Energy landscapes of a mechanical prion and their implications for the molecular mechanism of long-term memory

Significance The physical basis for the long timescale of memory has been mysterious. The formation of a functional prion-like fiber in the neuronal system may resolve the question. This work shows that the energy landscapes of a candidate prion, cytoplasmic polyadenylation element binding (CPEB) protein, allow external mechanical forces to facilitate the structural transition to a fiber form. The mechanical coupling thus allows a positive feedback loop between CPEB prion transitions and cytoskeletal actions to mark synapses. Aplysia cytoplasmic polyadenylation element binding (CPEB) protein, a translational regulator that recruits mRNAs and facilitates translation, has been shown to be a key component in the formation of long-term memory. Experimental data show that CPEB exists in at least a low-molecular weight coiled-coil oligomeric form and an amyloid fiber form involving the Q-rich domain (CPEB-Q). Using a coarse-grained energy landscape model, we predict the structures of the low-molecular weight oligomeric form and the dynamics of their transitions to the β-form. Up to the decamer, the oligomeric structures are predicted to be coiled coils. Free energy profiles confirm that the coiled coil is the most stable form for dimers and trimers. The structural transition from α to β is shown to be concentration dependent, with the transition barrier decreasing with increased concentration. We observe that a mechanical pulling force can facilitate the α-helix to β-sheet (α-to-β) transition by lowering the free energy barrier between the two forms. Interactome analysis of the CPEB protein suggests that its interactions with the cytoskeleton could provide the necessary mechanical force. We propose that, by exerting mechanical forces on CPEB oligomers, an active cytoskeleton can facilitate fiber formation. This mechanical catalysis makes possible a positive feedback loop that would help localize the formation of CPEB fibers to active synapse areas and mark those synapses for forming a long-term memory after the prion form is established. The functional role of the CPEB helical oligomers in this mechanism carries with it implications for targeting such species in neurodegenerative diseases.

[1]  Eric R Kandel,et al.  The molecular biology of memory: cAMP, PKA, CRE, CREB-1, CREB-2, and CPEB , 2012, Molecular Brain.

[2]  Eric R. Kandel,et al.  Aplysia CPEB Can Form Prion-like Multimers in Sensory Neurons that Contribute to Long-Term Facilitation , 2010, Cell.

[3]  J. H. Schwartz,et al.  The cytoplasmic polyadenylation element binding protein and polyadenylation of messenger RNA in Aplysia neurons , 2003, Brain Research.

[4]  E. Kandel,et al.  Characterization of prion-like conformational changes of the neuronal isoform of Aplysia CPEB , 2013, Nature Structural &Molecular Biology.

[5]  Olga Kononova,et al.  Mechanical transition from α-helical coiled coils to β-sheets in fibrin(ogen). , 2012, Journal of the American Chemical Society.

[6]  K. Pagel,et al.  Random Coils, β-Sheet Ribbons, and α-Helical Fibers: One Peptide Adopting Three Different Secondary Structures at Will , 2006 .

[7]  J. Hofrichter,et al.  Sickle cell hemoglobin polymerization. , 1990, Advances in protein chemistry.

[8]  S. Prusiner Novel proteinaceous infectious particles cause scrapie. , 1982, Science.

[9]  Sathyanarayanan V. Puthanveettil,et al.  Sustained CPEB-Dependent Local Protein Synthesis Is Required to Stabilize Synaptic Growth for Persistence of Long-Term Facilitation in Aplysia , 2008, Neuron.

[10]  Peter G. Wolynes,et al.  Frustration in the energy landscapes of multidomain protein misfolding , 2013, Proceedings of the National Academy of Sciences.

[11]  Luana Fioriti,et al.  The CPEB3 Protein Is a Functional Prion that Interacts with the Actin Cytoskeleton. , 2015, Cell reports.

[12]  Christoph Böttcher,et al.  Intramolecular charge interactions as a tool to control the coiled-coil-to-amyloid transformation. , 2008, Chemistry.

[13]  J. Griffith,et al.  Self-replication and scrapie. , 1967, Nature.

[14]  S. Auer,et al.  Communication: Conformation state diagram of polypeptides: a chain length induced α-β transition. , 2011, The Journal of chemical physics.

[15]  K. Kar,et al.  Critical nucleus size for disease-related polyglutamine aggregation is repeat length dependent , 2010, Nature Structural &Molecular Biology.

[16]  Nicholas P. Schafer,et al.  Predictive energy landscapes for protein–protein association , 2012, Proceedings of the National Academy of Sciences.

[17]  M. Buehler,et al.  Molecular dynamics simulation of the α-helix to β-sheet transition in coiled protein filaments: evidence for a critical filament length scale. , 2010, Physical review letters.

[18]  F. Crick Neurobiology: Memory and molecular turnover , 1984, Nature.

[19]  Peter G Wolynes,et al.  Frustration in biomolecules , 2013, Quarterly Reviews of Biophysics.

[20]  Nicholas P. Schafer,et al.  AWSEM-MD: protein structure prediction using coarse-grained physical potentials and bioinformatically based local structure biasing. , 2012, Journal of Physical Chemistry B.

[21]  TIKVAH ALPER,et al.  Does the Agent of Scrapie Replicate without Nucleic Acid ? , 1967, Nature.

[22]  C. Dobson,et al.  The amyloid state and its association with protein misfolding diseases , 2014, Nature Reviews Molecular Cell Biology.

[23]  Markus J. Buehler,et al.  Hierarchical Structure Controls Nanomechanical Properties of Vimentin Intermediate Filaments , 2009, PloS one.

[24]  E. Kandel,et al.  A Neuronal Isoform of the Aplysia CPEB Has Prion-Like Properties , 2003, Cell.

[25]  P. Tompa,et al.  Prion proteins as memory molecules: an hypothesis. , 1998, Neuroscience.

[26]  Peter G Wolynes,et al.  Free energy landscapes for initiation and branching of protein aggregation , 2013, Proceedings of the National Academy of Sciences.

[27]  Eric R. Kandel,et al.  A Neuronal Isoform of CPEB Regulates Local Protein Synthesis and Stabilizes Synapse-Specific Long-Term Facilitation in Aplysia , 2003, Cell.

[28]  David Eisenberg,et al.  Atomic View of a Toxic Amyloid Small Oligomer , 2012, Science.

[29]  F. Crick Memory and molecular turnover. , 1984, Nature.

[30]  E. Kandel,et al.  The Molecular and Systems Biology of Memory , 2014, Cell.

[31]  S. Lindquist,et al.  Protein-only mechanism induces self-perpetuating changes in the activity of neuronal Aplysia cytoplasmic polyadenylation element binding protein (CPEB) , 2011, Proceedings of the National Academy of Sciences.

[32]  J. Griffith,et al.  Nature of the Scrapie Agent: Self-replication and Scrapie , 1967, Nature.

[33]  E. Kandel,et al.  Essential Role of Coiled Coils for Aggregation and Activity of Q/N-Rich Prions and PolyQ Proteins , 2010, Cell.