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 "conformational and mutually induced fit", 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 (CaM), 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+ bound conformation (Ca2+ -CaM) or as its Ca2+ -free state (ApoCaM). Proteins each have their own unique affinities for CaM, that can be manipulated by the presence or absence of Ca2+ concentrations to allow for the desired release or binding to CaM that determines its ability to carry out its cellular function. Proteins that get activated upon binding to Ca2+ -CaM, include Myosin light-chain kinase, Phosphatase, Ca2+/calmodulin-dependent protein kinase II(CaMKs), etc. Proteins, like neurogranin (Ng) that plays a vital role in postsynaptic function, however, can only bind to the CaM in ApoCaM via their IQ-domain. Since these interactions are exceptionally specific, they can be regulated through Post-translational modification by enzymes like kinases and Phosphatase to affect their cellular functions. In the case of Ng, it's the synaptic function can be inhibited by the PKC-mediated phosphorylation of its IQ-domain that impedes its interaction with CaM.[1]
Cellular functions can be indirectly regulated by CaM, 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 2 pairs of Ef-hand calcium binding domain 2 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 a “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.[2]
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 CaM 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 negatively charged CaM electrostatically interacting with the positively charged “pocket” formed in the GAP-43 molecule itself.[3]
References
- 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 US National Library of Medicine Medical Subject Headings (MeSH)