Biochemical characterization of the mammalian stress proteins and identification of two stress proteins as glucose- and Ca2+-ionophore-regulated proteins

Expression of wild-type and mutant forms of influenza hemagglutinin: the role of folding in intracellular transport

The hemagglutinin of influenza virus is synthesized as a monomeric subunit that is cotranslationally translocated across the membrane of the rough endoplasmic reticulum. We show that folding and assembly of hemagglutinin monomers into trimeric structures takes approximately 7-10 min and is completed before the protein leaves the endoplasmic reticulum. Mutants of hemagglutinin that fail to be transported from the endoplasmic reticulum are blocked at different stages of the folding pathway. Unfolded molecules of hemagglutinin are associated with a cellular protein of 77 kd that has been shown previously to bind to IgG heavy chain in the endoplasmic reticulum of certain myelomas. We discuss why assembly of native structures is required for transport of proteins through the exocytotic pathway.

Stress induces an increased hexose uptake in cultured cells

Temperature-sensitive mutants have revealed a region of the herpes simplex virus 1 genome that affects both the uptake of hexose and the synthesis of heat shock proteins. Other inducers of heat-shock proteins, namely heat shock itself and arsenite, likewise induce an increased uptake of hexose. The increased uptake, like that induced by insulin, is insensitive to the presence of actinomycin D or cycloheximide. It is concluded that an increased hexose uptake, reflecting an activation or relocation of existing hexose transport protein, is a general biochemical response of stressed cells.

An Hsp70-like protein in the ER: identity with the 78 kd glucose-regulated protein and immunoglobulin heavy chain binding protein

We have characterized a cDNA clone that encodes a protein related to the 70 kd heat shock protein, but is expressed in normal rat liver. This protein has a hydrophobic leader and is secreted into the endoplasmic reticulum. We show that it is identical with two previously described proteins: GRP78, whose synthesis is induced by glucose starvation, and BiP, which is found bound to immunoglobulin heavy chains in pre-B cells. This protein, which is abundant in antibody-secreting cells, can be released from heavy chains by ATP, a reaction analogous to the release of hsp70 from heat shocked nuclear structures. We propose a specific role for this protein in the assembly of secreted and membrane-bound proteins.

Intracellular distribution of 73,000 and 72,000 dalton heat shock proteins in HeLa cells

Intracellular localization of 73,000 and 72,000 dalton heat shock proteins (HSP73/72) in HeLa cells that were heat shocked or treated with chemical stressors was investigated using indirect immunofluorescent staining. The antiserum used specifically recognized the HSP73/72 in HeLa cells, and HSPs were increased by heating cells at 42 degrees C for 2 or 4 h and by prior treatment with chemical stressors (sodium arsenite, cadmium chloride, 8-hydroxyquinoline and ethanol). There was diffuse cytoplasmic staining at 37 degrees C, whereas nucleoli were stained brightly when cells were heated at 42 degrees C for 2 h. This rapid accumulation of HSP73/72 in the nucleoli was not inhibited by cycloheximide (50 micrograms/ml). Translocation of HSPs to the nucleoli was specific for heat because no translocation was induced by treatment with chemical stressors. When the cells were returned to 37 degrees C after heating, the HSPs in their nucleoli disappeared rapidly and diffuse cytoplasmic staining was present after 6-9 h. Our results suggest that the transient accumulation of HSP73/72 in HeLa cell nucleoli that is induced by heat shock is not correlated with the development of thermotolerance obtained in other cell systems.

Heat shock induction of intranuclear actin rods in cultured mammalian cells

Incubation of cultured cells of mouse C3H-2K fibroblastic cell line and other mammalian cell lines at 42.0-43.0 degrees C for 30 min or longer caused disintegration of normal actin structures including stress fibers, and induced formation of intranuclear actin paracrystal-like structures, called actin rods. When cells exposed to the elevated temperatures were shifted back to 37 degrees C, normal actin structures were regained. Pretreatment of cells at moderately high temperatures such as 38.5 degrees C inhibited formation of the actin rods upon subsequent exposure to 42.0 degrees C. Neither microtubules nor intermediate filaments were disrupted by the heat treatment. Several heat shock proteins were found to be synthesized under the conditions where actin rods were induced. However, there is no causal relationship between two cellular events, the induction of intranuclear actin rods and the synthesis of heat shock proteins.

Modulators of the eukaryotic heat shock response

A wide variety of agents other than heat have been reported to induce or suppress heat shock protein (hsp) synthesis in eukaryotic cells. Such agents, termed 'modulators', include inhibitors of respiration, low molecular weight nutrients, oxygen, hormones, sulfhydryl reagents, ionophores and amino acid analogues. The evidence for modulation is critically reviewed and common mechanisms of action that may relate modulation to induction by heat are discussed.

Selective gene expression in focal cerebral ischemia

Regional patterns of protein synthesis were examined in rat cortex made ischemic by the occlusion of the right common carotid and middle cerebral arteries. At 2 h of ischemia, proteins were pulse labeled with intracortical injections of a mixture of [3H]leucine, [3H]isoleucine, and [3H]proline. Newly synthesized proteins were analyzed by two-dimensional gel fluorography, and the results correlated with local CBF, measured with [14C]iodoantipyrine as tracer. Small blood flow reductions (CBF = 50-80 ml 100 g-1 min-1) were accompanied by a modest inhibition in synthesis of many proteins and a marked increase in one protein (Mr 27,000). With further reduction in blood flow (CBF = 40 ml 100 g-1 min-1), synthesis became limited to a small group of proteins (Mr 27,000, 34,000, 73,000, 79,000, and actin) including two new polypeptides (Mr 55,000 and 70,000). Severe ischemia (CBF = 15-25 ml 100 g-1 min-1) caused the isoelectric modification of several proteins (Mr 44,000, 55,000, and 70,000) and induced synthesis of another protein (Mr 40,000). Two polypeptides (Mr 27,000 and 70,000) dominated residual protein synthesis in severe ischemia. The changes in protein synthesis induced by different grades of ischemia most likely comprise a variation of the so-called "heat shock" or "stress" response found in all eukaryotic cells subjected to adverse conditions. Since heat shock genes are known to confer partial protection against anoxia and a variety of other noxious insults, their induction may be a factor in limiting the extent of ischemic tissue damage.

Uncoating ATPase is a member of the 70 kilodalton family of stress proteins

The synthetic peptide, VGIDLGTTYSC, derived from the heat shock-induced genes human hsp70, Drosophila hsp70, S. cerevisiae YG100, and E. coli dnaK, elicited antibodies that recognized two constitutive proteins in bovine extracts. One of these proteins, 71 kd, has previously been identified as uncoating ATPase, an enzyme that releases clathrin from coated vesicles. This immunological data complemented the result that uncoating ATPase was indistinguishable from the constitutive mammalian 71 kd stress protein by either partial proteolytic mapping or two-dimensional gel analysis. In addition, affinity-purified uncoating ATPase antibodies recognize proteins in yeast identified as the gene products of the heat shock or heat shock cognate genes YG100 and YG102. The results show that uncoating ATPase is a member of the 70 kd heat shock protein family.

Stress protein systems of mammalian cells

Living organisms are known to react to a heat stress by the selective induction in the synthesis of several polypeptides. In this review we list the major stress proteins of mammalian cells that are induced by heat shock and other environments and categorize these proteins into specific subgroups: the major heat shock proteins, the glucose-regulated proteins, and the low-molecular-weight heat shock proteins. Characteristics of the localization and expression of proteins in each of these subgroups are presented. Specifically, the nuclear/nucleolar locale of certain of the major heat shock proteins is considered with respect to their association with RNA and the recovery of cells after a heat exposure. The induction of these major heat shock proteins and the repression of the glucose-regulated proteins as a result of reoxygenation of anoxic cells or by the addition of glucose to glucose-deprived cultures is described. Changes in the expression of these protein systems during embryogenesis and differentiation in mammalian and nonmammalian systems is summarized, and the protective role that some of these proteins appear to play in protecting the animal against the lethal effects of a severe heat treatment and against teratogenesis is critically examined.

Differential induction of glucose-regulated and heat shock proteins: effects of pH and sulfhydryl-reducing agents on chicken embryo cells

Glucose-regulated and heat shock proteins are two subsets of eukaryotic stress proteins that can be induced differentially, simultaneously, and reciprocally. Two new inducers, low extracellular pH and 2-mercaptoethanol, that stimulate chicken embryo cells to synthesize glucose-regulated proteins rapidly were found. Two classes of cellular targets for mercaptoethanol were defined operationally, one dependent on and the other independent of protein synthesis. A new inducer of heat shock proteins, high extracellular pH, was found as well. Inductions by low and high extracellular pH were inhibited by actinomycin D but were insensitive to cycloheximide. Inductions of glucose-regulated and heat shock proteins are discussed in terms of changes in intracellular pH and sulfhydryl oxidation states.

Inhibition of the heat shock response and synthesis of glucose-regulated proteins in Ca2+-deprived rat hepatoma cells

Rat hepatoma cells become refractory to the induction of heat shock proteins and highly resistant to severe hyperthermia when incubated in Ca2+-free medium. The Ca2+-depleted cells synthesize polypeptides identified as the glucose-regulated proteins, but these proteins do not appear to be directly involved in the inhibition of the heat shock response. The results suggest that a Ca2+-dependent metabolic process is involved in the generation of the heat shock signal and/or mediates a step in the subsequent cascade of events that leads to the induction of heat shock protein synthesis and cell death.

Inhibition of poly(A)-binding protein synthesis in Friend erythroleukemia cells subsequent to heat shock

When Friend erythroleukemia cells (FEC) are incubated at 43 degrees C there is a rapid and nearly complete inhibition of protein synthesis which can be reversed when cells are returned to their normal growing temperature of 37 degrees C. Examination of the recovery of FEC from heat shock indicates that most cellular mRNAs behave as a cohort and return to translation at approximately the same rate. We found a notable exception to this rule in the case of a 78 kDa basic protein (named protein A) whose rate of return to a normal synthetic rate is markedly inhibited subsequent to heat shock. We show that protein A corresponds to the 78 kDa polypeptide commonly found to be associated with the poly(A) tails of mammalian mRNA.

Antagonistic effects of insulin and dexamethasone on glucose-regulated and heat shock protein synthesis

The present study extends our previous observation (Kasambalides and Lanks, J. Cell. Physiol., 114:93-98, 1983), that dexamethasone inhibits the alterations in heat shock protein (HSP) and glucose-regulated protein (GRP) synthesis caused by glucose deprivation. We now show that insulin, even in the presence of high extracellular glucose concentrations, will induce 95K and 82K GRP synthesis while suppressing 85K and 69K HSP synthesis. Heat shock of insulin-treated cultures causes induction of the 82K GRP rather than the 85K and 69K HSP's. All of the insulin effects are antagonized by dexamethasone. These data suggest that the changes in GRP and HSP synthesis induced by glucose deprivation and heat shock, respectively, may reflect the operation of a normal physiological mechanism that regulates glucose metabolism.

Analysis of the expression of the two major proteins of the 70 kilodalton mammalian heat shock family

This study compares the expression after heat shock of the two major variants of the mammalian 70 kilodalton heat shock family in three separate systems. The ability of wild type and temperature sensitive mutant (ts85) FM3A cells to elicit a heat shock response following a 45 degrees C, 12 min exposure was examined. The ts85 cells were found to be both significantly more thermosensitive than parent FM3A cells and to induce a 66kDa heat shock protein (hsp66) not visibly synthesized in the parent line by this exposure. However, a constitutive (synthesized at 37 degrees C) 68kDa heat shock protein (hsp68) is comparably induced in both cell lines after heat. A relationship between the severity of the heat exposure as seen by the cell and hsp66 expression is suggested and tested in Chinese hamster ovary cells. In CHO cells a brief 45 degrees C heat shock induces the constitutive hsp68 (but not hsp66), while longer and more severe exposures are required for the expression of hsp66. The induction of these two proteins is also examined in situ in mouse skeletal muscle. In this case both hsp66 and hsp68 are induced following comparatively mild heat treatments, and the 'threshold' for hsp66 induction observed in cultured cells either does not occur or is greatly reduced. However, once again, hsp68 is naturally synthesized at 37 degrees C while hsp66 appears to be de novo synthesized after heat shock.

The heat shock response

The response of cells to a heat shock or other stresses is the activation of a small number of genes which were previously inactive or transcribed at low levels. This response has been observed in a wide variety of bacterial, plant, and animal species. Evidence is accumulating that at least some of the proteins found in diverse species are similar, indicating a conservation of the response and the proteins in evolution. In a number of organisms a strong positive correlation has been found between the presence of heat shock proteins and ability of the organism to withstand thermal stress. This review attempts to assess the available data concerning the homology of proteins in different species, the localization of the proteins in cells, and the relationship between heat shock proteins and thermoresistance.

Studies on a possible relationship between alterations in the cytoskeleton and induction of heat shock protein synthesis in mammalian cells

Heat shock-induced alterations in protein synthesis and the cytoskeleton of two mammalian cell types have been investigated. A hyperthermic treatment of 30 min at 43 degrees C causes an accumulation of heat shock proteins (HSPs). The apparent molecular weights of HSPs of Reuber H35 hepatoma cells and of N2A neuroblastoma cells are 28 000, 65 000, 68 000, 70 000, 84 000, 100 000 D and 68 000, 70 000, 84 000 and 100 000 D respectively. Hyperthermia induces the disruption of microfilaments in hepatoma cells. Microtubules and intermediate filaments (vimentin and cytokeratin) remain intact. In neuroblastoma cells microfilaments remain intact whereas microtubules become disorganized after heat shock. As a result vimentin is found as a perinuclear aggregate. These cells were still able to synthesize heat shock proteins after pretreatment with cytoskeleton disrupting drugs such as dihydroxycytochalasin B and colchicine. Therefore it is concluded that the alterations in the cytoskeleton observed after the heat treatment are unlikely to be the cause of heat shock protein synthesis. Our results suggest that these heat shock-induced alterations in the cytoskeleton can be considered as a part of the heat shock response.

Elevated levels of 70,000 dalton heat shock protein in transiently thermotolerant Chinese hamster fibroblasts and in their stable heat resistant variants

The function of one or more shock proteins (HSPs) may be to confer protection of cells against thermal damage. The quantitative relationship between heat sensitivity and concentration of several HSPs was examined in thermotolerant Chinese hamster HA-1 cells and in their heat-resistant variants. Low molecular weight HSPs (22-27 kd) showed no correlation with cell survival. The best correlation was found between concentration of 70 kd HSP and the logarithm of cell survival. There was no difference between the HSP 70 induced by heat shock and that present in a constitutive form. The 70 kd HSP may actually confer heat resistance on cells, but in any case HSP 70 appeared to be the best predictor of heat response.

Regulation of a hybrid gene by glucose and temperature in hamster fibroblasts

A novel eukaryotic hybrid gene has been constructed from the 5' sequence of a rat gene and the bacterial neomycin-resistance gene. After transfection into hamster fibroblasts, the neo transcripts can be induced to high levels by the absence of glucose. Furthermore, this hybrid gene can be regulated by temperature when it is introduced into a temperature-sensitive mutant cell line.

Culture shock

The isolation of Xenopus liver, lung and testis cells by collagenase digestion of the tissue, followed by Percoll density gradient centrifugation, was characterized by the preferential synthesis of two proteins whose size and charge were similar to 70 and 85 kD heat-shock proteins. The synthesis of these two heat-shock-like proteins, relative to that of total protein, declined gradually in the first 3-4 days after the cells were plated out for primary culture. In fresh primary cultures of liver parenchymal cells albumin mRNA concentration declined rapidly and plateaued at 3-4 days of culture. Freshly isolated male Xenopus hepatocytes were refractory to induction by estrogen of vitellogenin gene transcription but they reacquired hormonal response during the first 3 days of culture. Both of these differentiated phenotypic functions of the Xenopus hepatocytes were quantitatively associated with the decline in synthesis of hsp-like proteins in freshly prepared primary cell cultures. Freshly isolated or heat-shocked hepatocytes exhibited a rounded shape with little intercellular contacts, whereas during the recovery period of 3 days they acquired a flattened shape with a high degree of intercellular and cell-substratum interaction. These results present the first evidence for the preferential synthesis of heat-shock-like proteins by procedures for establishing primary cell cultures. They emphasize the necessity of monitoring normal and heat-shock protein synthesis and cell morphology before using primary cell cultures for studying normal regulatory and developmental processes.

Induction of brain ornithine decarboxylase during recovery from metabolic, mechanical, thermal, or chemical injury

Metabolic, mechanical, thermal, and chemical injury induced ornithine decarboxylase (ODC) activity in rat brain. A two- to sixfold increase in ODC activity was measured at 5-9 h after different modes of injury to the brain. During the early phase of recovery from transient ischemia, when average protein synthesis was less than 50% of control, ODC activity was increased nearly fivefold. The rise in activity could be blocked by anisomycin, or reduced by intracerebral injections of actinomycin D. Drilling burr holes into the skull, injection of the vehicle for actinomycin D, hyperthermia, and freezing lesions all caused increased ODC activity. Neurotoxic chemicals (ammonia, methionine sulfoximine, acrylamide, carbon tetrachloride, and anisomycin) also increased brain ODC activity, whereas other chemicals (mannitol and valine) did not. Treatments known to stimulate the synthesis of heat shock proteins (carotid occlusion, hyperthermia, Cd2+, canavanine, and ethanol) induced ODC activity in the liver, whereas only hyperthermia and ethanol caused significant increases in spleen ODC activity. All increases in ODC activity were blocked by difluoromethylornithine, an irreversible inhibitor of ODC. The cellular response to noxious or stressful stimuli includes the synthesis of a small number of proteins of unknown functions; ODC may be one of these "heat shock" or "trauma" proteins.