Calmodulin-binding proteins

Calmodulin-binding proteins are, as their name implies, proteins which bind calmodulin. Calmodulin can bind to a variety of proteins through a two-step binding mechanism, namely "conformational and mutually induced fit",^[1] where typically two domains of calmodulin wrap around an emerging helical calmodulin binding domain from the target protein.

Examples include:

Gap-43 protein (presynaptic)
Neurogranin (postsynaptic)
Caldesmon

Ca²⁺ Activation

A variety of different ions, including Calcium (Ca²⁺), play a vital role in the regulation of cellular functions. Calmodulin, a Calcium-binding protein, that mediates Ca²⁺ signaling is involved in all types of cellular mechanisms, including metabolism, synaptic plasticity, nerve growth, smooth muscle contraction, etc. Calmodulin allows for a number of proteins to aid in the progression of these pathways using their interactions with CaM in its Ca²⁺-free or Ca²⁺-bound state. Proteins each have their own unique affinities for calmodulin, that can be manipulated by Ca²⁺ concentrations to allow for the desired release or binding to calmodulin that determines its ability to carry out its cellular function. Proteins that get activated upon binding to Ca²⁺-bound state, include Myosin light-chain kinase, Phosphatase, Ca²⁺/calmodulin-dependent protein kinase II, etc. Proteins, such as neurogranin that plays a vital role in postsynaptic function, however, can bind to calmodulin in Ca²⁺-free or Ca²⁺-bound state via their IQ calmodulin-binding motifs.^[2] Since these interactions are exceptionally specific, they can be regulated through post-translational modifications by enzymes like kinases and phosphatases to affect their cellular functions. In the case of neurogranin, it's the synaptic function can be inhibited by the PKC-mediated phosphorylation of its IQ calmodulin-binding motif that impedes its interaction with calmodulin.^[3]

Cellular functions can be indirectly regulated by calmodulin, as it acts as a mediator for enzymes that require Ca²⁺ stimulation for activation. Studies have proven that calmodulin's affinity for Ca²⁺ increases when it is bound to a calmodulin-binding protein, which allows for it to take on its regulatory role for Ca²⁺-dependent reactions. Calmodulin, made up of two pairs of EF-hand motifs separated in different structural regions by an extended alpha helical region, that permits it to respond to the changes in the cytosolic concentration of the Ca²⁺ ions by taking on two distinct conformations, in the inactive Ca²⁺ unbound state and active Ca²⁺ bound state. Calmodulin binds to the targeted proteins via their short complementary peptide sequences, causing an “induced fit” conformational change that alters the calmodulin-binding proteins’ activity as desired in response to the second messenger Ca²⁺ signals that arise due to changes in the intracellular Ca²⁺ concentrations. These second messenger Ca²⁺ signals are transduced and integrated to maintain a homeostatic balance of the Ca²⁺ ions.^[4]

GAP-43 Protein

Found in the nervous system, GAP-43 is a growth-associated protein (GAP) expressed in high levels during presynaptic developmental and regenerative axonal growth. As a major growth cone component, an increase in GAP-43 concentrations delays the process of axonal growth cones evolving into stable synaptic terminals. All GAP-43 proteins share a completely conserved amino acid sequence that contain a calmodulin-binding domain and a serine residue that can be used to inhibit calmodulin binding upon phosphorylation of Protein kinase C (PKC). By possessing these calmodulin-binding properties, GAP-43 is able to respond to PKC activation and release free calmodulin in desired areas. When there are low levels of Ca²⁺ concentrations, GAP-43 is able to bind and stabilize the inactive Ca²⁺-free state of calmodulin, this allows it to absorb and reversibly inactivate the CaM in the growth cones. This binding of the calmodulin to GAP-43 is allowed by the electrostatic interaction between the negatively-charged calmodulin and the positively-charged “pocket” formed in the GAP-43 molecule.^[5]

References

^ Wang Q, Zhang P, Hoffman L, Tripathi S, Homouz D, Liu Y, Waxham MN, Cheung MS (December 2013). "Protein recognition and selection through conformational and mutually induced fit". Proc Natl Acad Sci U S A. 110 (51): 20545–50. Bibcode:2013PNAS..11020545W. doi:10.1073/pnas.1312788110. PMC 3870683. PMID 24297894.
^ Hoffman L, Chandrasekar A, Wang X, Putkey JA, Waxham MN (2014-05-23). "Neurogranin alters the structure and calcium binding properties of calmodulin". J Biol Chem. 289 (21): 14644–55. doi:10.1074/jbc.M114.560656. PMC 4031520. PMID 24713697.
^ Kaleka, Kanwardeep S.; Petersen, Amber N.; Florence, Matthew A.; Gerges, Nashaat Z. (2012-01-23). "Pull-down of Calmodulin-binding Proteins". Journal of Visualized Experiments (59): 3502. doi:10.3791/3502. ISSN 1940-087X. PMC 3462570. PMID 22297704.
^ Zielinski, Raymond E. (1998). "Calmodulin and Calmodulin-Binding Proteins in Plants". Annual Review of Plant Physiology and Plant Molecular Biology. 49 (1): 697–725. doi:10.1146/annurev.arplant.49.1.697. ISSN 1040-2519. PMID 15012251.
^ Skene, J.H.Pate (1990). "GAP-43 as a 'calmodulin sponge' and some implications for calcium signalling in axon terminals". Neuroscience Research Supplements. 13: S112–S125. doi:10.1016/0921-8696(90)90040-a. ISSN 0921-8696. PMID 1979675.

External links

Calmodulin-Binding+Proteins at the U.S. National Library of Medicine Medical Subject Headings (MeSH)

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[1] Wang Q, Zhang P, Hoffman L, Tripathi S, Homouz D, Liu Y, Waxham MN, Cheung MS (December 2013). "Protein recognition and selection through conformational and mutually induced fit". Proc Natl Acad Sci U S A. 110 (51): 20545–50. Bibcode:2013PNAS..11020545W. doi:10.1073/pnas.1312788110. PMC 3870683. PMID 24297894.

[2] Hoffman L, Chandrasekar A, Wang X, Putkey JA, Waxham MN (2014-05-23). "Neurogranin alters the structure and calcium binding properties of calmodulin". J Biol Chem. 289 (21): 14644–55. doi:10.1074/jbc.M114.560656. PMC 4031520. PMID 24713697.

[3] Kaleka, Kanwardeep S.; Petersen, Amber N.; Florence, Matthew A.; Gerges, Nashaat Z. (2012-01-23). "Pull-down of Calmodulin-binding Proteins". Journal of Visualized Experiments (59): 3502. doi:10.3791/3502. ISSN 1940-087X. PMC 3462570. PMID 22297704.

[4] Zielinski, Raymond E. (1998). "Calmodulin and Calmodulin-Binding Proteins in Plants". Annual Review of Plant Physiology and Plant Molecular Biology. 49 (1): 697–725. doi:10.1146/annurev.arplant.49.1.697. ISSN 1040-2519. PMID 15012251.

[5] Skene, J.H.Pate (1990). "GAP-43 as a 'calmodulin sponge' and some implications for calcium signalling in axon terminals". Neuroscience Research Supplements. 13: S112–S125. doi:10.1016/0921-8696(90)90040-a. ISSN 0921-8696. PMID 1979675.

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v t e Proteins: carrier proteins
Fatty acid	FABP1 FABP2 FABP3 FABP4 FABP5 FABP6 FABP7
Hormone	peptide hormone: Follistatin Growth hormone binding protein Insulin-like growth factor binding protein IGFBP1 IGFBP2 IGFBP3 IGFBP4 IGFBP5 IGFBP6 IGFBP7 Neurophysins Neurophysin I II steroid hormone: Sex hormone binding globulin/Androgen binding protein Transcortin Thyroxine-binding globulin Transthyretin
Metal/element	calcium Calcium-binding protein Calmodulin-binding proteins copper Ceruloplasmin iron Iron-binding proteins Transferrin receptor
Vitamin	Retinol binding protein 1 2 3 4 Transcobalamin
Pigment	Plant Light-Harvesting Complex Orange Carotenoid Protein Phycobiliprotein Photosynthetic Reaction Centers Phytochrome Rhodopsin
Other	Acyl carrier protein Adaptor protein Cholesterylester transfer protein F-box protein GTP-binding protein Latent TGF-beta binding protein Major urinary proteins Membrane transport protein Odorant binding protein

Calmodulin-binding proteins

Ca2+ Activation

GAP-43 Protein

References

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Ca²⁺ Activation