Molecular mechanism of activation-triggered subunit exchange in Ca2+/calmodulin-dependent protein kinase II

Autor: Howard Schulman, Christine L. Gee, Ethan D McSpadden, Nishant Pappireddi, Tiago Barros, Catherine C. Going, Yumeng Melody Cao, Anna Elleman, John Kuriyan, Margaret M. Stratton, Moitrayee Bhattacharyya, Pawel Burkhardt, Anna C. Susa, Evan R. Williams, Yongjian Huang
Jazyk: angličtina
Rok vydání: 2016
Předmět:
0301 basic medicine
Models
Molecular
Calmodulin
QH301-705.5
Science
Protein subunit
Molecular Conformation
Bioinformatics
environment and public health
Biochemistry
kinase activation
Models
Biological
General Biochemistry
Genetics and Molecular Biology
03 medical and health sciences
Holoenzymes
Ca2+/calmodulin-dependent protein kinase
Transferase
Humans
Biology (General)
Ca2+/CaM stimulus
General Immunology and Microbiology
biology
Chemistry
N. vectensis
musculoskeletal
neural
and ocular physiology
General Neuroscience
E. coli
S. rosetta
General Medicine
Biophysics and Structural Biology
3. Good health
enzymes and coenzymes (carbohydrates)
Protein Subunits
030104 developmental biology
Protein kinase domain
Structural biology
structural transition
subunit exchange
biology.protein
Biophysics
cardiovascular system
Medicine
Phosphorylation
Protein Multimerization
Calcium-Calmodulin-Dependent Protein Kinase Type 2
Research Article
Zdroj: eLife
eLife, Vol 5 (2016)
ISSN: 2050-084X
Popis: Activation triggers the exchange of subunits in Ca2+/calmodulin-dependent protein kinase II (CaMKII), an oligomeric enzyme that is critical for learning, memory, and cardiac function. The mechanism by which subunit exchange occurs remains elusive. We show that the human CaMKII holoenzyme exists in dodecameric and tetradecameric forms, and that the calmodulin (CaM)-binding element of CaMKII can bind to the hub of the holoenzyme and destabilize it to release dimers. The structures of CaMKII from two distantly diverged organisms suggest that the CaM-binding element of activated CaMKII acts as a wedge by docking at intersubunit interfaces in the hub. This converts the hub into a spiral form that can release or gain CaMKII dimers. Our data reveal a three-way competition for the CaM-binding element, whereby phosphorylation biases it towards the hub interface, away from the kinase domain and calmodulin, thus unlocking the ability of activated CaMKII holoenzymes to exchange dimers with unactivated ones. DOI: http://dx.doi.org/10.7554/eLife.13405.001
eLife digest How does memory outlast the lifetime of the molecules that encode it? One enzyme that is found in neurons and has been suggested to help long-term memories to form is called CaMKII. Each CaMKII assembly is typically composed of 12 to 14 protein subunits associated in a ring and can exist in either an “unactivated” or “activated” state. In 2014, researchers showed that CaMKII assemblies can exchange subunits with each other. Importantly, an active CaMKII can mix with an unactivated CaMKII and share its activation state. CaMKII may use this mechanism to spread information to the next generation of proteins – thereby allowing activation to outlast the lifespan of the initially activated proteins. However the molecular mechanism that underlies this process was not clear. Now, Bhattacharyya et al. – including some of the researchers involved in the 2014 work – address two questions about this mechanism. How do subunits exchange between CaMKII assemblies? And how does the activation of CaMKII initiate subunit exchange? A closed-ring hub ties the subunits of CaMKII together, similar to the organization of the segments in an orange. To undergo subunit exchange, the hub must open up to release and accept subunits. Bhattacharyya et al. have now uncovered an intrinsic flexibility in the hub that is triggered by a short peptide segment in CaMKII. This segment, which is exposed in activated CaMKII but not in the unactivated form, can crack open the hub ring by binding between the hub subunits, like a finger separating the segments of an orange. This allows the hub to flex and expand, and once open, the hub’s flexibility allows room for subunits to be released or accepted. Although this subunit exchange mechanism could be a powerful means for spreading the activated state throughout signaling pathways, the biological relevance of this phenomenon has not been clarified. However, the mechanistic framework provided by Bhattacharyya et al. may allow new experiments to be performed that test the consequences of subunit exchange in live cells and organisms. It could also enable investigations into the importance of subunit exchange in long-term memory. DOI: http://dx.doi.org/10.7554/eLife.13405.002
Databáze: OpenAIRE
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