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Hub AI
Heat shock protein AI simulator
(@Heat shock protein_simulator)
Hub AI
Heat shock protein AI simulator
(@Heat shock protein_simulator)
Heat shock protein
Heat shock proteins (HSPs) are a family of proteins produced by cells in response to exposure to stressful conditions. They were first described in relation to heat shock, but are now known to also be expressed during other stresses including exposure to cold, UV light and during wound healing or tissue remodeling. Many members of this group perform chaperone functions by stabilizing new proteins to ensure correct folding or by helping to refold proteins that were damaged by the cell stress. This increase in expression is transcriptionally regulated. The dramatic upregulation of the heat shock proteins is a key part of the heat shock response and is induced primarily by heat shock factor (HSF). HSPs are found in virtually all living organisms, from bacteria to humans.
Heat shock proteins are named according to their molecular weight. For example, Hsp60, Hsp70 and Hsp90 (the most widely studied HSPs) refer to families of heat shock proteins on the order of 60, 70 and 90 kilodaltons in size, respectively. The small 8-kilodalton protein ubiquitin, which marks proteins for degradation, also has features of a heat shock protein. A conserved protein binding domain of approximately 80 amino-acid alpha crystallins are known as small heat shock proteins (sHSP).
It is known that rapid heat hardening can be elicited by a brief exposure of cells to sub-lethal high temperature, which in turn provides protection from subsequent and more severe temperature. In 1962, Italian geneticist Ferruccio Ritossa reported that heat and the metabolic uncoupler 2,4-dinitrophenol induced a characteristic pattern of "puffing" in the chromosomes of Drosophila. This discovery eventually led to the identification of the heat-shock proteins (HSP) or stress proteins whose expression this puffing represented. Increased synthesis of selected proteins in Drosophila cells following stresses such as heat shock was first reported in 1974. In 1974, Tissieres, Mitchell and Tracy discovered that heat-shock induces the production of a small number of proteins and inhibits the production of most others. This initial biochemical finding gave rise to a large number of studies on the induction of heat shock and its biological role. Heat shock proteins often function as chaperones in the refolding of proteins damaged by heat stress. Heat shock proteins have been found in all species examined, from bacteria to humans, suggesting that they evolved very early and have an important function.
According to Marvin et al. sHSPs independently express not only in heat shock response but also have developmental roles in embryonic or juvenile stages of mammals, teleost fish and some lower vertebral genomes. hspb1 (HSP27) is expressed during stress and during the development of embryo, somites, mid-hindbrain, heart and lens in zebrafish. Expression of the hspb4 gene, which codes for alpha crystallin, increases considerably in the lens in response to heat shock.
Production of high levels of heat shock proteins can also be triggered by exposure to different kinds of environmental stress conditions, such as infection, inflammation, exercise, exposure of the cell to harmful materials (ethanol, arsenic, and trace metals, among many others), ultraviolet light, starvation, hypoxia (oxygen deprivation), nitrogen deficiency (in plants) or water deprivation. As a consequence, the heat shock proteins are also referred to as stress proteins and their upregulation is sometimes described more generally as part of the stress response.
The mechanism by which heat shock (or other environmental stressors) activates the heat shock factor has been determined in bacteria. During heat stress, outer membrane proteins (OMPs) do not fold and cannot insert correctly into the outer membrane. They accumulate in the periplasmic space. These OMPs are detected by DegS, an inner membrane protease, that passes the signal through the membrane to the sigmaE transcription factor. However, some studies suggest that an increase in damaged or abnormal proteins brings HSPs into action.
Some bacterial heat shock proteins are upregulated via a mechanism involving RNA thermometers such as the FourU thermometer, ROSE element and the Hsp90 cis-regulatory element.
Petersen and Mitchell found that in D. melanogaster a mild heat shock pretreatment which induces heat shock gene expression (and greatly enhances survival after a subsequent higher temperature heat shock) primarily affects translation of messenger RNA rather than transcription of RNA. Heat shock proteins are also synthesized in D. melanogaster during recovery from prolonged exposure to cold in the absence of heat shock. A mild heat shock pretreatment of the same kind that protects against death from subsequent heat shock also prevents death from exposure to cold.
Heat shock protein
Heat shock proteins (HSPs) are a family of proteins produced by cells in response to exposure to stressful conditions. They were first described in relation to heat shock, but are now known to also be expressed during other stresses including exposure to cold, UV light and during wound healing or tissue remodeling. Many members of this group perform chaperone functions by stabilizing new proteins to ensure correct folding or by helping to refold proteins that were damaged by the cell stress. This increase in expression is transcriptionally regulated. The dramatic upregulation of the heat shock proteins is a key part of the heat shock response and is induced primarily by heat shock factor (HSF). HSPs are found in virtually all living organisms, from bacteria to humans.
Heat shock proteins are named according to their molecular weight. For example, Hsp60, Hsp70 and Hsp90 (the most widely studied HSPs) refer to families of heat shock proteins on the order of 60, 70 and 90 kilodaltons in size, respectively. The small 8-kilodalton protein ubiquitin, which marks proteins for degradation, also has features of a heat shock protein. A conserved protein binding domain of approximately 80 amino-acid alpha crystallins are known as small heat shock proteins (sHSP).
It is known that rapid heat hardening can be elicited by a brief exposure of cells to sub-lethal high temperature, which in turn provides protection from subsequent and more severe temperature. In 1962, Italian geneticist Ferruccio Ritossa reported that heat and the metabolic uncoupler 2,4-dinitrophenol induced a characteristic pattern of "puffing" in the chromosomes of Drosophila. This discovery eventually led to the identification of the heat-shock proteins (HSP) or stress proteins whose expression this puffing represented. Increased synthesis of selected proteins in Drosophila cells following stresses such as heat shock was first reported in 1974. In 1974, Tissieres, Mitchell and Tracy discovered that heat-shock induces the production of a small number of proteins and inhibits the production of most others. This initial biochemical finding gave rise to a large number of studies on the induction of heat shock and its biological role. Heat shock proteins often function as chaperones in the refolding of proteins damaged by heat stress. Heat shock proteins have been found in all species examined, from bacteria to humans, suggesting that they evolved very early and have an important function.
According to Marvin et al. sHSPs independently express not only in heat shock response but also have developmental roles in embryonic or juvenile stages of mammals, teleost fish and some lower vertebral genomes. hspb1 (HSP27) is expressed during stress and during the development of embryo, somites, mid-hindbrain, heart and lens in zebrafish. Expression of the hspb4 gene, which codes for alpha crystallin, increases considerably in the lens in response to heat shock.
Production of high levels of heat shock proteins can also be triggered by exposure to different kinds of environmental stress conditions, such as infection, inflammation, exercise, exposure of the cell to harmful materials (ethanol, arsenic, and trace metals, among many others), ultraviolet light, starvation, hypoxia (oxygen deprivation), nitrogen deficiency (in plants) or water deprivation. As a consequence, the heat shock proteins are also referred to as stress proteins and their upregulation is sometimes described more generally as part of the stress response.
The mechanism by which heat shock (or other environmental stressors) activates the heat shock factor has been determined in bacteria. During heat stress, outer membrane proteins (OMPs) do not fold and cannot insert correctly into the outer membrane. They accumulate in the periplasmic space. These OMPs are detected by DegS, an inner membrane protease, that passes the signal through the membrane to the sigmaE transcription factor. However, some studies suggest that an increase in damaged or abnormal proteins brings HSPs into action.
Some bacterial heat shock proteins are upregulated via a mechanism involving RNA thermometers such as the FourU thermometer, ROSE element and the Hsp90 cis-regulatory element.
Petersen and Mitchell found that in D. melanogaster a mild heat shock pretreatment which induces heat shock gene expression (and greatly enhances survival after a subsequent higher temperature heat shock) primarily affects translation of messenger RNA rather than transcription of RNA. Heat shock proteins are also synthesized in D. melanogaster during recovery from prolonged exposure to cold in the absence of heat shock. A mild heat shock pretreatment of the same kind that protects against death from subsequent heat shock also prevents death from exposure to cold.