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Oscillations in neuronal activity: a neuron-centered spatiotemporal model of the Unfolded Protein Response in prion diseases (2405.16695v1)

Published 26 May 2024 in q-bio.NC and math.DS

Abstract: Many neurodegenerative diseases (NDs) are characterized by the slow spatial spread of toxic protein species in the brain. The toxic proteins can induce neuronal stress, triggering the Unfolded Protein Response (UPR), which slows or stops protein translation and can indirectly reduce the toxic load. However, the UPR may also trigger processes leading to apoptotic cell death and the UPR is implicated in the progression of several NDs. In this paper, we develop a novel mathematical model to describe the spatiotemporal dynamics of the UPR mechanism for prion diseases. Our model is centered around a single neuron, with representative proteins P (healthy) and S (toxic) interacting with heterodimer dynamics (S interacts with P to form two S's). The model takes the form of a coupled system of nonlinear reaction-diffusion equations with a delayed, nonlinear flux for P (delay from the UPR). Through the delay, we find parameter regimes that exhibit oscillations in the P- and S-protein levels. We find that oscillations are more pronounced when the S-clearance rate and S-diffusivity are small in comparison to the P-clearance rate and P-diffusivity, respectively. The oscillations become more pronounced as delays in initiating the UPR increase. We also consider quasi-realistic clinical parameters to understand how possible drug therapies can alter the course of a prion disease. We find that decreasing the production of P, decreasing the recruitment rate, increasing the diffusivity of S, increasing the UPR S-threshold, and increasing the S clearance rate appear to be the most powerful modifications to reduce the mean UPR intensity and potentially moderate the disease progression.

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References (48)
  1. Goedert M, Spillantini MG. A century of Alzheimer’s disease. science. 2006;314(5800):777-81.
  2. Davie CA. A review of Parkinson’s disease. British medical bulletin. 2008;86(1):109-27.
  3. Neurodegenerative diseases and effective drug delivery: A review of challenges and novel therapeutics. Journal of Controlled Release. 2021;330:1152-67.
  4. Kiaei M. New hopes and challenges for treatment of neurodegenerative disorders: Great opportunities for young neuroscientists. Basic and Clinical Neuroscience. 2013;4(1):3.
  5. Newby GA, Lindquist S. Blessings in disguise: biological benefits of prion-like mechanisms. Trends in cell biology. 2013;23(6):251-9.
  6. Structure–neurotoxicity relationships of amyloid β𝛽\betaitalic_β-protein oligomers. Proceedings of the National Academy of Sciences. 2009;106(35):14745-50.
  7. The path forward in Alzheimer’s disease therapeutics: Reevaluating the amyloid cascade hypothesis. Alzheimer’s & Dementia. 2020;16(11):1553-60.
  8. Stefanis L. α𝛼\alphaitalic_α-Synuclein in Parkinson’s disease. Cold Spring Harbor perspectives in medicine. 2012;2(2):a009399.
  9. Prusiner S. Creutzfeldt-Jakob disease and scrapie prions. Alzheimer Disease & Associated Disorders. 1989;3(1):52-78.
  10. Mechanisms, regulation and functions of the unfolded protein response. Nature reviews Molecular cell biology. 2020;21(8):421-38.
  11. Halliday M, Mallucci GR. Targeting the unfolded protein response in neurodegeneration: a new approach to therapy. Neuropharmacology. 2014;76:169-74.
  12. Neuronal cell death. Physiological reviews. 2018;98(2):813-80.
  13. Cellular tolerance of prion protein PrP in yeast involves proteolysis and the unfolded protein response. Biochemical and biophysical research communications. 2006;347(1):319-26.
  14. Hao W, Friedman A. Mathematical model on Alzheimer’s disease. BMC systems biology. 2016;10(1):1-18.
  15. Puri IK, Li L. Mathematical modeling for the pathogenesis of Alzheimer’s disease. PloS one. 2010;5(12):e15176.
  16. From reaction kinetics to dementia: A simple dimer model of Alzheimer’s disease etiology. PLoS computational biology. 2021;17(7):e1009114.
  17. Inclusion formation and neuronal cell death through neuron-to-neuron transmission of α𝛼\alphaitalic_α-synuclein. Proceedings of the National Academy of Sciences. 2009;106(31):13010-5.
  18. Mathematical biology models of Parkinson’s disease. CPT: pharmacometrics & systems pharmacology. 2019;8(2):77-86.
  19. Predictive model of spread of Parkinson’s pathology using network diffusion. NeuroImage. 2019;192:178-94.
  20. A mathematical analysis of the dynamics of prion proliferation. Journal of theoretical biology. 2006;242(3):598-606.
  21. Salman S, Ahmed E. A mathematical model for Creutzfeldt Jacob Disease (CJD). Chaos, Solitons & Fractals. 2018;116:249-60.
  22. Neuron Scale Modeling of Prion Production with the Unfolded Protein Response. SIAM Journal on Applied Dynamical Systems. 2022;21(4):2487-517.
  23. A multigroup approach to delayed prion production. Discrete and Continuous Dynamical Systems - Series B. 2024;29.
  24. Trusina A, Tang C. The unfolded protein response and translation attenuation: a modelling approach. Diabetes, Obesity and Metabolism. 2010;12:27-31.
  25. Neuronal oscillations on evolving networks: dynamics, damage, degradation, decline, dementia, and death. Physical review letters. 2020;125(12):128102.
  26. Dynamics of prion proliferation under combined treatment of pharmacological chaperones and interferons. Journal of Theoretical Biology. 2021;527:110797.
  27. Prion protein scrapie and the normal cellular prion protein. Prion. 2016;10(1):63-82.
  28. Selkoe DJ. Folding proteins in fatal ways. nature. 2003;426(6968):900-4.
  29. The prion protein and its ligands: Insights into structure-function relationships. Biochimica et Biophysica Acta (BBA)-Molecular Cell Research. 2022;1869(6):119240.
  30. Non-amyloid and amyloid prion protein deposits in prion-infected mice differ in blockage of interstitial brain fluid. Neuropathology and applied neurobiology. 2013;39(3):217-30.
  31. Sustained translational repression by eIF2α𝛼\alphaitalic_α-P mediates prion neurodegeneration. Nature. 2012;485(7399):507-11.
  32. Di Domenico F, Lanzillotta C. Chapter Two - The disturbance of protein synthesis/degradation homeostasis is a common trait of age-related neurodegenerative disorders. Advances in Protein Chemistry and Structural Biology. 2022;132:49-87.
  33. Martin JB. Applications of molecular genetics to restorative neurology. In: Principles and Practice of Restorative Neurology. Elsevier; 1992. p. 189-201.
  34. Extracellular fluid viscosity enhances cell migration and cancer dissemination. Nature. 2022;611(7935):365-73.
  35. Estimation of diffusion coefficients of proteins. Biotechnology and bioengineering. 1980;22(5):947-55.
  36. A model of effective diffusion and tortuosity in the extracellular space of the brain. Biophysical journal. 2004;87(3):1606-17.
  37. Quantifying the kinetic parameters of prion replication. Biophysical chemistry. 1999;77(2-3):139-52.
  38. Sequential appearance and accumulation of pathognomonic markers in the central nervous system of hamsters orally infected with scrapie. Journal of General Virology. 1996;77(8):1925-34.
  39. The density of tissues in and about the head. Acta neurologica scandinavica. 1970;46(1):85-92.
  40. Matthäus F. Diffusion versus network models as descriptions for the spread of prion diseases in the brain. Journal of theoretical biology. 2006;240(1):104-13.
  41. Peña J, Harris E. Dengue virus modulates the unfolded protein response in a time-dependent manner. Journal of Biological Chemistry. 2011;286(16):14226-36.
  42. Braitenberg V. Brain size and number of neurons: an exercise in synthetic neuroanatomy. Journal of computational neuroscience. 2001;10:71-7.
  43. Raine C. Characteristics of the Neuron; 1999. https://www.ncbi.nlm.nih.gov/books/NBK28209/.
  44. Dendrites. Oxford University Press; 2016.
  45. Experimental treatments for human transmissible spongiform encephalopathies: is there a role for pentosan polysulfate? Expert opinion on biological therapy. 2007;7(5):713-26.
  46. Wade J. Belfast man suffering from variant CJD passes away. The Journal. 2011. Available from: https://www.thejournal.ie/belfast-man-suffering-from-variant-cjd-passes-away-100653-Mar2011/.
  47. Comparison of the anti-prion mechanism of four different anti-prion compounds, anti-PrP monoclonal antibody 44B1, pentosan polysulfate, chlorpromazine, and U18666A, in prion-infected mouse neuroblastoma cells. PLoS One. 2014;9(9):e106516.
  48. Douglas Jr J. A survey of numerical methods for parabolic differential equations. In: Advances in computers. vol. 2. Elsevier; 1961. p. 1-54.
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