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Calmodulin

February 15, 2024

Calmodulin (CaM) (an abbreviation for calcium-modulated protein) is a multifunctional intermediate calcium-binding messenger protein expressed in all eukaryotic cells.[1] It is an intracellular target of the secondary messenger Ca2+, and the binding of Ca2+ is required for the activation of calmodulin. Once bound to Ca2+, calmodulin acts as part of a calcium signal transduction pathway by modifying its interactions with various target proteins such as kinases or phosphatases.[2][3][4]

Calmodulin
3D structure of Ca2+-bound calmodulin (PDB: 1OSA​)
Identifiers
SymbolCaM
PDB1OSA
UniProtP62158
Search for
StructuresSwiss-model
DomainsInterPro
The helix–loop–helix structure of the calcium-binding EF hand motif

Structure edit

Calmodulin is a small, highly conserved protein that is 148 amino acids long (16.7 kDa). The protein has two approximately symmetrical globular domains (the N- and C- domains) each containing a pair of EF hand motifs[5] separated by a flexible linker region for a total of four Ca2+ binding sites, two in each globular domain.[6] In the Ca2+-free state, the helices that form the four EF-hands are collapsed in a compact orientation, and the central linker is disordered;[5][6][7][8] in the Ca2+-saturated state, the EF-hand helices adopt an open orientation roughly perpendicular to one another, and the central linker forms an extended alpha-helix in the crystal structure,[5][6] but remains largely disordered in solution.[9] The C-domain has a higher binding affinity for Ca2+ than the N-domain.[10][11]

Calmodulin is structurally quite similar to troponin C, another Ca2+-binding protein containing four EF-hand motifs.[5][12] However, troponin C contains an additional alpha-helix at its N-terminus, and is constitutively bound to its target, troponin I. It therefore does not exhibit the same diversity of target recognition as does calmodulin.

Importance of flexibility in calmodulin edit

Calmodulin's ability to recognize a tremendous range of target proteins is due in large part to its structural flexibility.[13] In addition to the flexibility of the central linker domain, the N- and C-domains undergo open-closed conformational cycling in the Ca2+-bound state.[9] Calmodulin also exhibits great structural variability, and undergoes considerable conformational fluctuations, when bound to targets.[14][15][16] Moreover, the predominantly hydrophobic nature of binding between calmodulin and most of its targets allows for recognition of a broad range of target protein sequences.[14][17] Together, these features allow calmodulin to recognize some 300 target proteins[18] exhibiting a variety of CaM-binding sequence motifs.

Mechanism edit

 
This images shows conformational changes in calmodulin. On the left is calmodulin without calcium and on the right is calmodulin with calcium. Sites that bind target proteins are indicated by red stars.
 
Solution structure of Ca2+-calmodulin C-terminal domain
 
Solution structure of Ca2+-calmodulin N-terminal domain

Binding of Ca2+ by the EF-hands causes an opening of the N- and C-domains, which exposes hydrophobic target-binding surfaces.[6] These surfaces interact with complementary nonpolar segments on target proteins, typically consisting of groups of bulky hydrophobic amino acids separated by 10–16 polar and/or basic amino acids.[18][14] The flexible central domain of calmodulin allows the protein to wrap around its target, although alternate modes of binding are known. "Canonical" targets of calmodulin, such as myosin light-chain kinases and CaMKII, bind only to the Ca2+-bound protein, whereas some proteins, such as NaV channels and IQ-motif proteins, also bind to calmodulin in the absence of Ca2+.[14] Binding of calmodulin induces conformational rearrangements in the target protein via "mutually induced fit",[19] leading to changes in the target protein's function.

Calcium binding by calmodulin exhibits considerable cooperativity,[5][11] making calmodulin an unusual example of a monomeric (single-chain) cooperative binding protein. Furthermore, target binding alters the binding affinity of calmodulin toward Ca2+ ions,[20][21][22] which allows for complex allosteric interplay between Ca2+ and target binding interactions.[23] This influence of target binding on Ca2+ affinity is believed to allow for Ca2+ activation of proteins that are constitutively bound to calmodulin, such as small-conductance Ca2+-activated potassium (SK) channels.[24]

Although calmodulin principally operates as a Ca2+ binding protein, it also coordinates other metal ions. For example, in the presence of typical intracellular concentrations of Mg2+ (0.5–1.0 mM) and resting concentrations of Ca2+ (100 nM), calmodulin's Ca2+ binding sites are at least partially saturated by Mg2+.[25] This Mg2+ is displaced by the higher concentrations of Ca2+ generated by signaling events. Similarly, Ca2+ may itself be displaced by other metal ions, such as the trivalent lanthanides, that associate with calmodulin's binding pockets even more strongly than Ca2+.[26][27] Though such ions distort calmodulin's structure[28][29] and are generally not physiologically relevant due to their scarcity in vivo, they have nonetheless seen wide scientific use as reporters of calmodulin structure and function.[30][31][26]

Role in animals edit

Calmodulin mediates many crucial processes such as inflammation, metabolism, apoptosis, smooth muscle contraction, intracellular movement, short-term and long-term memory, and the immune response.[32][33] Calcium participates in an intracellular signaling system by acting as a diffusible second messenger to the initial stimuli. It does this by binding various targets in the cell including a large number of enzymes, ion channels, aquaporins and other proteins.[4] Calmodulin is expressed in many cell types and can have different subcellular locations, including the cytoplasm, within organelles, or associated with the plasma or organelle membranes, but it is always found intracellularly.[33] Many of the proteins that calmodulin binds are unable to bind calcium themselves, and use calmodulin as a calcium sensor and signal transducer. Calmodulin can also make use of the calcium stores in the endoplasmic reticulum, and the sarcoplasmic reticulum. Calmodulin can undergo post-translational modifications, such as phosphorylation, acetylation, methylation and proteolytic cleavage, each of which has potential to modulate its actions.

Specific examples edit

Role in smooth muscle contraction edit

 
Calmodulin bound to a peptide from MLC kinase (PDB: 2LV6​)

Calmodulin plays an important role in excitation contraction (EC) coupling and the initiation of the cross-bridge cycling in smooth muscle, ultimately causing smooth muscle contraction.[34] In order to activate contraction of smooth muscle, the head of the myosin light chain must be phosphorylated. This phosphorylation is done by myosin light chain (MLC) kinase. This MLC kinase is activated by a calmodulin when it is bound by calcium, thus making smooth muscle contraction dependent on the presence of calcium, through the binding of calmodulin and activation of MLC kinase.[34]

Another way that calmodulin affects muscle contraction is by controlling the movement of Ca2+ across both the cell and sarcoplasmic reticulum membranes. The Ca2+ channels, such as the ryanodine receptor of the sarcoplasmic reticulum, can be inhibited by calmodulin bound to calcium, thus affecting the overall levels of calcium in the cell.[35] Calcium pumps take calcium out of the cytoplasm or store it in the endoplasmic reticulum and this control helps regulate many downstream processes.

This is a very important function of calmodulin because it indirectly plays a role in every physiological process that is affected by smooth muscle contraction such as digestion and contraction of arteries (which helps distribute blood and regulate blood pressure).[36]

Role in metabolism edit

Calmodulin plays an important role in the activation of phosphorylase kinase, which ultimately leads to glucose being cleaved from glycogen by glycogen phosphorylase.[37]

Calmodulin also plays an important role in lipid metabolism by affecting calcitonin. Calcitonin is a polypeptide hormone that lowers blood Ca2+ levels and activates G protein cascades that leads to the generation of cAMP. The actions of calcitonin can be blocked by inhibiting the actions of calmodulin, suggesting that calmodulin plays a crucial role in the activation of calcitonin.[37]

Role in short-term and long-term memory edit

Ca2+/calmodulin-dependent protein kinase II (CaMKII) plays a crucial role in a type of synaptic plasticity known as long-term potentiation (LTP) which requires the presence of calcium/calmodulin. CaMKII contributes to the phosphorylation of an AMPA receptor which increases the sensitivity of AMPA receptors.[38] Furthermore, research shows that inhibiting CaMKII interferes with LTP.[38]

Role in plants edit

 
Sorghum plant contains temperature-responsive genes. These genes help the plant adapt in extreme weather conditions such as hot and dry environments.

While yeasts have only a single CaM gene, plants and vertebrates contain an evolutionarily conserved form of CaM genes. The difference between plants and animals in Ca2+ signaling is that the plants contain an extended family of the CaM in addition to the evolutionarily conserved form.[39] Calmodulins play an essential role in plant development and adaptation to environmental stimuli.

Calcium plays a key role in the structural integrity of the cell wall and the membrane system of the cell. However, high calcium levels can be toxic to a plant's cellular energy metabolism and, hence, the Ca2+ concentration in the cytosol is maintained at a submicromolar level by removing the cytosolic Ca2+ to either the apoplast or the lumen of the intracellular organelles. Ca2+ pulses created due to increased influx and efflux act as cellular signals in response to external stimuli such as hormones, light, gravity, abiotic stress factors and also interactions with pathogens.[40]

CMLs (CaM-related proteins) edit

Plants contain CaM-related proteins (CMLs) apart from the typical CaM proteins. The CMLs have about 15% amino acid similarity with the typical CaMs. Arabidopsis thaliana contains about 50 different CML genes which leads to the question of what purpose these diverse ranges of proteins serve in the cellular function. All plant species exhibit this diversity in the CML genes. The different CaMs and CMLs differ in their affinity to bind and activate the CaM-regulated enzymes in vivo. The CaM or CMLs are also found to be located in different organelle compartments.

Plant growth and development edit

In Arabidopsis, the protein DWF1 plays an enzymatic role in the biosynthesis of brassinosteroids, steroid hormones in plants that are required for growth. An interaction occurs between CaM and DWF1,[clarification needed] and DWF1 being unable to bind CaM is unable to produce a regular growth phenotype in plants. Hence, CaM is essential for the DWF1 function in plant growth.

CaM binding proteins are also known to regulate reproductive development in plants. For instance, the CaM-binding protein kinase in tobacco acts as a negative regulator of flowering. However, these CaM-binding protein kinase are also present in the shoot apical meristem of tobacco and a high concentration of these kinases in the meristem causes a delayed transition to flowering in the plant.

S-locus receptor kinase (SRK) is another protein kinase that interacts with CaM. SRK is involved in the self-incompatibility responses involved in pollen-pistil interactions in Brassica.

CaM targets in Arabidopsis are also involved in pollen development and fertilization. Ca2+ transporters are essential for pollen tube growth. Hence, a constant Ca2+ gradient is maintained at the apex of pollen tube for elongation during the process of fertilization. Similarly, CaM is also essential at the pollen tube apex, where its primarily role involves the guidance of the pollen tube growth.

Interaction with microbes edit

Nodule formation edit

Ca2+ plays an important role in nodule formation in legumes. Nitrogen is an essential element required in plants and many legumes, unable to fix nitrogen independently, pair symbiotically with nitrogen-fixing bacteria that reduce nitrogen to ammonia. This legume-Rhizobium interaction establishment requires the Nod factor that is produced by the Rhizobium bacteria. The Nod factor is recognized by the root hair cells that are involved in the nodule formation in legumes. Ca2+ responses of varied nature are characterized to be involved in the Nod factor recognition. There is a Ca2+ flux at the tip of the root hair initially followed by repetitive oscillation of Ca2+ in the cytosol and also Ca2+ spike occurs around the nucleus. DMI3, an essential gene for Nod factor signaling functions downstream of the Ca2+ spiking signature, might be recognizing the Ca2+ signature. Further, several CaM and CML genes in Medicago and Lotus are expressed in nodules.

Pathogen defense edit

Among the diverse range of defense strategies plants utilize against pathogens, Ca2+ signaling is very common. Free Ca2+ levels in the cytoplasm increases in response to a pathogenic infection. Ca2+ signatures of this nature usually activate the plant defense system by inducing defense-related genes and the hypersensitive cell death. CaMs, CMLs and CaM-binding proteins are some of the recently identified elements of the plant defense signaling pathways. Several CML genes in tobacco, bean and tomato are responsive to pathogens. CML43 is a CaM-related protein that, as isolated from APR134 gene in the disease-resistant leaves of Arabidopsis for gene expression analysis, is rapidly induced when the leaves are inoculated with Pseudomonas syringae. These genes are also found in tomatoes (Solanum lycopersicum). The CML43 from the APR134 also binds to Ca2+ ions in vitro which shows that CML43 and APR134 are, hence, involved in the Ca2+-dependent signaling during the plant immune response to bacterial pathogens.[41] The CML9 expression in Arabidopsis thaliana is rapidly induced by phytopathogenic bacteria, flagellin and salicylic acid.[42] Expression of soybean SCaM4 and SCaM5 in transgenic tobacco and Arabidopsis causes an activation of genes related to pathogen resistance and also results in enhanced resistance to a wide spectrum of pathogen infection. The same is not true for soybean SCaM1 and SCaM2 that are highly conserved CaM isoforms. The AtBAG6 protein is a CaM-binding protein that binds to CaM only in the absence of Ca2+ and not in the presence of it. AtBAG6 is responsible for the hypersensitive response of programmed cell death in order to prevent the spread of pathogen infection or to restrict pathogen growth. Mutations in the CaM binding proteins can lead to severe effects on the defense response of the plants towards pathogen infections. Cyclic nucleotide-gated channels (CNGCs) are functional protein channels in the plasma membrane that have overlapping CaM binding sites transport divalent cations such as Ca2+. However, the exact role of the positioning of the CNGCs in this pathway for plant defense is still unclear.

Abiotic stress response in plants edit

Change in intracellular Ca2+ levels is used as a signature for diverse responses towards mechanical stimuli, osmotic and salt treatments, and cold and heat shocks. Different root cell types show a different Ca2+ response to osmotic and salt stresses and this implies the cellular specificities of Ca2+ patterns. In response to external stress CaM activates glutamate decarboxylase (GAD) that catalyzes the conversion of L-glutamate to GABA. A tight control on the GABA synthesis is important for plant development and, hence, increased GABA levels can essentially affect plant development. Therefore, external stress can affect plant growth and development and CaM are involved in that pathway controlling this effect.[citation needed]

Plant examples edit

Sorghum edit

The plant sorghum is well established model organism and can adapt in hot and dry environments. For this reason, it is used as a model to study calmodulin's role in plants.[43] Sorghum contains seedlings that express a glycine-rich RNA-binding protein, SbGRBP. This particular protein can be modulated by using heat as a stressor. Its unique location in the cell nucleus and cytosol demonstrates interaction with calmodulin that requires the use of Ca2+.[44] By exposing the plant to versatile stress conditions, it can cause different proteins that enable the plant cells to tolerate environmental changes to become repressed. These modulated stress proteins are shown to interact with CaM. The CaMBP genes expressed in the sorghum are depicted as a “model crop” for researching the tolerance to heat and drought stress.

Arabidopsis edit

In an Arabidopsis thaliana study, hundreds of different proteins demonstrated the possibility to bind to CaM in plants.[43]

Family members edit

Other calcium-binding proteins edit

Calmodulin belongs to one of the two main groups of calcium-binding proteins, called EF hand proteins. The other group, called annexins, bind calcium and phospholipids such as lipocortin. Many other proteins bind calcium, although binding calcium may not be considered their principal function in the cell.

See also edit

References edit

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External links edit

  • . Molecule of the Month. RCSB PDB. July 2020. Archived from the original on 2010-05-29. Retrieved 2021-06-19.
  • Nelson M, Chazin W. "Home Page for Calmodulin". EF-Hand Calcium-Binding Proteins Data Library. Vanderbilt University. Retrieved 2008-03-22.
  • Ikura M (2000). "Calmodulin Target Database". Journal of Structural and Functional Genomics. Ontario Cancer Institute, University of Toronto. 1 (1): 8–14. doi:10.1023/a:1011320027914. PMID 12836676. S2CID 23097597. Retrieved 2008-03-22.
  • Calmodulin at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  • InterProIPR015754
  • Proteopedia page for Calmodulin and its conformational change

February 15, 2024
calmodulin, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, december, 2007,. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Calmodulin news newspapers books scholar JSTOR December 2007 Learn how and when to remove this template message Calmodulin CaM an abbreviation for calcium modulated protein is a multifunctional intermediate calcium binding messenger protein expressed in all eukaryotic cells 1 It is an intracellular target of the secondary messenger Ca2 and the binding of Ca2 is required for the activation of calmodulin Once bound to Ca2 calmodulin acts as part of a calcium signal transduction pathway by modifying its interactions with various target proteins such as kinases or phosphatases 2 3 4 Calmodulin3D structure of Ca2 bound calmodulin PDB 1OSA IdentifiersSymbolCaMPDB1OSAUniProtP62158Search forStructuresSwiss modelDomainsInterProThe helix loop helix structure of the calcium binding EF hand motif Contents 1 Structure 1 1 Importance of flexibility in calmodulin 2 Mechanism 3 Role in animals 3 1 Specific examples 3 1 1 Role in smooth muscle contraction 3 1 2 Role in metabolism 3 1 3 Role in short term and long term memory 4 Role in plants 4 1 CMLs CaM related proteins 4 2 Plant growth and development 4 3 Interaction with microbes 4 3 1 Nodule formation 4 3 2 Pathogen defense 4 4 Abiotic stress response in plants 4 5 Plant examples 4 5 1 Sorghum 4 5 2 Arabidopsis 5 Family members 6 Other calcium binding proteins 7 See also 8 References 9 External linksStructure editCalmodulin is a small highly conserved protein that is 148 amino acids long 16 7 kDa The protein has two approximately symmetrical globular domains the N and C domains each containing a pair of EF hand motifs 5 separated by a flexible linker region for a total of four Ca2 binding sites two in each globular domain 6 In the Ca2 free state the helices that form the four EF hands are collapsed in a compact orientation and the central linker is disordered 5 6 7 8 in the Ca2 saturated state the EF hand helices adopt an open orientation roughly perpendicular to one another and the central linker forms an extended alpha helix in the crystal structure 5 6 but remains largely disordered in solution 9 The C domain has a higher binding affinity for Ca2 than the N domain 10 11 Calmodulin is structurally quite similar to troponin C another Ca2 binding protein containing four EF hand motifs 5 12 However troponin C contains an additional alpha helix at its N terminus and is constitutively bound to its target troponin I It therefore does not exhibit the same diversity of target recognition as does calmodulin Importance of flexibility in calmodulin edit Calmodulin s ability to recognize a tremendous range of target proteins is due in large part to its structural flexibility 13 In addition to the flexibility of the central linker domain the N and C domains undergo open closed conformational cycling in the Ca2 bound state 9 Calmodulin also exhibits great structural variability and undergoes considerable conformational fluctuations when bound to targets 14 15 16 Moreover the predominantly hydrophobic nature of binding between calmodulin and most of its targets allows for recognition of a broad range of target protein sequences 14 17 Together these features allow calmodulin to recognize some 300 target proteins 18 exhibiting a variety of CaM binding sequence motifs Mechanism edit nbsp This images shows conformational changes in calmodulin On the left is calmodulin without calcium and on the right is calmodulin with calcium Sites that bind target proteins are indicated by red stars nbsp Solution structure of Ca2 calmodulin C terminal domain nbsp Solution structure of Ca2 calmodulin N terminal domainBinding of Ca2 by the EF hands causes an opening of the N and C domains which exposes hydrophobic target binding surfaces 6 These surfaces interact with complementary nonpolar segments on target proteins typically consisting of groups of bulky hydrophobic amino acids separated by 10 16 polar and or basic amino acids 18 14 The flexible central domain of calmodulin allows the protein to wrap around its target although alternate modes of binding are known Canonical targets of calmodulin such as myosin light chain kinases and CaMKII bind only to the Ca2 bound protein whereas some proteins such as NaV channels and IQ motif proteins also bind to calmodulin in the absence of Ca2 14 Binding of calmodulin induces conformational rearrangements in the target protein via mutually induced fit 19 leading to changes in the target protein s function Calcium binding by calmodulin exhibits considerable cooperativity 5 11 making calmodulin an unusual example of a monomeric single chain cooperative binding protein Furthermore target binding alters the binding affinity of calmodulin toward Ca2 ions 20 21 22 which allows for complex allosteric interplay between Ca2 and target binding interactions 23 This influence of target binding on Ca2 affinity is believed to allow for Ca2 activation of proteins that are constitutively bound to calmodulin such as small conductance Ca2 activated potassium SK channels 24 Although calmodulin principally operates as a Ca2 binding protein it also coordinates other metal ions For example in the presence of typical intracellular concentrations of Mg2 0 5 1 0 mM and resting concentrations of Ca2 100 nM calmodulin s Ca2 binding sites are at least partially saturated by Mg2 25 This Mg2 is displaced by the higher concentrations of Ca2 generated by signaling events Similarly Ca2 may itself be displaced by other metal ions such as the trivalent lanthanides that associate with calmodulin s binding pockets even more strongly than Ca2 26 27 Though such ions distort calmodulin s structure 28 29 and are generally not physiologically relevant due to their scarcity in vivo they have nonetheless seen wide scientific use as reporters of calmodulin structure and function 30 31 26 Role in animals editCalmodulin mediates many crucial processes such as inflammation metabolism apoptosis smooth muscle contraction intracellular movement short term and long term memory and the immune response 32 33 Calcium participates in an intracellular signaling system by acting as a diffusible second messenger to the initial stimuli It does this by binding various targets in the cell including a large number of enzymes ion channels aquaporins and other proteins 4 Calmodulin is expressed in many cell types and can have different subcellular locations including the cytoplasm within organelles or associated with the plasma or organelle membranes but it is always found intracellularly 33 Many of the proteins that calmodulin binds are unable to bind calcium themselves and use calmodulin as a calcium sensor and signal transducer Calmodulin can also make use of the calcium stores in the endoplasmic reticulum and the sarcoplasmic reticulum Calmodulin can undergo post translational modifications such as phosphorylation acetylation methylation and proteolytic cleavage each of which has potential to modulate its actions Specific examples edit Role in smooth muscle contraction edit nbsp Calmodulin bound to a peptide from MLC kinase PDB 2LV6 Calmodulin plays an important role in excitation contraction EC coupling and the initiation of the cross bridge cycling in smooth muscle ultimately causing smooth muscle contraction 34 In order to activate contraction of smooth muscle the head of the myosin light chain must be phosphorylated This phosphorylation is done by myosin light chain MLC kinase This MLC kinase is activated by a calmodulin when it is bound by calcium thus making smooth muscle contraction dependent on the presence of calcium through the binding of calmodulin and activation of MLC kinase 34 Another way that calmodulin affects muscle contraction is by controlling the movement of Ca2 across both the cell and sarcoplasmic reticulum membranes The Ca2 channels such as the ryanodine receptor of the sarcoplasmic reticulum can be inhibited by calmodulin bound to calcium thus affecting the overall levels of calcium in the cell 35 Calcium pumps take calcium out of the cytoplasm or store it in the endoplasmic reticulum and this control helps regulate many downstream processes This is a very important function of calmodulin because it indirectly plays a role in every physiological process that is affected by smooth muscle contraction such as digestion and contraction of arteries which helps distribute blood and regulate blood pressure 36 Role in metabolism edit Calmodulin plays an important role in the activation of phosphorylase kinase which ultimately leads to glucose being cleaved from glycogen by glycogen phosphorylase 37 Calmodulin also plays an important role in lipid metabolism by affecting calcitonin Calcitonin is a polypeptide hormone that lowers blood Ca2 levels and activates G protein cascades that leads to the generation of cAMP The actions of calcitonin can be blocked by inhibiting the actions of calmodulin suggesting that calmodulin plays a crucial role in the activation of calcitonin 37 Role in short term and long term memory edit Ca2 calmodulin dependent protein kinase II CaMKII plays a crucial role in a type of synaptic plasticity known as long term potentiation LTP which requires the presence of calcium calmodulin CaMKII contributes to the phosphorylation of an AMPA receptor which increases the sensitivity of AMPA receptors 38 Furthermore research shows that inhibiting CaMKII interferes with LTP 38 Role in plants editThis section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed March 2020 Learn how and when to remove this template message nbsp Sorghum plant contains temperature responsive genes These genes help the plant adapt in extreme weather conditions such as hot and dry environments While yeasts have only a single CaM gene plants and vertebrates contain an evolutionarily conserved form of CaM genes The difference between plants and animals in Ca2 signaling is that the plants contain an extended family of the CaM in addition to the evolutionarily conserved form 39 Calmodulins play an essential role in plant development and adaptation to environmental stimuli Calcium plays a key role in the structural integrity of the cell wall and the membrane system of the cell However high calcium levels can be toxic to a plant s cellular energy metabolism and hence the Ca2 concentration in the cytosol is maintained at a submicromolar level by removing the cytosolic Ca2 to either the apoplast or the lumen of the intracellular organelles Ca2 pulses created due to increased influx and efflux act as cellular signals in response to external stimuli such as hormones light gravity abiotic stress factors and also interactions with pathogens 40 CMLs CaM related proteins edit Plants contain CaM related proteins CMLs apart from the typical CaM proteins The CMLs have about 15 amino acid similarity with the typical CaMs Arabidopsis thaliana contains about 50 different CML genes which leads to the question of what purpose these diverse ranges of proteins serve in the cellular function All plant species exhibit this diversity in the CML genes The different CaMs and CMLs differ in their affinity to bind and activate the CaM regulated enzymes in vivo The CaM or CMLs are also found to be located in different organelle compartments Plant growth and development edit In Arabidopsis the protein DWF1 plays an enzymatic role in the biosynthesis of brassinosteroids steroid hormones in plants that are required for growth An interaction occurs between CaM and DWF1 clarification needed and DWF1 being unable to bind CaM is unable to produce a regular growth phenotype in plants Hence CaM is essential for the DWF1 function in plant growth CaM binding proteins are also known to regulate reproductive development in plants For instance the CaM binding protein kinase in tobacco acts as a negative regulator of flowering However these CaM binding protein kinase are also present in the shoot apical meristem of tobacco and a high concentration of these kinases in the meristem causes a delayed transition to flowering in the plant S locus receptor kinase SRK is another protein kinase that interacts with CaM SRK is involved in the self incompatibility responses involved in pollen pistil interactions in Brassica CaM targets in Arabidopsis are also involved in pollen development and fertilization Ca2 transporters are essential for pollen tube growth Hence a constant Ca2 gradient is maintained at the apex of pollen tube for elongation during the process of fertilization Similarly CaM is also essential at the pollen tube apex where its primarily role involves the guidance of the pollen tube growth Interaction with microbes edit Nodule formation edit Ca2 plays an important role in nodule formation in legumes Nitrogen is an essential element required in plants and many legumes unable to fix nitrogen independently pair symbiotically with nitrogen fixing bacteria that reduce nitrogen to ammonia This legume Rhizobium interaction establishment requires the Nod factor that is produced by the Rhizobium bacteria The Nod factor is recognized by the root hair cells that are involved in the nodule formation in legumes Ca2 responses of varied nature are characterized to be involved in the Nod factor recognition There is a Ca2 flux at the tip of the root hair initially followed by repetitive oscillation of Ca2 in the cytosol and also Ca2 spike occurs around the nucleus DMI3 an essential gene for Nod factor signaling functions downstream of the Ca2 spiking signature might be recognizing the Ca2 signature Further several CaM and CML genes in Medicago and Lotus are expressed in nodules Pathogen defense edit Among the diverse range of defense strategies plants utilize against pathogens Ca2 signaling is very common Free Ca2 levels in the cytoplasm increases in response to a pathogenic infection Ca2 signatures of this nature usually activate the plant defense system by inducing defense related genes and the hypersensitive cell death CaMs CMLs and CaM binding proteins are some of the recently identified elements of the plant defense signaling pathways Several CML genes in tobacco bean and tomato are responsive to pathogens CML43 is a CaM related protein that as isolated from APR134 gene in the disease resistant leaves of Arabidopsis for gene expression analysis is rapidly induced when the leaves are inoculated with Pseudomonas syringae These genes are also found in tomatoes Solanum lycopersicum The CML43 from the APR134 also binds to Ca2 ions in vitro which shows that CML43 and APR134 are hence involved in the Ca2 dependent signaling during the plant immune response to bacterial pathogens 41 The CML9 expression in Arabidopsis thaliana is rapidly induced by phytopathogenic bacteria flagellin and salicylic acid 42 Expression of soybean SCaM4 and SCaM5 in transgenic tobacco and Arabidopsis causes an activation of genes related to pathogen resistance and also results in enhanced resistance to a wide spectrum of pathogen infection The same is not true for soybean SCaM1 and SCaM2 that are highly conserved CaM isoforms The AtBAG6 protein is a CaM binding protein that binds to CaM only in the absence of Ca2 and not in the presence of it AtBAG6 is responsible for the hypersensitive response of programmed cell death in order to prevent the spread of pathogen infection or to restrict pathogen growth Mutations in the CaM binding proteins can lead to severe effects on the defense response of the plants towards pathogen infections Cyclic nucleotide gated channels CNGCs are functional protein channels in the plasma membrane that have overlapping CaM binding sites transport divalent cations such as Ca2 However the exact role of the positioning of the CNGCs in this pathway for plant defense is still unclear Abiotic stress response in plants edit Change in intracellular Ca2 levels is used as a signature for diverse responses towards mechanical stimuli osmotic and salt treatments and cold and heat shocks Different root cell types show a different Ca2 response to osmotic and salt stresses and this implies the cellular specificities of Ca2 patterns In response to external stress CaM activates glutamate decarboxylase GAD that catalyzes the conversion of L glutamate to GABA A tight control on the GABA synthesis is important for plant development and hence increased GABA levels can essentially affect plant development Therefore external stress can affect plant growth and development and CaM are involved in that pathway controlling this effect citation needed Plant examples edit Sorghum edit The plant sorghum is well established model organism and can adapt in hot and dry environments For this reason it is used as a model to study calmodulin s role in plants 43 Sorghum contains seedlings that express a glycine rich RNA binding protein SbGRBP This particular protein can be modulated by using heat as a stressor Its unique location in the cell nucleus and cytosol demonstrates interaction with calmodulin that requires the use of Ca2 44 By exposing the plant to versatile stress conditions it can cause different proteins that enable the plant cells to tolerate environmental changes to become repressed These modulated stress proteins are shown to interact with CaM The CaMBP genes expressed in the sorghum are depicted as a model crop for researching the tolerance to heat and drought stress Arabidopsis edit In an Arabidopsis thaliana study hundreds of different proteins demonstrated the possibility to bind to CaM in plants 43 Family members editCalmodulin 1 CALM1 Calmodulin 2 CALM2 Calmodulin 3 CALM3 calmodulin 1 pseudogene 1 CALM1P1 Calmodulin like 3 CALML3 Calmodulin like 4 CALML4 Calmodulin like 5 CALML5 Calmodulin like 6 CALML6 Other calcium binding proteins editCalmodulin belongs to one of the two main groups of calcium binding proteins called EF hand proteins The other group called annexins bind calcium and phospholipids such as lipocortin Many other proteins bind calcium although binding calcium may not be considered their principal function in the cell See also editProtein kinase Ca2 calmodulin dependent protein kinaseReferences edit Stevens FC August 1983 Calmodulin an introduction Canadian Journal of Biochemistry and Cell Biology 61 8 906 10 doi 10 1139 o83 115 PMID 6313166 Chin D Means AR August 2000 Calmodulin a prototypical calcium sensor Trends in Cell Biology 10 8 322 8 doi 10 1016 S0962 8924 00 01800 6 PMID 10884684 Purves D Augustine G Fitzpatrick D Hall W LaMantia AS White L 2012 Neuroscience Massachusetts Sinauer Associates pp 95 147 148 ISBN 9780878936953 a b CALM1 Calmodulin Homo sapiens Human CALM1 gene amp protein www uniprot org Retrieved 2016 02 23 a b c d e Gifford JL Walsh MP Vogel HJ July 2007 Structures and metal ion binding properties of the Ca2 binding helix loop helix EF hand motifs The Biochemical Journal 405 2 199 221 doi 10 1042 BJ20070255 PMID 17590154 a b c d Chin D Means AR August 2000 Calmodulin a prototypical calcium sensor Trends in Cell Biology 10 8 322 8 doi 10 1016 s0962 8924 00 01800 6 PMID 10884684 Kuboniwa H Tjandra N Grzesiek S Ren H Klee CB Bax A September 1995 Solution structure of calcium free calmodulin Nature Structural Biology 2 9 768 76 doi 10 1038 nsb0995 768 PMID 7552748 S2CID 22220229 Zhang M Tanaka T Ikura M September 1995 Calcium induced conformational transition revealed by the solution structure of apo calmodulin Nature Structural Biology 2 9 758 67 doi 10 1038 nsb0995 758 PMID 7552747 S2CID 35098883 a b Chou JJ Li S Klee CB Bax A November 2001 Solution structure of Ca 2 calmodulin reveals flexible hand like properties of its domains Nature Structural Biology 8 11 990 7 doi 10 1038 nsb1101 990 PMID 11685248 S2CID 4665648 Yang JJ Gawthrop A Ye Y August 2003 Obtaining site specific calcium binding affinities of calmodulin Protein and Peptide Letters 10 4 331 45 doi 10 2174 0929866033478852 PMID 14529487 a b Linse S Helmersson A Forsen S May 1991 Calcium binding to calmodulin and its globular domains The Journal of Biological Chemistry 266 13 8050 4 doi 10 1016 S0021 9258 18 92938 8 PMID 1902469 Houdusse A Love ML Dominguez R Grabarek Z Cohen C December 1997 Structures of four Ca2 bound troponin C at 2 0 A resolution further insights into the Ca2 switch in the calmodulin superfamily Structure 5 12 1695 711 doi 10 1016 s0969 2126 97 00315 8 PMID 9438870 Yamniuk AP Vogel HJ May 2004 Calmodulin s flexibility allows for promiscuity in its interactions with target proteins and peptides Molecular Biotechnology 27 1 33 57 doi 10 1385 MB 27 1 33 PMID 15122046 S2CID 26585744 a b c d Tidow H Nissen P November 2013 Structural diversity of calmodulin binding to its target sites The FEBS Journal 280 21 5551 65 doi 10 1111 febs 12296 PMID 23601118 Frederick KK Marlow MS Valentine KG Wand AJ July 2007 Conformational entropy in molecular recognition by proteins Nature 448 7151 325 9 Bibcode 2007Natur 448 325F doi 10 1038 nature05959 PMC 4156320 PMID 17637663 Gsponer J Christodoulou J Cavalli A Bui JM Richter B Dobson CM Vendruscolo M May 2008 A coupled equilibrium shift mechanism in calmodulin mediated signal transduction Structure 16 5 736 46 doi 10 1016 j str 2008 02 017 PMC 2428103 PMID 18462678 Ishida H Vogel HJ 2006 Protein peptide interaction studies demonstrate the versatility of calmodulin target protein binding Protein and Peptide Letters 13 5 455 65 doi 10 2174 092986606776819600 PMID 16800798 a b Calmodulin Target Database Retrieved 27 July 2020 Wang Q Zhang P Hoffman L Tripathi S Homouz D Liu Y et al December 2013 Protein recognition and selection through conformational and mutually induced fit Proceedings of the National Academy of Sciences of the United States of America 110 51 20545 50 Bibcode 2013PNAS 11020545W doi 10 1073 pnas 1312788110 PMC 3870683 PMID 24297894 Johnson JD Snyder C Walsh M Flynn M January 1996 Effects of myosin light chain kinase and peptides on Ca2 exchange with the N and C terminal Ca2 binding sites of calmodulin The Journal of Biological Chemistry 271 2 761 7 doi 10 1074 jbc 271 2 761 PMID 8557684 S2CID 9746955 Bayley PM Findlay WA Martin SR July 1996 Target recognition by calmodulin dissecting the kinetics and affinity of interaction using short peptide sequences Protein Science 5 7 1215 28 doi 10 1002 pro 5560050701 PMC 2143466 PMID 8819155 Theoharis NT Sorensen BR Theisen Toupal J Shea MA January 2008 The neuronal voltage dependent sodium channel type II IQ motif lowers the calcium affinity of the C domain of calmodulin Biochemistry 47 1 112 23 doi 10 1021 bi7013129 PMID 18067319 Stefan MI Edelstein SJ Le Novere N August 2008 An allosteric model of calmodulin explains differential activation of PP2B and CaMKII Proceedings of the National Academy of Sciences of the United States of America 105 31 10768 73 Bibcode 2008PNAS 10510768S doi 10 1073 pnas 0804672105 PMC 2504824 PMID 18669651 Zhang M Abrams C Wang L Gizzi A He L Lin R et al May 2012 Structural basis for calmodulin as a dynamic calcium sensor Structure 20 5 911 23 doi 10 1016 j str 2012 03 019 PMC 3372094 PMID 22579256 Grabarek Z May 2011 Insights into modulation of calcium signaling by magnesium in calmodulin troponin C and related EF hand proteins Biochimica et Biophysica Acta BBA Molecular Cell Research 1813 5 913 21 doi 10 1016 j bbamcr 2011 01 017 PMC 3078997 PMID 21262274 a b Brittain HG Richardson FS Martin RB December 1976 Terbium III emission as a probe of calcium II binding sites in proteins Journal of the American Chemical Society 98 25 8255 60 doi 10 1021 ja00441a060 PMID 993525 Kilhoffer MC Demaille JG Gerard D July 1980 Terbium as luminescent probe of calmodulin calcium binding sites domains I and II contain the high affinity sites FEBS Letters 116 2 269 72 doi 10 1016 0014 5793 80 80660 0 PMID 7409149 Edington SC Gonzalez A Middendorf TR Halling DB Aldrich RW Baiz CR April 2018 Coordination to lanthanide ions distorts binding site conformation in calmodulin Proceedings of the National Academy of Sciences of the United States of America 115 14 E3126 E3134 Bibcode 2018PNAS 115E3126E doi 10 1073 pnas 1722042115 PMC 5889669 PMID 29545272 Chao SH Suzuki Y Zysk JR Cheung WY July 1984 Activation of calmodulin by various metal cations as a function of ionic radius Molecular Pharmacology 26 1 75 82 PMID 6087119 Horrocks Jr WD Sudnick DR 1981 12 01 Lanthanide ion luminescence probes of the structure of biological macromolecules Accounts of Chemical Research 14 12 384 392 doi 10 1021 ar00072a004 ISSN 0001 4842 Mulqueen P Tingey JM Horrocks WD November 1985 Characterization of lanthanide III ion binding to calmodulin using luminescence spectroscopy Biochemistry 24 23 6639 45 doi 10 1021 bi00344a051 PMID 4084548 Home Page for Calmodulin structbio vanderbilt edu Retrieved 2016 02 23 a b McDowall J Calmodulin InterPro Protein Archive Retrieved 23 February 2016 a b Tansey MG Luby Phelps K Kamm KE Stull JT April 1994 Ca 2 dependent phosphorylation of myosin light chain kinase decreases the Ca2 sensitivity of light chain phosphorylation within smooth muscle cells The Journal of Biological Chemistry 269 13 9912 20 doi 10 1016 S0021 9258 17 36969 7 PMID 8144585 Walsh MP June 1994 Calmodulin and the regulation of smooth muscle contraction Molecular and Cellular Biochemistry 135 1 21 41 doi 10 1007 bf00925958 PMID 7816054 S2CID 2304136 Martinsen A Dessy C Morel N 2014 10 31 Regulation of calcium channels in smooth muscle new insights into the role of myosin light chain kinase Channels 8 5 402 13 doi 10 4161 19336950 2014 950537 PMC 4594426 PMID 25483583 a b Nishizawa Y Okui Y Inaba M Okuno S Yukioka K Miki T et al October 1988 Calcium calmodulin mediated action of calcitonin on lipid metabolism in rats The Journal of Clinical Investigation 82 4 1165 72 doi 10 1172 jci113713 PMC 442666 PMID 2844851 a b Lledo PM Hjelmstad GO Mukherji S Soderling TR Malenka RC Nicoll RA November 1995 Calcium calmodulin dependent kinase II and long term potentiation enhance synaptic transmission by the same mechanism Proceedings of the National Academy of Sciences of the United States of America 92 24 11175 9 Bibcode 1995PNAS 9211175L doi 10 1073 pnas 92 24 11175 PMC 40594 PMID 7479960 Ranty B Aldon D Galaud JP May 2006 Plant calmodulins and calmodulin related proteins multifaceted relays to decode calcium signals Plant Signaling amp Behavior 1 3 96 104 doi 10 4161 psb 1 3 2998 PMC 2635005 PMID 19521489 Virdi Amardeep S Singh Supreet Singh Prabhjeet 2015 Abiotic stress responses in plants roles of calmodulin regulated proteins Frontiers in Plant Science 6 809 doi 10 3389 fpls 2015 00809 ISSN 1664 462X PMC 4604306 PMID 26528296 Chiasson D Ekengren SK Martin GB Dobney SL Snedden WA August 2005 Calmodulin like proteins from Arabidopsis and tomato are involved in host defense against Pseudomonas syringae pv tomato Plant Molecular Biology 58 6 887 897 doi 10 1007 s11103 005 8395 x PMID 16240180 S2CID 1572549 Leba LJ Cheval C Ortiz Martin I Ranty B Beuzon CR Galaud JP Aldon D September 2012 CML9 an Arabidopsis calmodulin like protein contributes to plant innate immunity through a flagellin dependent signalling pathway The Plant Journal 71 6 976 89 doi 10 1111 j 1365 313x 2012 05045 x PMID 22563930 a b Sanchez AC Subudhi PK Rosenow DT Nguyen HT 2002 Mapping QTLs associated with drought resistance in sorghum Sorghum bicolor L Moench Plant Molecular Biology 48 5 6 713 26 doi 10 1023 a 1014894130270 PMID 11999845 S2CID 25834614 Singh S Virdi AS Jaswal R Chawla M Kapoor S Mohapatra SB et al June 2017 A temperature responsive gene in sorghum encodes a glycine rich protein that interacts with calmodulin Biochimie 137 Supplement C 115 123 doi 10 1016 j biochi 2017 03 010 PMID 28322928 External links edit Myelin associated Glycoprotein Molecule of the Month RCSB PDB July 2020 Archived from the original on 2010 05 29 Retrieved 2021 06 19 Nelson M Chazin W Home Page for Calmodulin EF Hand Calcium Binding Proteins Data Library Vanderbilt University Retrieved 2008 03 22 Ikura M 2000 Calmodulin Target Database Journal of Structural and Functional Genomics Ontario Cancer Institute University of Toronto 1 1 8 14 doi 10 1023 a 1011320027914 PMID 12836676 S2CID 23097597 Retrieved 2008 03 22 Calmodulin at the U S National Library of Medicine Medical Subject Headings MeSH InterPro IPR015754 Proteopedia page for Calmodulin and its conformational change Retrieved from https en wikipedia org w index php title Calmodulin amp oldid 1189456384, wikipedia, wiki, book, books, library,

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