment with chemical mutagens does not affect reversion frequencies. These results suggest that heat shock may change the structure and function of cellular membranes and thereby increase the influx of mutagens into cells.     

Characterization of goldfish heat shock protein-30 induced upon severe heat shock in cultured cells

Temperature-dependent changes of growth rate and protein components were investigated for primary cultured cells derived from goldfish caudal fin. When the culture temperature was shifted from 20 degrees C to 35 degrees C and 40 degrees C, the growth rate was increased at 35 degrees C as compared with that at 20 degrees C, but no cell growth was observed at 40 degrees C. The differential scanning calorimetry demonstrated the onset of the endothermic reaction for goldfish cellular components at 40 degrees C. Therefore, the temperature shift to 40 degrees C was found to be of severe heat shock for goldfish cultured cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis revealed that, although expression of 70-kDa components was slightly induced at 35 degrees C, the temperature shift to 40 degrees C markedly induced the expression of the 30-kDa component in addition to that of 70-kDa component. The N-terminal amino acid sequencing identified the 30- and 70-kDa components to be heat shock protein (Hsp)-30 and Hsp70, respectively. Northern blot analysis revealed that the enhanced Hsp30 messenger ribonucleic acid (mRNA) levels were only observed at 40 degrees C, whereas Hsp70 mRNA was slightly accumulated at 35 degrees C. These results indicated that Hsp30 might have important functions under severe heat stress condition.