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Kinase

February 16, 2024

For kinases that phosphorylate proteins, see Protein kinase.

In biochemistry, a kinase (/ˈkns, ˈkɪns, -z/)[2] is an enzyme that catalyzes the transfer of phosphate groups from high-energy, phosphate-donating molecules to specific substrates. This process is known as phosphorylation, where the high-energy ATP molecule donates a phosphate group to the substrate molecule. This transesterification produces a phosphorylated substrate and ADP. Conversely, it is referred to as dephosphorylation when the phosphorylated substrate donates a phosphate group and ADP gains a phosphate group (producing a dephosphorylated substrate and the high energy molecule of ATP). These two processes, phosphorylation and dephosphorylation, occur four times during glycolysis.[3][4][5]

Dihydroxyacetone kinase in complex with a non-hydrolyzable ATP analog (AMP-PNP). Coordinates from PDB ID:1UN9.[1]

Kinases are part of the larger family of phosphotransferases. Kinases should not be confused with phosphorylases, which catalyze the addition of inorganic phosphate groups to an acceptor, nor with phosphatases, which remove phosphate groups (dephosphorylation). The phosphorylation state of a molecule, whether it be a protein, lipid or carbohydrate, can affect its activity, reactivity and its ability to bind other molecules. Therefore, kinases are critical in metabolism, cell signalling, protein regulation, cellular transport, secretory processes and many other cellular pathways, which makes them very important to physiology.

Biochemistry and functional relevance edit

 
General reaction that is catalyzed by kinases

Kinases mediate the transfer of a phosphate moiety from a high energy molecule (such as ATP) to their substrate molecule, as seen in the figure below. Kinases are needed to stabilize this reaction because the phosphoanhydride bond contains a high level of energy. Kinases properly orient their substrate and the phosphoryl group within their active sites, which increases the rate of the reaction. Additionally, they commonly use positively charged amino acid residues, which electrostatically stabilize the transition state by interacting with the negatively charged phosphate groups. Alternatively, some kinases utilize bound metal cofactors in their active sites to coordinate the phosphate groups. Protein kinases can be classed as catalytically active (canonical) or as pseudokinases, reflecting the evolutionary loss of one or more of the catalytic amino acids that position or hydrolyse ATP.[6] However, in terms of signalling outputs and disease relevance, both kinases and pseudokinases are important signalling modulators in human cells, making kinases important drug targets.[7]

Kinases are used extensively to transmit signals and regulate complex processes in cells. Phosphorylation of molecules can enhance or inhibit their activity and modulate their ability to interact with other molecules. The addition and removal of phosphoryl groups provides the cell with a means of control because various kinases can respond to different conditions or signals. Mutations in kinases that lead to a loss-of-function or gain-of-function can cause cancer[8] and disease in humans, including certain types of leukemia and neuroblastomas, glioblastoma,[9] spinocerebellar ataxia (type 14), forms of agammaglobulinaemia, and many others.[10]

History and classification edit

The first protein to be recognized as catalyzing the phosphorylation of another protein using ATP was observed in 1954 by Eugene P. Kennedy at which time he described a liver enzyme that catalyzed the phosphorylation of casein.[citation needed] In 1956, Edmond H. Fischer and Edwin G. Krebs discovered that the interconversion between phosphorylase a and phosphorylase b was mediated by phosphorylation and dephosphorylation.[11] The kinase that transferred a phosphoryl group to Phosphorylase b, converting it to Phosphorylase a, was named Phosphorylase Kinase. Years later, the first example of a kinase cascade was identified, whereby Protein Kinase A (PKA) phosphorylates Phosphorylase Kinase. At the same time, it was found that PKA inhibits glycogen synthase, which was the first example of a phosphorylation event that resulted in inhibition. In 1969, Lester Reed discovered that pyruvate dehydrogenase was inactivated by phosphorylation, and this discovery was the first clue that phosphorylation might serve as a means of regulation in other metabolic pathways besides glycogen metabolism. In the same year, Tom Langan discovered that PKA phosphorylates histone H1, which suggested phosphorylation might regulate nonenzymatic proteins. The 1970s included the discovery of calmodulin-dependent protein kinases and the finding that proteins can be phosphorylated on more than one amino acid residue. The 1990s may be described as the "decade of protein kinase cascades". During this time, the MAPK/ERK pathway, the JAK kinases (a family of protein tyrosine kinases), and the PIP3-dependent kinase cascade were discovered.[12]

Kinases are classified into broad groups by the substrate they act upon: protein kinases, lipid kinases, carbohydrate kinases. Kinases can be found in a variety of species, from bacteria to mold to worms to mammals.[13] More than five hundred different kinases have been identified in humans.[3] Their diversity and their role in signaling makes them an interesting object of study. Various other kinases act on small molecules such as lipids, carbohydrates, amino acids, and nucleotides, either for signaling or to prime them for metabolic pathways. Specific kinases are often named after their substrates. Protein kinases often have multiple substrates, and proteins can serve as substrates for more than one specific kinase. For this reason protein kinases are named based on what regulates their activity (i.e. Calmodulin-dependent protein kinases). Sometimes they are further subdivided into categories because there are several isoenzymatic forms. For example, type I and type II cyclic-AMP dependent protein kinases have identical catalytic subunits but different regulatory subunits that bind cyclic AMP.[14]

Protein kinases edit

 
Overview of signal transduction pathways. Many of the proteins involved are kinases, including protein kinases (such as MAPK and JAK) and lipid kinases (such as PI3K).
Main article: Protein kinase

Protein kinases act on proteins, by phosphorylating them on their serine, threonine, tyrosine, or histidine residues. Phosphorylation can modify the function of a protein in many ways. It can increase or decrease a protein's activity, stabilize it or mark it for destruction, localize it within a specific cellular compartment, and it can initiate or disrupt its interaction with other proteins. The protein kinases make up the majority of all kinases and are widely studied.[15] These kinases, in conjunction with phosphatases, play a major role in protein and enzyme regulation as well as signalling in the cell.

A common point of confusion arises when thinking about the different ways a cell achieves biological regulation. There are countless examples of covalent modifications that cellular proteins can undergo; however, phosphorylation is one of the few reversible covalent modifications. This provided the rationale that phosphorylation of proteins is regulatory. The potential to regulate protein function is enormous given that there are many ways to covalently modify a protein in addition to regulation provided by allosteric control. In his Hopkins Memorial Lecture, Edwin Krebs asserted that allosteric control evolved to respond to signals arising from inside the cell, whereas phosphorylation evolved to respond to signals outside of the cell. This idea is consistent with the fact that phosphorylation of proteins occurs much more frequently in eukaryotic cells in comparison to prokaryotic cells because the more complex cell type evolved to respond to a wider array of signals.[14]

Cyclin dependent kinases edit

Cyclin dependent kinases (CDKs) are a group of several different kinases involved in regulation of the cell cycle. They phosphorylate other proteins on their serine or threonine residues, but CDKs must first bind to a cyclin protein in order to be active.[16] Different combinations of specific CDKs and cyclins mark different parts of the cell cycle. Additionally, the phosphorylation state of CDKs is also critical to their activity, as they are subject to regulation by other kinases (such as CDK-activating kinase) and phosphatases (such as Cdc25).[17] Once the CDKs are active, they phosphorylate other proteins to change their activity, which leads to events necessary for the next stage of the cell cycle. While they are most known for their function in cell cycle control, CDKs also have roles in transcription, metabolism, and other cellular events.[18]

Because of their key role in the controlling cell division, mutations in CDKs are often found in cancerous cells. These mutations lead to uncontrolled growth of the cells, where they are rapidly going through the whole cell cycle repeatedly.[19] CDK mutations can be found in lymphomas, breast cancer, pancreatic tumors, and lung cancer. Therefore, inhibitors of CDK have been developed as treatments for some types of cancer.[19]

Mitogen-activated protein kinases edit

Main article: Mitogen-activated protein kinase

MAP kinases (MAPKs) are a family of serine/threonine kinases that respond to a variety of extracellular growth signals. For example, growth hormone, epidermal growth factor, platelet-derived growth factor, and insulin are all considered mitogenic stimuli that can engage the MAPK pathway. Activation of this pathway at the level of the receptor initiates a signaling cascade whereby the Ras GTPase exchanges GDP for GTP. Next, Ras activates Raf kinase (also known as MAPKKK), which activates MEK (MAPKK). MEK activates MAPK (also known as ERK), which can go on to regulate transcription and translation. Whereas RAF and MAPK are both serine/threonine kinases, MAPKK is a tyrosine/threonine kinase.

 
A variety of mitogenic signals engage the MAPK pathway and promote cell growth and differentiation through a kinase cascade.

MAPK can regulate transcription factors directly or indirectly. Its major transcriptional targets include ATF-2, Chop, c-Jun, c-Myc, DPC4, Elk-1, Ets1, Max, MEF2C, NFAT4, Sap1a, STATs, Tal, p53, CREB, and Myc. MAPK can also regulate translation by phosphorylating the S6 kinase in the large ribosomal subunit. It can also phosphorylate components in the upstream portion of the MAPK signalling cascade including Ras, Sos, and the EGF receptor itself.[20]

The carcinogenic potential of the MAPK pathway makes it clinically significant. It is implicated in cell processes that can lead to uncontrolled growth and subsequent tumor formation. Mutations within this pathway alter its regulatory effects on cell differentiation, proliferation, survival, and apoptosis, all of which are implicated in various forms of cancer.[20]

Lipid kinases edit

Lipid kinases phosphorylate lipids in the cell, both on the plasma membrane as well as on the membranes of the organelles. The addition of phosphate groups can change the reactivity and localization of the lipid and can be used in signal transmission.

Phosphatidylinositol kinases edit

See also: Phosphatidylinositol phosphate kinases
 
Insulin binding to its receptor leads allows PI3 kinase to dock at the membrane where it can phosphorylate PI lipids

Phosphatidylinositol kinases phosphorylate phosphatidylinositol species, to create species such as phosphatidylinositol 3,4-bisphosphate (PI(3,4)P2), phosphatidylinositol 3,4,5-trisphosphate (PIP3), and phosphatidylinositol 3-phosphate (PI3P). The kinases include phosphoinositide 3-kinase (PI3K), phosphatidylinositol-4-phosphate 3-kinase, and phosphatidylinositol-4,5-bisphosphate 3-kinase. The phosphorylation state of phosphatidylinositol plays a major role in cellular signalling, such as in the insulin signalling pathway, and also has roles in endocytosis, exocytosis and other trafficking events.[21][22] Mutations in these kinases, such as PI3K, can lead to cancer or insulin resistance.[23]

The kinase enzymes increase the rate of the reactions by making the inositol hydroxyl group more nucleophilic, often using the side chain of an amino acid residue to act as a general base and deprotonate the hydroxyl, as seen in the mechanism below.[24] Here, a reaction between adenosine triphosphate (ATP) and phosphatidylinositol is coordinated. The end result is a phosphatidylinositol-3-phosphate as well as adenosine diphosphate (ADP). The enzymes can also help to properly orient the ATP molecule, as well as the inositol group, to make the reaction proceed faster. Metal ions are often coordinated for this purpose.[24]

 
Mechanism of phosphatidylinositol-3 kinase. ATP and phosphatidylinositol react to form phosphatidylinositol-3-phosphate and ADP, with the help of general base B.[24]

Sphingosine kinases edit

Sphingosine kinase (SK) is a lipid kinase that catalyzes the conversion of sphingosine to sphingosine-1-phosphate (S1P). Sphingolipids are ubiquitous membrane lipids. Upon activation, sphingosine kinase migrates from the cytosol to the plasma membrane where it transfers a γ phosphate (which is the last or terminal phosphate) from ATP or GTP to sphingosine. The S1P receptor is a GPCR receptor, so S1P has the ability to regulate G protein signaling. The resulting signal can activate intracellular effectors like ERKs, Rho GTPase, Rac GTPase, PLC, and AKT/PI3K. It can also exert its effect on target molecules inside the cell. S1P has been shown to directly inhibit the histone deacetylase activity of HDACs. In contrast, the dephosphorylated sphingosine promotes cell apoptosis, and it is therefore critical to understand the regulation of SKs because of its role in determining cell fate. Past research shows that SKs may sustain cancer cell growth because they promote cellular-proliferation, and SK1 (a specific type of SK) is present at higher concentrations in certain types of cancers.

There are two kinases present in mammalian cells, SK1 and SK2. SK1 is more specific compared to SK2, and their expression patterns differ as well. SK1 is expressed in lung, spleen, and leukocyte cells, whereas SK2 is expressed in kidney and liver cells. The involvement of these two kinases in cell survival, proliferation, differentiation, and inflammation makes them viable candidates for chemotherapeutic therapies.[25]

Carbohydrate kinases edit

 

For many mammals, carbohydrates provide a large portion of the daily caloric requirement. To harvest energy from oligosaccharides, they must first be broken down into monosaccharides so they can enter metabolism. Kinases play an important role in almost all metabolic pathways. The figure on the left shows the second phase of glycolysis, which contains two important reactions catalyzed by kinases. The anhydride linkage in 1,3 bisphosphoglycerate is unstable and has a high energy. 1,3-bisphosphogylcerate kinase requires ADP to carry out its reaction yielding 3-phosphoglycerate and ATP. In the final step of glycolysis, pyruvate kinase transfers a phosphoryl group from phosphoenolpyruvate to ADP, generating ATP and pyruvate.

Hexokinase is the most common enzyme that makes use of glucose when it first enters the cell. It converts D-glucose to glucose-6-phosphate by transferring the gamma phosphate of an ATP to the C6 position. This is an important step in glycolysis because it traps glucose inside the cell due to the negative charge. In its dephosphorylated form, glucose can move back and forth across the membrane very easily.[26] Mutations in the hexokinase gene can lead to a hexokinase deficiency which can cause nonspherocytic hemolytic anemia.[27]

Phosphofructokinase, or PFK, catalyzes the conversion of fructose-6-phosphate to fructose-1,6-bisphosphate and is an important point in the regulation of glycolysis. High levels of ATP, H+, and citrate inhibit PFK. If citrate levels are high, it means that glycolysis is functioning at an optimal rate. High levels of AMP stimulate PFK. Tarui's disease, a glycogen storage disease that leads to exercise intolerance, is due to a mutation in the PFK gene that reduces its activity.[28]

Other kinases edit

 
The active site of riboflavin kinase bound to its products--FMN (on left) and ADP (on right). Coordinates from PDB ID: 1N07.[29]

Kinases act upon many other molecules besides proteins, lipids, and carbohydrates. There are many that act on nucleotides (DNA and RNA) including those involved in nucleotide interconverstion, such as nucleoside-phosphate kinases and nucleoside-diphosphate kinases.[30] Other small molecules that are substrates of kinases include creatine, phosphoglycerate, riboflavin, dihydroxyacetone, shikimate, and many others.

Riboflavin kinase edit

Main article: Riboflavin kinase

Riboflavin kinase catalyzes the phosphorylation of riboflavin to create flavin mononucleotide(FMN). It has an ordered binding mechanism where riboflavin must bind to the kinase before it binds to the ATP molecule.[31] Divalent cations help coordinate the nucleotide.[31] The general mechanism is shown in the figure below.

 
Mechanism of riboflavin kinase.

Riboflavin kinase plays an important role in cells, as FMN is an important cofactor. FMN also is a precursor to flavin adenine dinucleotide(FAD), a redox cofactor used by many enzymes, including many in metabolism. In fact, there are some enzymes that are capable of carrying out both the phosphorylation of riboflavin to FMN, as well as the FMN to FAD reaction.[32] Riboflavin kinase may help prevent stroke, and could possibly be used as a treatment in the future.[33] It is also implicated in infection, when studied in mice.[34]

Thymidine kinase edit

Main article: Thymidine kinase

Thymidine kinase is one of the many nucleoside kinases that are responsible for nucleoside phosphorylation. It phosphorylates thymidine to create thymidine monophosphate (dTMP). This kinase uses an ATP molecule to supply the phosphate to thymidine, as shown below. This transfer of a phosphate from one nucleotide to another by thymidine kinase, as well as other nucleoside and nucleotide kinases, functions to help control the level of each of the different nucleotides.

 
Overall reaction catalysed by thymidine kinase.

After creation of the dTMP molecule, another kinase, thymidylate kinase, can act upon dTMP to create the diphosphate form, dTDP. Nucleoside diphosphate kinase catalyzes production of thymidine triphosphate, dTTP, which is used in DNA synthesis. Because of this, thymidine kinase activity is closely correlated with the cell cycle and used as a tumor marker in clinical chemistry.[35] Therefore, it can sometime be used to predict patient prognosis.[36] Patients with mutations in the thymidine kinase gene may have a certain type of mitochondrial DNA depletion syndrome, a disease that leads to death in early childhood.[37]

See also edit

 
Wikimedia Commons has media related to Kinases.

References edit

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  32. ^ Galluccio M, Brizio C, Torchetti EM, Ferranti P, Gianazza E, Indiveri C, Barile M (March 2007). "Over-expression in Escherichia coli, purification and characterization of isoform 2 of human FAD synthetase". Protein Expression and Purification. 52 (1): 175–181. doi:10.1016/j.pep.2006.09.002. PMID 17049878.
  33. ^ Zou YX, Zhang XH, Su FY, Liu X (October 2012). "Importance of riboflavin kinase in the pathogenesis of stroke". CNS Neuroscience & Therapeutics. 18 (10): 834–840. doi:10.1111/j.1755-5949.2012.00379.x. PMC 6493343. PMID 22925047.
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February 16, 2024
kinase, kinases, that, phosphorylate, proteins, protein, kinase, biochemistry, kinase, enzyme, that, catalyzes, transfer, phosphate, groups, from, high, energy, phosphate, donating, molecules, specific, substrates, this, process, known, phosphorylation, where,. For kinases that phosphorylate proteins see Protein kinase In biochemistry a kinase ˈ k aɪ n eɪ s ˈ k ɪ n eɪ s eɪ z 2 is an enzyme that catalyzes the transfer of phosphate groups from high energy phosphate donating molecules to specific substrates This process is known as phosphorylation where the high energy ATP molecule donates a phosphate group to the substrate molecule This transesterification produces a phosphorylated substrate and ADP Conversely it is referred to as dephosphorylation when the phosphorylated substrate donates a phosphate group and ADP gains a phosphate group producing a dephosphorylated substrate and the high energy molecule of ATP These two processes phosphorylation and dephosphorylation occur four times during glycolysis 3 4 5 Dihydroxyacetone kinase in complex with a non hydrolyzable ATP analog AMP PNP Coordinates from PDB ID 1UN9 1 Kinases are part of the larger family of phosphotransferases Kinases should not be confused with phosphorylases which catalyze the addition of inorganic phosphate groups to an acceptor nor with phosphatases which remove phosphate groups dephosphorylation The phosphorylation state of a molecule whether it be a protein lipid or carbohydrate can affect its activity reactivity and its ability to bind other molecules Therefore kinases are critical in metabolism cell signalling protein regulation cellular transport secretory processes and many other cellular pathways which makes them very important to physiology Contents 1 Biochemistry and functional relevance 2 History and classification 3 Protein kinases 3 1 Cyclin dependent kinases 3 2 Mitogen activated protein kinases 4 Lipid kinases 4 1 Phosphatidylinositol kinases 4 2 Sphingosine kinases 5 Carbohydrate kinases 6 Other kinases 6 1 Riboflavin kinase 6 2 Thymidine kinase 7 See also 8 ReferencesBiochemistry and functional relevance edit nbsp General reaction that is catalyzed by kinasesKinases mediate the transfer of a phosphate moiety from a high energy molecule such as ATP to their substrate molecule as seen in the figure below Kinases are needed to stabilize this reaction because the phosphoanhydride bond contains a high level of energy Kinases properly orient their substrate and the phosphoryl group within their active sites which increases the rate of the reaction Additionally they commonly use positively charged amino acid residues which electrostatically stabilize the transition state by interacting with the negatively charged phosphate groups Alternatively some kinases utilize bound metal cofactors in their active sites to coordinate the phosphate groups Protein kinases can be classed as catalytically active canonical or as pseudokinases reflecting the evolutionary loss of one or more of the catalytic amino acids that position or hydrolyse ATP 6 However in terms of signalling outputs and disease relevance both kinases and pseudokinases are important signalling modulators in human cells making kinases important drug targets 7 Kinases are used extensively to transmit signals and regulate complex processes in cells Phosphorylation of molecules can enhance or inhibit their activity and modulate their ability to interact with other molecules The addition and removal of phosphoryl groups provides the cell with a means of control because various kinases can respond to different conditions or signals Mutations in kinases that lead to a loss of function or gain of function can cause cancer 8 and disease in humans including certain types of leukemia and neuroblastomas glioblastoma 9 spinocerebellar ataxia type 14 forms of agammaglobulinaemia and many others 10 History and classification editThe first protein to be recognized as catalyzing the phosphorylation of another protein using ATP was observed in 1954 by Eugene P Kennedy at which time he described a liver enzyme that catalyzed the phosphorylation of casein citation needed In 1956 Edmond H Fischer and Edwin G Krebs discovered that the interconversion between phosphorylase a and phosphorylase b was mediated by phosphorylation and dephosphorylation 11 The kinase that transferred a phosphoryl group to Phosphorylase b converting it to Phosphorylase a was named Phosphorylase Kinase Years later the first example of a kinase cascade was identified whereby Protein Kinase A PKA phosphorylates Phosphorylase Kinase At the same time it was found that PKA inhibits glycogen synthase which was the first example of a phosphorylation event that resulted in inhibition In 1969 Lester Reed discovered that pyruvate dehydrogenase was inactivated by phosphorylation and this discovery was the first clue that phosphorylation might serve as a means of regulation in other metabolic pathways besides glycogen metabolism In the same year Tom Langan discovered that PKA phosphorylates histone H1 which suggested phosphorylation might regulate nonenzymatic proteins The 1970s included the discovery of calmodulin dependent protein kinases and the finding that proteins can be phosphorylated on more than one amino acid residue The 1990s may be described as the decade of protein kinase cascades During this time the MAPK ERK pathway the JAK kinases a family of protein tyrosine kinases and the PIP3 dependent kinase cascade were discovered 12 Kinases are classified into broad groups by the substrate they act upon protein kinases lipid kinases carbohydrate kinases Kinases can be found in a variety of species from bacteria to mold to worms to mammals 13 More than five hundred different kinases have been identified in humans 3 Their diversity and their role in signaling makes them an interesting object of study Various other kinases act on small molecules such as lipids carbohydrates amino acids and nucleotides either for signaling or to prime them for metabolic pathways Specific kinases are often named after their substrates Protein kinases often have multiple substrates and proteins can serve as substrates for more than one specific kinase For this reason protein kinases are named based on what regulates their activity i e Calmodulin dependent protein kinases Sometimes they are further subdivided into categories because there are several isoenzymatic forms For example type I and type II cyclic AMP dependent protein kinases have identical catalytic subunits but different regulatory subunits that bind cyclic AMP 14 Protein kinases edit nbsp Overview of signal transduction pathways Many of the proteins involved are kinases including protein kinases such as MAPK and JAK and lipid kinases such as PI3K Main article Protein kinase Protein kinases act on proteins by phosphorylating them on their serine threonine tyrosine or histidine residues Phosphorylation can modify the function of a protein in many ways It can increase or decrease a protein s activity stabilize it or mark it for destruction localize it within a specific cellular compartment and it can initiate or disrupt its interaction with other proteins The protein kinases make up the majority of all kinases and are widely studied 15 These kinases in conjunction with phosphatases play a major role in protein and enzyme regulation as well as signalling in the cell A common point of confusion arises when thinking about the different ways a cell achieves biological regulation There are countless examples of covalent modifications that cellular proteins can undergo however phosphorylation is one of the few reversible covalent modifications This provided the rationale that phosphorylation of proteins is regulatory The potential to regulate protein function is enormous given that there are many ways to covalently modify a protein in addition to regulation provided by allosteric control In his Hopkins Memorial Lecture Edwin Krebs asserted that allosteric control evolved to respond to signals arising from inside the cell whereas phosphorylation evolved to respond to signals outside of the cell This idea is consistent with the fact that phosphorylation of proteins occurs much more frequently in eukaryotic cells in comparison to prokaryotic cells because the more complex cell type evolved to respond to a wider array of signals 14 Cyclin dependent kinases edit Cyclin dependent kinases CDKs are a group of several different kinases involved in regulation of the cell cycle They phosphorylate other proteins on their serine or threonine residues but CDKs must first bind to a cyclin protein in order to be active 16 Different combinations of specific CDKs and cyclins mark different parts of the cell cycle Additionally the phosphorylation state of CDKs is also critical to their activity as they are subject to regulation by other kinases such as CDK activating kinase and phosphatases such as Cdc25 17 Once the CDKs are active they phosphorylate other proteins to change their activity which leads to events necessary for the next stage of the cell cycle While they are most known for their function in cell cycle control CDKs also have roles in transcription metabolism and other cellular events 18 Because of their key role in the controlling cell division mutations in CDKs are often found in cancerous cells These mutations lead to uncontrolled growth of the cells where they are rapidly going through the whole cell cycle repeatedly 19 CDK mutations can be found in lymphomas breast cancer pancreatic tumors and lung cancer Therefore inhibitors of CDK have been developed as treatments for some types of cancer 19 Mitogen activated protein kinases edit Main article Mitogen activated protein kinase MAP kinases MAPKs are a family of serine threonine kinases that respond to a variety of extracellular growth signals For example growth hormone epidermal growth factor platelet derived growth factor and insulin are all considered mitogenic stimuli that can engage the MAPK pathway Activation of this pathway at the level of the receptor initiates a signaling cascade whereby the Ras GTPase exchanges GDP for GTP Next Ras activates Raf kinase also known as MAPKKK which activates MEK MAPKK MEK activates MAPK also known as ERK which can go on to regulate transcription and translation Whereas RAF and MAPK are both serine threonine kinases MAPKK is a tyrosine threonine kinase nbsp A variety of mitogenic signals engage the MAPK pathway and promote cell growth and differentiation through a kinase cascade MAPK can regulate transcription factors directly or indirectly Its major transcriptional targets include ATF 2 Chop c Jun c Myc DPC4 Elk 1 Ets1 Max MEF2C NFAT4 Sap1a STATs Tal p53 CREB and Myc MAPK can also regulate translation by phosphorylating the S6 kinase in the large ribosomal subunit It can also phosphorylate components in the upstream portion of the MAPK signalling cascade including Ras Sos and the EGF receptor itself 20 The carcinogenic potential of the MAPK pathway makes it clinically significant It is implicated in cell processes that can lead to uncontrolled growth and subsequent tumor formation Mutations within this pathway alter its regulatory effects on cell differentiation proliferation survival and apoptosis all of which are implicated in various forms of cancer 20 Lipid kinases editLipid kinases phosphorylate lipids in the cell both on the plasma membrane as well as on the membranes of the organelles The addition of phosphate groups can change the reactivity and localization of the lipid and can be used in signal transmission Phosphatidylinositol kinases edit See also Phosphatidylinositol phosphate kinases nbsp Insulin binding to its receptor leads allows PI3 kinase to dock at the membrane where it can phosphorylate PI lipidsPhosphatidylinositol kinases phosphorylate phosphatidylinositol species to create species such as phosphatidylinositol 3 4 bisphosphate PI 3 4 P2 phosphatidylinositol 3 4 5 trisphosphate PIP3 and phosphatidylinositol 3 phosphate PI3P The kinases include phosphoinositide 3 kinase PI3K phosphatidylinositol 4 phosphate 3 kinase and phosphatidylinositol 4 5 bisphosphate 3 kinase The phosphorylation state of phosphatidylinositol plays a major role in cellular signalling such as in the insulin signalling pathway and also has roles in endocytosis exocytosis and other trafficking events 21 22 Mutations in these kinases such as PI3K can lead to cancer or insulin resistance 23 The kinase enzymes increase the rate of the reactions by making the inositol hydroxyl group more nucleophilic often using the side chain of an amino acid residue to act as a general base and deprotonate the hydroxyl as seen in the mechanism below 24 Here a reaction between adenosine triphosphate ATP and phosphatidylinositol is coordinated The end result is a phosphatidylinositol 3 phosphate as well as adenosine diphosphate ADP The enzymes can also help to properly orient the ATP molecule as well as the inositol group to make the reaction proceed faster Metal ions are often coordinated for this purpose 24 nbsp Mechanism of phosphatidylinositol 3 kinase ATP and phosphatidylinositol react to form phosphatidylinositol 3 phosphate and ADP with the help of general base B 24 Sphingosine kinases edit Sphingosine kinase SK is a lipid kinase that catalyzes the conversion of sphingosine to sphingosine 1 phosphate S1P Sphingolipids are ubiquitous membrane lipids Upon activation sphingosine kinase migrates from the cytosol to the plasma membrane where it transfers a g phosphate which is the last or terminal phosphate from ATP or GTP to sphingosine The S1P receptor is a GPCR receptor so S1P has the ability to regulate G protein signaling The resulting signal can activate intracellular effectors like ERKs Rho GTPase Rac GTPase PLC and AKT PI3K It can also exert its effect on target molecules inside the cell S1P has been shown to directly inhibit the histone deacetylase activity of HDACs In contrast the dephosphorylated sphingosine promotes cell apoptosis and it is therefore critical to understand the regulation of SKs because of its role in determining cell fate Past research shows that SKs may sustain cancer cell growth because they promote cellular proliferation and SK1 a specific type of SK is present at higher concentrations in certain types of cancers There are two kinases present in mammalian cells SK1 and SK2 SK1 is more specific compared to SK2 and their expression patterns differ as well SK1 is expressed in lung spleen and leukocyte cells whereas SK2 is expressed in kidney and liver cells The involvement of these two kinases in cell survival proliferation differentiation and inflammation makes them viable candidates for chemotherapeutic therapies 25 Carbohydrate kinases edit nbsp For many mammals carbohydrates provide a large portion of the daily caloric requirement To harvest energy from oligosaccharides they must first be broken down into monosaccharides so they can enter metabolism Kinases play an important role in almost all metabolic pathways The figure on the left shows the second phase of glycolysis which contains two important reactions catalyzed by kinases The anhydride linkage in 1 3 bisphosphoglycerate is unstable and has a high energy 1 3 bisphosphogylcerate kinase requires ADP to carry out its reaction yielding 3 phosphoglycerate and ATP In the final step of glycolysis pyruvate kinase transfers a phosphoryl group from phosphoenolpyruvate to ADP generating ATP and pyruvate Hexokinase is the most common enzyme that makes use of glucose when it first enters the cell It converts D glucose to glucose 6 phosphate by transferring the gamma phosphate of an ATP to the C6 position This is an important step in glycolysis because it traps glucose inside the cell due to the negative charge In its dephosphorylated form glucose can move back and forth across the membrane very easily 26 Mutations in the hexokinase gene can lead to a hexokinase deficiency which can cause nonspherocytic hemolytic anemia 27 Phosphofructokinase or PFK catalyzes the conversion of fructose 6 phosphate to fructose 1 6 bisphosphate and is an important point in the regulation of glycolysis High levels of ATP H and citrate inhibit PFK If citrate levels are high it means that glycolysis is functioning at an optimal rate High levels of AMP stimulate PFK Tarui s disease a glycogen storage disease that leads to exercise intolerance is due to a mutation in the PFK gene that reduces its activity 28 Other kinases edit nbsp The active site of riboflavin kinase bound to its products FMN on left and ADP on right Coordinates from PDB ID 1N07 29 Kinases act upon many other molecules besides proteins lipids and carbohydrates There are many that act on nucleotides DNA and RNA including those involved in nucleotide interconverstion such as nucleoside phosphate kinases and nucleoside diphosphate kinases 30 Other small molecules that are substrates of kinases include creatine phosphoglycerate riboflavin dihydroxyacetone shikimate and many others Riboflavin kinase edit Main article Riboflavin kinaseRiboflavin kinase catalyzes the phosphorylation of riboflavin to create flavin mononucleotide FMN It has an ordered binding mechanism where riboflavin must bind to the kinase before it binds to the ATP molecule 31 Divalent cations help coordinate the nucleotide 31 The general mechanism is shown in the figure below nbsp Mechanism of riboflavin kinase Riboflavin kinase plays an important role in cells as FMN is an important cofactor FMN also is a precursor to flavin adenine dinucleotide FAD a redox cofactor used by many enzymes including many in metabolism In fact there are some enzymes that are capable of carrying out both the phosphorylation of riboflavin to FMN as well as the FMN to FAD reaction 32 Riboflavin kinase may help prevent stroke and could possibly be used as a treatment in the future 33 It is also implicated in infection when studied in mice 34 Thymidine kinase edit Main article Thymidine kinase Thymidine kinase is one of the many nucleoside kinases that are responsible for nucleoside phosphorylation It phosphorylates thymidine to create thymidine monophosphate dTMP This kinase uses an ATP molecule to supply the phosphate to thymidine as shown below This transfer of a phosphate from one nucleotide to another by thymidine kinase as well as other nucleoside and nucleotide kinases functions to help control the level of each of the different nucleotides nbsp Overall reaction catalysed by thymidine kinase After creation of the dTMP molecule another kinase thymidylate kinase can act upon dTMP to create the diphosphate form dTDP Nucleoside diphosphate kinase catalyzes production of thymidine triphosphate dTTP which is used in DNA synthesis Because of this thymidine kinase activity is closely correlated with the cell cycle and used as a tumor marker in clinical chemistry 35 Therefore it can sometime be used to predict patient prognosis 36 Patients with mutations in the thymidine kinase gene may have a certain type of mitochondrial DNA depletion syndrome a disease that leads to death in early childhood 37 See also edit nbsp Wikimedia Commons has media related to Kinases Activation loop Autophosphorylation Ca2 calmodulin dependent protein kinase Cell signaling Cyclin dependent kinase G protein coupled receptor Nucleoside diphosphate kinase Phosphatase Phosphatidylinositol phosphate kinases Phospholipid Phosphoprotein Phosphorylation Phosphotransferase Signal transduction Thymidine kinase Thymidine kinase in clinical chemistry Thymidylate kinase Wall associated kinaseReferences edit Siebold C Arnold I Garcia Alles LF Baumann U HErnia B November 2003 Crystal structure of the Citrobacter freundii dihydroxyacetone kinase reveals an eight stranded alpha helical barrel AKTP binding domain The Journal of Biological Chemistry 278 48 48236 48244 doi 10 1074 jbc M305942200 PMID 12966101 kinase Dictionary com Unabridged Online n d Retrieved 2022 06 18 a b Manning G Whyte DB Martinez R Hunter T Sudarsanam S December 2002 The protein kinase complement of the human genome Science 298 5600 1912 1934 Bibcode 2002Sci 298 1912M doi 10 1126 science 1075762 PMID 12471243 S2CID 26554314 Kinase TheFreeDictionary com History of ATP research milestones from an ATP related chemistry Nobelprize org Reiterer V Eyers PA Farhan H September 2014 Day of the dead pseudokinases and pseudophosphatases in physiology and disease Trends in Cell Biology 24 9 489 505 doi 10 1016 j tcb 2014 03 008 PMID 24818526 Foulkes DM Byrne DP and Eyers PA 2017 Pseudokinases update on their functions and evaluation as new drug targets Future Med Chem 9 2 245 265 Samarasinghe B Hallmarks of Cancer 1 Scientific American Bleeker FE Lamba S Zanon C Molenaar RJ Hulsebos TJ Troost D et al September 2014 Mutational profiling of kinases in glioblastoma BMC Cancer 14 718 doi 10 1186 1471 2407 14 718 PMC 4192443 PMID 25256166 Lahiry P Torkamani A Schork NJ Hegele RA January 2010 Kinase mutations in human disease interpreting genotype phenotype relationships Nature Reviews Genetics 11 1 60 74 doi 10 1038 nrg2707 PMID 20019687 S2CID 37398118 Krebs EG July 1983 Historical perspectives on protein phosphorylation and a classification system for protein kinases Philosophical Transactions of the Royal Society of London Series B Biological Sciences 302 1108 3 11 Bibcode 1983RSPTB 302 3K doi 10 1098 rstb 1983 0033 PMID 6137005 Corbellino M Poirel L Aubin JT Paulli M Magrini U Bestetti G et al June 1996 The role of human herpesvirus 8 and Epstein Barr virus in the pathogenesis of giant lymph node hyperplasia Castleman s disease Clinical Infectious Diseases 22 6 1120 1121 doi 10 1093 clinids 22 6 1120 PMID 8783733 Scheeff ED Bourne PE October 2005 Structural evolution of the protein kinase like superfamily PLOS Computational Biology 1 5 e49 Bibcode 2005PLSCB 1 49S doi 10 1371 journal pcbi 0010049 PMC 1261164 PMID 16244704 a b Krebs EG October 1985 The phosphorylation of proteins a major mechanism for biological regulation Fourteenth Sir Frederick Gowland Hopkins memorial lecture Biochemical Society Transactions 13 5 813 820 doi 10 1042 bst0130813 PMID 2998902 Manning G Whyte DB Martinez R Hunter T Sudarsanam S December 2002 The protein kinase complement of the human genome Science 298 5600 1912 1934 Bibcode 2002Sci 298 1912M doi 10 1126 science 1075762 PMID 12471243 S2CID 26554314 Harper JW Adams PD August 2001 Cyclin dependent kinases Chemical Reviews 101 8 2511 2526 doi 10 1021 cr0001030 PMID 11749386 Karp G 2010 Cell and molecular biology concepts and experiments 6th ed Hoboken NJ John Wiley ISBN 9780470483374 Lim S Kaldis P August 2013 Cdks cyclins and CKIs roles beyond cell cycle regulation Development 140 15 3079 3093 doi 10 1242 dev 091744 PMID 23861057 a b Canavese M Santo L Raje N May 2012 Cyclin dependent kinases in cancer potential for therapeutic intervention Cancer Biology amp Therapy 13 7 451 457 doi 10 4161 cbt 19589 PMID 22361734 a b Garrington TP Johnson GL April 1999 Organization and regulation of mitogen activated protein kinase signaling pathways Current Opinion in Cell Biology 11 2 211 218 doi 10 1016 s0955 0674 99 80028 3 PMID 10209154 Sun Y Thapa N Hedman AC Anderson RA June 2013 Phosphatidylinositol 4 5 bisphosphate targeted production and signaling BioEssays 35 6 513 522 doi 10 1002 bies 201200171 PMC 3882169 PMID 23575577 Heath CM Stahl PD Barbieri MA July 2003 Lipid kinases play crucial and multiple roles in membrane trafficking and signaling Histology and Histopathology 18 3 989 998 doi 10 14670 HH 18 989 PMID 12792909 Cantley LC 2012 PI 3 kinase and disease BMC Proceedings 6 Suppl 3 O2 doi 10 1186 1753 6561 6 S3 O2 PMC 3395034 a b c Miller S Tavshanjian B Oleksy A Perisic O Houseman BT Shokat KM Williams RL March 2010 Shaping development of autophagy inhibitors with the structure of the lipid kinase Vps34 Science 327 5973 1638 1642 Bibcode 2010Sci 327 1638M doi 10 1126 science 1184429 PMC 2860105 PMID 20339072 Neubauer HA Pitson SM November 2013 Roles regulation and inhibitors of sphingosine kinase 2 The FEBS Journal 280 21 5317 5336 doi 10 1111 febs 12314 PMID 23638983 Holzer H Duntze W 1971 Metabolic regulation by chemical modification of enzymes Annual Review of Biochemistry 40 345 374 doi 10 1146 annurev bi 40 070171 002021 PMID 4399446 Nonspherocytic hemolytic anemia due to hexokinase deficiency Archived from the original on 2015 09 05 Retrieved 2014 02 24 Phosphofructokinase Deficiency Glycogen Storage Disease Bauer S Kemter K Bacher A Huber R Fischer M Steinbacher S March 2003 Crystal structure of Schizosaccharomyces pombe riboflavin kinase reveals a novel ATP and riboflavin binding fold Journal of Molecular Biology 326 5 1463 1473 doi 10 1016 s0022 2836 03 00059 7 PMID 12595258 Voet D Voet JC Pratt CW 2008 Fundamentals of biochemistry life at the molecular level 3rd ed Hoboken NJ Wiley ISBN 9780470129302 a b Karthikeyan S Zhou Q Osterman AL Zhang H November 2003 Ligand binding induced conformational changes in riboflavin kinase structural basis for the ordered mechanism Biochemistry 42 43 12532 12538 doi 10 1021 bi035450t PMID 14580199 Galluccio M Brizio C Torchetti EM Ferranti P Gianazza E Indiveri C Barile M March 2007 Over expression in Escherichia coli purification and characterization of isoform 2 of human FAD synthetase Protein Expression and Purification 52 1 175 181 doi 10 1016 j pep 2006 09 002 PMID 17049878 Zou YX Zhang XH Su FY Liu X October 2012 Importance of riboflavin kinase in the pathogenesis of stroke CNS Neuroscience amp Therapeutics 18 10 834 840 doi 10 1111 j 1755 5949 2012 00379 x PMC 6493343 PMID 22925047 Brijlal S Lakshmi AV Bamji MS Suresh P September 1996 Flavin metabolism during respiratory infection in mice The British Journal of Nutrition 76 3 453 462 doi 10 1079 BJN19960050 PMID 8881717 Aufderklamm S Todenhofer T Gakis G Kruck S Hennenlotter J Stenzl A Schwentner C March 2012 Thymidine kinase and cancer monitoring Cancer Letters 316 1 6 10 doi 10 1016 j canlet 2011 10 025 PMID 22068047 Topolcan O Holubec L February 2008 The role of thymidine kinase in cancer diseases Expert Opinion on Medical Diagnostics 2 2 129 141 doi 10 1517 17530059 2 2 129 PMID 23485133 Gotz A Isohanni P Pihko H Paetau A Herva R Saarenpaa Heikkila O et al November 2008 Thymidine kinase 2 defects can cause multi tissue mtDNA depletion syndrome Brain 131 Pt 11 2841 2850 doi 10 1093 brain awn236 PMID 18819985 Portal nbsp Biology Retrieved from https en wikipedia org w index php title Kinase amp oldid 1187980553, wikipedia, wiki, book, books, library,

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