Heat shock factor is required for growth at normal temperatures in the fission yeast Schizosaccharomyces pombe

1993 ◽  
Vol 13 (2) ◽  
pp. 749-761
Author(s):  
G J Gallo ◽  
H Prentice ◽  
R E Kingston
Keyword(s):  
Heat Shock ◽  
Schizosaccharomyces Pombe ◽  
Normal Growth ◽  
Growth Conditions ◽  
Heat Shock Factor ◽  
Binding Ability ◽  
Lower Growth ◽  
General Role ◽  
Functional Conservation ◽  
Cellular Processes

Schizosaccharomyces pombe is becoming an increasingly useful organism for the study of cellular processes, since in certain respects, such as the cell cycle and splicing, it is similar to metazoans. Previous biochemical studies have shown that the DNA binding ability of S. pombe heat shock factor (HSF) is fully induced only under stressed conditions, in a manner similar to that of Drosophila melanogaster and humans but differing from the constitutive binding by HSF in the budding yeasts. We report the isolation of the cDNA and gene for the HSF from S. pombe. S. pombe HSF has a domain structure that is more closely related to the structure of human and D. melanogaster HSFs than to the structure of the budding yeast HSFs, further arguing that regulation of HSF in S. pombe is likely to reflect regulation in metazoans. Surprisingly, the S. pombe HSF gene is required for growth at normal temperatures. We show that the S. pombe HSF gene can be replaced by the D. melanogaster HSF gene and that strains containing either of these genes behave similarly to transiently heat-shocked strains with respect to viability and the level of heat-induced transcripts from heat shock promoters. Strains containing the D. melanogaster HSF gene, however, have lower growth rates and show altered morphology at normal growth temperatures. These data demonstrate the functional conservation of domains of HSF that are required for response to heat shock. They further suggest a general role for HSF in growth of eukaryotic cells under normal (nonstressed) growth conditions.

scholarly journals Heat shock factor is required for growth at normal temperatures in the fission yeast Schizosaccharomyces pombe.

1993 ◽  
Vol 13 (2) ◽  
pp. 749-761 ◽  
Author(s):  
G J Gallo ◽  
H Prentice ◽  
R E Kingston
Keyword(s):  
Heat Shock ◽  
Schizosaccharomyces Pombe ◽  
Normal Growth ◽  
Growth Conditions ◽  
Heat Shock Factor ◽  
Binding Ability ◽  
Lower Growth ◽  
General Role ◽  
Functional Conservation ◽  
Cellular Processes

Schizosaccharomyces pombe is becoming an increasingly useful organism for the study of cellular processes, since in certain respects, such as the cell cycle and splicing, it is similar to metazoans. Previous biochemical studies have shown that the DNA binding ability of S. pombe heat shock factor (HSF) is fully induced only under stressed conditions, in a manner similar to that of Drosophila melanogaster and humans but differing from the constitutive binding by HSF in the budding yeasts. We report the isolation of the cDNA and gene for the HSF from S. pombe. S. pombe HSF has a domain structure that is more closely related to the structure of human and D. melanogaster HSFs than to the structure of the budding yeast HSFs, further arguing that regulation of HSF in S. pombe is likely to reflect regulation in metazoans. Surprisingly, the S. pombe HSF gene is required for growth at normal temperatures. We show that the S. pombe HSF gene can be replaced by the D. melanogaster HSF gene and that strains containing either of these genes behave similarly to transiently heat-shocked strains with respect to viability and the level of heat-induced transcripts from heat shock promoters. Strains containing the D. melanogaster HSF gene, however, have lower growth rates and show altered morphology at normal growth temperatures. These data demonstrate the functional conservation of domains of HSF that are required for response to heat shock. They further suggest a general role for HSF in growth of eukaryotic cells under normal (nonstressed) growth conditions.

scholarly journals Sequence and regulation of a gene encoding a human 89-kilodalton heat shock protein.

1989 ◽  
Vol 9 (6) ◽  
pp. 2615-2626 ◽  
Author(s):  
E Hickey ◽  
S E Brandon ◽  
G Smale ◽  
D Lloyd ◽  
L A Weber
Keyword(s):  
Heat Shock ◽  
Heat Shock Protein ◽  
Normal Growth ◽  
Gene Families ◽  
Growth Conditions ◽  
Complete Sequence ◽  
Start Codon ◽  
Hybridization Probe ◽  
Reading Frame ◽  
Alpha Gene

Vertebrate cells synthesize two forms of the 82- to 90-kilodalton heat shock protein that are encoded by distinct gene families. In HeLa cells, both proteins (hsp89 alpha and hsp89 beta) are abundant under normal growth conditions and are synthesized at increased rates in response to heat stress. Only the larger form, hsp89 alpha, is induced by the adenovirus E1A gene product (M. C. Simon, K. Kitchener, H. T. Kao, E. Hickey, L. Weber, R. Voellmy, N. Heintz, and J. R. Nevins, Mol. Cell. Biol. 7:2884-2890, 1987). We have isolated a human hsp89 alpha gene that shows complete sequence identity with heat- and E1A-inducible cDNA used as a hybridization probe. The 5'-flanking region contained overlapping and inverted consensus heat shock control elements that can confer heat-inducible expression on a beta-globin reporter gene. The gene contained 10 intervening sequences. The first intron was located adjacent to the translation start codon, an arrangement also found in the Drosophila hsp82 gene. The spliced mRNA sequence contained a single open reading frame encoding an 84,564-dalton polypeptide showing high homology with the hsp82 to hsp90 proteins of other organisms. The deduced hsp89 alpha protein sequence differed from the human hsp89 beta sequence reported elsewhere (N. F. Rebbe, J. Ware, R. M. Bertina, P. Modrich, and D. W. Stafford (Gene 53:235-245, 1987) in at least 99 out of the 732 amino acids. Transcription of the hsp89 alpha gene was induced by serum during normal cell growth, but expression did not appear to be restricted to a particular stage of the cell cycle. hsp89 alpha mRNA was considerably more stable than the mRNA encoding hsp70, which can account for the higher constitutive rate of hsp89 synthesis in unstressed cells.

scholarly journals Regulation of heat shock factor in Schizosaccharomyces pombe more closely resembles regulation in mammals than in Saccharomyces cerevisiae.

1991 ◽  
Vol 11 (1) ◽  
pp. 281-288 ◽  
Author(s):  
G J Gallo ◽  
T J Schuetz ◽  
R E Kingston
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Heat Shock ◽  
Dna Binding ◽  
Schizosaccharomyces Pombe ◽  
Fission Yeast ◽  
Heat Shock Response ◽  
Heat Shock Factor ◽  
Regulatory Sequence ◽  
Heat Shock Element ◽  
Shock Response

The heat shock response appears to be universal. All eucaryotes studied encode a protein, heat shock factor (HSF), that is believed to regulate transcription of heat shock genes. This protein binds to a regulatory sequence, the heat shock element, that is absolutely conserved among eucaryotes. We report here the identification of HSF in the fission yeast Schizosaccharomyces pombe. HSF binding was not observed in extracts from normally growing S. pombe (28 degrees C) but was detected in increasing amounts as the temperature of heat shock increased between 39 and 45 degrees C. This regulation is in contrast to that observed in Saccharomyces cerevisiae, in which HSF binding is detectable at both normal and heat shock temperatures. The S. pombe factor bound specifically to the heat shock element, as judged by methylation interference and DNase I protection analysis. The induction of S. pombe HSF was not inhibited by cycloheximide, suggesting that induction occurs posttranslationally, and the induced factor was shown to be phosphorylated. S. pombe HSF was purified to near homogeneity and was shown to have an apparent mobility of approximately 108 kDa. Since heat-induced DNA binding by HSF had previously been demonstrated only in metazoans, the conservation of heat-induced DNA binding by HSF among S. pombe and metazoans suggests that this mode of regulation is evolutionarily ancient.

scholarly journals The VapBC1 toxin–antitoxin complex fromMycobacterium tuberculosis: purification, crystallization and X-ray diffraction analysis

2016 ◽  
Vol 72 (6) ◽  
pp. 485-489 ◽  
Author(s):  
Zuokun Lu ◽  
Han Wang ◽  
Aili Zhang ◽  
Yusheng Tan
Keyword(s):  
Sparse Matrix ◽  
Stringent Response ◽  
Normal Growth ◽  
Growth Conditions ◽  
Biological Processes ◽  
X Ray Diffraction ◽  
X Ray ◽  
Cell Parameters ◽  
Cellular Processes ◽  
Crystallization Solution

Mycobacterium tuberculosis, a major human pathogen, encodes at least 88 toxin–antitoxin (TA) systems. Remarkably, more than half of these modules belong to the VapBC family. Under normal growth conditions, the toxicity of the toxin VapC is neutralized by the protein antitoxin VapB. When bacteria face an unfavourable environment, the antitoxin is degraded and the free toxin VapC targets important cellular processes in order to inhibit cell growth. TA systems function in many biological processes, such as in the stringent response, in biofilm formation and in drug tolerance. To explore the structure of the VapBC1 complex, the toxin VapC1 and the antitoxin VapB1 were separately cloned, co-expressed and crystallized. The best crystal was obtained using a crystallization solution consisting of optimized solution with commercial sparse-matrix screen solutions as additives. The crystal diffracted to a resolution of 2.7 Å and belonged to space groupP21, with unit-cell parametersa= 59.3,b= 106.7,c = 250.0 Å, β = 93.75°.

scholarly journals Proximity interactome of LC3B in normal growth conditions

2021 ◽  
Author(s):  
Marie Nollet ◽  
Alexander Agrotis ◽  
Fanourios Michailidis ◽  
Arran David Dokal ◽  
Vinothini Rajeeve ◽  
...  
Keyword(s):  
Cell Biology ◽  
Normal Growth ◽  
Growth Conditions ◽  
Biological Functions ◽  
Normal Medium ◽  
Outer Membranes ◽  
Cellular Processes ◽  
Proteomic Approach ◽  
And Function

LC3 (Light Chain 3) is a key player of autophagy, a major stress-responsive proteolysis pathway promoting cellular homeostasis. It coordinates the formation and maturation of autophagosomes and recruits cargo to be further degraded upon autophagosome-lysosome fusion. To orchestrate its functions, LC3 binds to multiple proteins from the autophagosomes inner and outer membranes, but the full extent of these interactions is not known. Moreover, LC3 has been increasingly reported in other cellular locations than the autophagosome, with cellular outcome not fully understood and not all related to autophagy. Furthermore, novel functions of LC3 as well as autophagy can occur in cells growing in a normal medium thus in non-stressed conditions. A better knowledge of the molecule in proximity to LC3 in normal growth conditions will improve the understanding of LC3 function in autophagy and in other cell biology function. Using an APEX2 based proteomic approach, we have detected 407 proteins in proximity to the well-characterised LC3B isoform in non-stress conditions. These include known and novel LC3B proximity proteins, associated with various cell localisation and biological functions. Sixty-nine of these proteins contain a putative LIR (LC3 Interacting Region) including 41 not reported associated to autophagy. Several APEX2 hits were validated by co-immunoprecipitation and co-immunofluorescence. This study uncovers the LC3B global interactome and reveals novel LC3B interactors, irrespective of LC3B localisation and function. This knowledge could be exploited to better understand the role of LC3B in autophagy and non-autophagy cellular processes.

Structure, organization, and expression of the 16-kDa heat shock gene family of Caenorhabditis elegans

Genome ◽  
1989 ◽  
Vol 31 (2) ◽  
pp. 690-697 ◽  
Author(s):  
E. P. M. Candido ◽  
D. Jones ◽  
D. K. Dixon ◽  
R. W. Graham ◽  
R. H. Russnak ◽  
...  
Keyword(s):  
Caenorhabditis Elegans ◽  
Heat Shock ◽  
Normal Growth ◽  
Growth Conditions ◽  
Amino Acid Sequences ◽  
Heat Shock Gene ◽  
Coding Region ◽  
Heat Shock Element ◽  
Hypersensitive Sites ◽  
Intergenic Regions

Exposure of the nematode Caenorhabditis elegans to a heat shock results in the induction of a number of genes not normally expressed in the animals under normal growth conditions. Among these are a family of genes encoding 16 kDa heat shock proteins (hsp16s). The major hsp16 genes have been cloned and characterized, and found to reside at two clusters in the C. elegans genome. One cluster contains two distinct genes, hsp16-1 and hsp16-48, arranged in divergent orientations separated by only 348 base pairs (bp). An identical pair, duplicated and inverted with respect to the first pair, is located 415 bp away. This cluster, located on chromosome V, therefore contains four genes as two identical pairs within less than 4 kilobases of DNA, and the pairs form the arms of a large inverted repeat. A second pair of genes, hsp16-2 and hsp16-41, constitutes a second hsp16 locus with an organization very similar to that of the hsp16-1/48 locus, except that it is not duplicated. Comparisons of the derived amino acid sequences show that hsp16-1 and hsp16-2 form a closely related pair, as do hsp16-41 and hsp16-48. These hsps show extensive sequence identity with the small hsps of Drosophila, as well as with mammalian alpha-crystallins. The coding region of each gene is interrupted by a single intron of approximately 50 bp, in a position homologous to that of the first intron in a mouse alpha-crystallin gene. The compact intergenic regions of both hsp16 loci contain a TATA element and a heat shock element (HSE) for each member of the pair, and are very similar in sequence overall. Expression studies, however, show that the level of transcripts from the hsp16-2/41 pair may be up to 14-fold higher on a per gene basis, as the level of RNA from the hsp16-1/48 pair, depending upon the induction conditions and developmental stage. This difference in message levels seems to be due to differences in the kinetics of inactivation of the genes rather than in transcription rates or rates of mRNA turnover. Distinct DNAseI hypersensitive sites are present upstream of each HSE in chromatin when the genes are inactive; these disappear and the whole intergenic region seems to become DNAse sensitive when the genes are maximally active.Key words: heat shock, 16-kDa polypeptides, gene structure, transcription, DNAseI hypersensitive sites, Caenorhabditis elegans.

scholarly journals The Nuclear Pore Complex and the DEAD Box Protein Rat8p/Dbp5p Have Nonessential Features Which Appear To Facilitate mRNA Export following Heat Shock

2004 ◽  
Vol 24 (11) ◽  
pp. 4869-4879 ◽  
Author(s):  
Christiane Rollenhagen ◽  
Christine A. Hodge ◽  
Charles N. Cole
Keyword(s):  
Heat Shock ◽  
Mrna Export ◽  
Normal Growth ◽  
Growth Conditions ◽  
Nuclear Pore ◽  
Nuclear Pore Complexes ◽  
Wild Type ◽  
Dead Box ◽  
Rna Export ◽  
Pore Complexes

ABSTRACT Nuclear pore complexes (NPCs) play an essential role in RNA export. Nucleoporins required for mRNA export in Saccharomyces cerevisiae are found in the Nup84p and Nup82p subcomplexes of the NPC. The Nup82p subcomplex contains Nup82p, Rat7p/Nup159p, Nsp1p, Gle1p/Rss1p, and Rip1p/Nup42p and is found only on the cytoplasmic face of NPCs. Both Rat7p and Gle1p contain binding sites for Rat8p/Dbp5p, an essential DEAD box protein and putative RNA helicase. Rip1p interacts directly with Gle1p and is the only protein known to be essential for mRNA export after heat shock but not under normal growth conditions. We report that in cells lacking Rip1p, both Gle1p and Rat8p dissociate from NPCs following heat shock at 42°C. Rat8p but not Gle1p was retained at NPCs if rip1Δ cells were first shifted to 37°C and then to 42°C, and this was correlated with preserving mRNA export in heat-shocked rip1Δ cells. Export following ethanol shock was less dependent on the presence of Rip1p. Exposure to 10% ethanol led to dissociation of Rat8p from NPCs in both wild-type and rip1Δ cells. Following this treatment, Rat8p was primarily nuclear in wild-type cells but primarily cytoplasmic in rip1Δ cells. We also determined that efficient export of heat shock mRNA after heat shock depends upon a novel 6-amino-acid element within Rat8p. This motif is not required under normal growth conditions or following ethanol shock. These studies suggest that the molecular mechanism responsible for the defect in export of heat shock mRNAs in heat-shocked rip1Δ cells is dissociation of Rat8p from NPCs. These studies also suggest that both nuclear pores and Rat8p have features not required for mRNA export in growing cells but which enhance the ability of mRNAs to be exported following heat shock.

scholarly journals Promoter Selectivity of the Bradyrhizobium japonicum RpoH Transcription Factors In Vivo and In Vitro

1998 ◽  
Vol 180 (9) ◽  
pp. 2395-2401 ◽  
Author(s):  
Franz Narberhaus ◽  
Michael Kowarik ◽  
Christoph Beck ◽  
Hauke Hennecke
Keyword(s):  
Heat Shock ◽  
Rna Polymerase ◽  
Bradyrhizobium Japonicum ◽  
Normal Growth ◽  
Growth Conditions ◽  
Start Site ◽  
E Coli ◽  
Soluble C

ABSTRACT Expression of the dnaKJ andgroESL 1 heat shock operons ofBradyrhizobium japonicum depends on a ς32-like transcription factor. Three such factors (RpoH1, RpoH2, and RpoH3) have previously been identified in this organism. We report here that they direct transcription from some but not all ς32-type promoters when the respective rpoH genes are expressed inEscherichia coli. All three RpoH factors were purified as soluble C-terminally histidine-tagged proteins, although the bulk of overproduced RpoH3 was insoluble. The purified proteins were recognized by an anti-E. coli ς32 serum. While RpoH1 and RpoH2 productively interacted with E. coli core RNA polymerase and produced E. coli groE transcript in vitro, RpoH3 was unable to do so.B. japonicum core RNA polymerase was prepared and reconstituted with the RpoH proteins. Again, RpoH1 and RpoH2 were active, and they initiated transcription at theB. japonicum groESL 1 and dnaKJpromoters. In all cases, the in vitro start site was shown to be identical to the start site determined in vivo. Promoter competition experiments revealed that the B. japonicum dnaKJ andgroESL 1 promoters were suboptimal for transcription by RpoH1- or RpoH2-containing RNA polymerase from B. japonicum. In a mixture of different templates, the E. coli groESL promoter was preferred over any other promoter. Differences were observed in the specificities of both sigma factors toward B. japonicum rpoH-dependent promoters. We conclude that the primary function of RpoH2is to supply the cell with DnaKJ under normal growth conditions whereas RpoH1 is responsible mainly for increasing the level of GroESL1 after a heat shock.

HSF1 granules: a novel stress-induced nuclear compartment of human cells

1997 ◽  
Vol 110 (23) ◽  
pp. 2925-2934 ◽  
Author(s):  
J. Cotto ◽  
S. Fox ◽  
R. Morimoto
Keyword(s):  
Heat Shock ◽  
Spatial Organization ◽  
Fluorescent Protein ◽  
Normal Growth ◽  
Growth Conditions ◽  
Heat Shock Gene ◽  
Heat Shock Factor 1 ◽  
Flag Epitope ◽  
Nuclear Structures ◽  
Stress Dependent

Heat shock factor 1 (HSF1) is the ubiquitous stress-responsive transcriptional activator which is essential for the inducible transcription of genes encoding heat shock proteins and molecular chaperones. HSF1 localizes within the nucleus of cells exposed to heat shock, heavy metals, and amino acid analogues, to form large, irregularly shaped, brightly staining granules which are not detected during attenuation of the heat shock response or when cells are returned to their normal growth conditions. The kinetics of detection of HSF1 granules parallels the transient induction of heat shock gene transcription. HSF1 granules are also detected using an HSF1-Flag epitope tagged protein or a chimeric HSF1-green fluorescent protein which reveals that these nuclear structures are stress-induced and can be detected in living cells. The spatial organization of HSF1 granules in nuclei of stressed cells reveals that they are novel nuclear structures which are stress-dependent and provides evidence that the nucleus undergoes dynamic reorganization in response to stress.

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