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BDNF and Parkinson’s Disease

BDNF and Parkinson’s Disease. March 26 th , 2010. What is Parkinson’s Disease?. Progressive loss of dopaminergic neurons in the substantia nigra Reduction in SN and striatal DA Increase in glial cells in the SN Neuromelanin (DA pigment) loss Lewy bodies. Diagnosis.

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BDNF and Parkinson’s Disease

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  1. BDNF and Parkinson’s Disease March 26th, 2010

  2. What is Parkinson’s Disease? • Progressive loss of dopaminergic neurons in the substantia nigra • Reduction in SN and striatal DA • Increase in glial cells in the SN • Neuromelanin (DA pigment) loss • Lewy bodies

  3. Diagnosis • Clinical features: Bradykinesia, resting tremors, muscle rigidity, loss of postural reflexes, flexed posture, and the freezing phenomenon • Parkinsonism diagnosis with 2 symptoms • Parkinsonisms: • Primary: Parkinson’s disease (PD) – most common • asymmetrical onset of motor symptoms • rest tremor • Substantial clinical response to levodopa therapy • Secondary: drug-induced or postencephalitic parkinsonism • Parkinson-plus syndromes - w/ other neurological features, i.e. progressive supranuclear palsy and multiple system atrophy • heredodegenerative disorders – parkinsonism features in a heritable degenerative disorder (juvenile Huntington or Wilson disease) Fahn and Sulzer, 2004

  4. Neurotrophin Hypothesis in Neurodegenerative (ND) disorders • Neurotrophins promote: development, heath, survival of neurons • BDNF: synaptic plasticity, neuronal survival and differentiation • Studies suggest BDNF disruption in: • Huntington’s • Alzheimer’s • Multiple Sclerosis • Parkinson’s

  5. BREIF Overview of Parkinson’s & BDNF Research… • Postmortem studies of PD patients: reduced levels of BDNF in the SCN- substantia nigra pars compacta (Mogi et al., 1999; Parain et al., 1999; Howells et al., 2000; Chauhan et al. 2001) • BDNF promotes survival & differentiation mesencephalic DA neurons in culture (Hyman et al., 1999; Feng et al., 1999) • BDNF protects from toxic insults (Murer et al., 2001) • BDNF+/- mice have decreased striatal DA and impaired behavioral responses (Dluzen et al., 2001, 2002) • trkB partial deletion – decreased TH, formation of α-synuclein deposits (von Bohlen Und Halbach et al., 2005) BDNF

  6. Normal BDNF Expression • DA neurons normally co-express BDNF in: • Substantia Nigra • Ventral Tegmental Area • Frontal cortex • DA neuron depletion  Decrease in BDNF (trophic support)?

  7. Exogenous BDNF Replacement • Goal: increase BDNF to preserve DA neurons and improve disease symptoms • Problems: • Large molecular size (~28 kDa) • trkB wide distribution – no targeted effects • Carrier molecules: stem cells, viral vectors, biomaterials • Unknown treatment length for protection, BDNF delivery rate, BDNF pharmokinetics • BDNF overexpression in animal models  seizures

  8. Experimental therapeutic strategies for restoring BDNF in ND diseases Zuccato and Cattaneo, 2009

  9. Brain-Derived Neurotrophic Factor Is Required for the Establishment of Proper Number of Dopaminergic Neurons in the Substantia Nigra Pars Compacta Baquet et al., 2005. Journal of Neuroscience. 25(26): 6251-6259.

  10. Aim of Study • Investigate the link between reduced BDNF in the substantia nigra and deterioration of dopamergic neurons in PD patients. • Create a conditional knock-out, as BDNF-/- mice die.

  11. Cre-Lox recombination Wnt-1 promoter R26R Cre (BDNFneo) LacZ

  12. Resulting Mice BDNF-/- BDNF+/+ BDNF+/- Wildtype BDNF Wnt-BDNFKO BDNFneo/lox+ Heterozygous for BDNF Wnt-1:R26R

  13. Figure 1: BDNF Expression Characterization

  14. What is TH? Kreek, et al. 2002

  15. Figure 2: Expression of Cre in midbrain BDNF-expressing neurons

  16. Figure 3: Reduced BDNF protein leads to motor deficits and reduced striatal TH in Wnt-BDNFKO KO HT WT KO HT WT

  17. Figure 4: Wnt-BDNFKO Mice have reduced TH expression in the SNC, but not the VTA Anterior Posterior KO HT WT

  18. Figure 5: No change in NeuN, CB, CR NeuN CB CR

  19. Conclusions • Selective BDNF deletion from the midbrain & hindbrain show: • reduced TH (differentiated DA neurons) • reduction in striatal DA • display early PD phenotype • More evidence for a link between BDNF and PD?

  20. Protective Effects of Neurotrophic Factor-Secreting Cells in a 6-OHDA Rat Model of Parkinson Disease Sadan et al., 2009. Stem Cells and Development. 18(8):1179-90.

  21. Aim of study • Induce MSC to differentiate into neurotrophic factor secreting astrocytes • Safe & efficient protocol • Increase NTF secretion • Study effects NTF (BDNF and GDNF) in: • behavior • dopamine levels/neurons in striatum • in vivo tracking of transplanted cells

  22. Definition of a Stem Cell 1. make identical copies of themselves for long periods of time (long-term self-renewal) 2. give rise to mature cell types that have characteristic morphologies (shapes) and specialized functions 8-cell stage

  23. Why use stem cells for ND therapy? • Replacement of degenerated cells • Improve the environment of diseased neural tissue – i.e. release neuroprotective factors • Factors already secreted by stem cells • Specific gene introduction to stem cells for secretion • Stem cells to induce/enhance neurogenesis to mimic native stem cell populations

  24. Obstacles in stem cell therapy • Immune (graft) rejection • Transplantation procedure • Risk of tumor development • Ethical issues • Matched donor • Fate assessment after therapy

  25. Types of Stem Cells • Embryonic Stem Cells (ESC) – totipotent • Ethical issues • Tumorigenic • Non-autologous source • Adult stem cells – many types, multipotent • Different properties • induced Pluripotent stem cells • Autologous source • Unlimited differentiation • Tumorigenic • Lentivirus vectors for induction – dangerous mutations • Safer method = piggyBac

  26. Bone marrow stem cells Hematopoietic stem cell Neuron Gl ia Neural

  27. Opposition to idea of MSC transdifferentiation to neuronal cells • Observations of extending neurites mistaken for cell-cell contacts • ‘neural’ makers could have different roles in MSC • Yet, recent reports suggest a subpopulation of MSC originate from the neural crest • likely that at least of subset of the MSCs may have a neural predisposition.

  28. MSC advantages • Differentiate to DA neurons, astrocytes, oligodendrocytes • Paracrine effect • Secrete soluble trophic factors (BDNF, VEGF, GDNF) • Cytokine secretion to inhibit lymphocyte proliferation • Migratory behavior • Neurogenesis – seen in stroke model and transplant to dentate gyrus of hippocampus, attributed to NTF secretion • Genetic manipulations to overexpress genes or program cells

  29. MSC induction to NF-SC SPN L-glutamate N2 hEGR hbFGF dbcAMP IBMX PDGF HRG1-β1 hbFGF Human Mesenchymal Stem Cells Neurotrophic factor secreting cells Media replaced 72 hrs later Passaged 12-18 days

  30. Figure 1: Confirmation of neurotrophic factor secretion.

  31. In vitro model of Parkinson’s Serum-free media (control) MSC Culture supernatant (control) + 1h 32-160 μM 6-OHDA Serum-free media NTF-SC Culture supernatant (contains NTF) Serum-free media

  32. 6-OHDA • 6-hydroxydopamine – selectively neurotoxic for DA neurons • drug redistributes DA from synaptic vesicles • Oxidized DA = DA-quinone reacts w/ DA uptake transporter

  33. Figure 2: NTF-SC/MSC protect neuroblastoma cells against 6-OHDA toxicity • MSC and NTF-SC groups were statistically significant @ 32, 48, and 72μM 6- OHDA. • No statistical difference b/t MSC & NTF-SC • @ 160μM, NTF-SC were statistically different from others

  34. Figure 3: Behavioral tests after stem cell transplant in 6-OHDA treated rats

  35. Control Treated PBS MSC NTF-SC

  36. Cellular transplantation inhibited 6-OHDA-induced dopamine depletion *

  37. Conclusions and Future Directions • NTF-SC could • increase production/ secretion of BDNF & GDNF • Attenuate 6-OHDA-induced behavior • Increase striatal dopamine • Autotransplantation of rat-derived MSC and induced NTF-SC • Transplantation later and at a site further from the lesion • Treatment for PD

  38. Baquet et al., 2005 S Fig 1

  39. Baquet et al., 2005 S Fig 2

  40. Baquet et al., 2005 S Fig 2

  41. Sudan et al, 2009 S Fig 1

  42. S Fig 2

  43. S Fig 3

  44. Gene’s associated with early onset PD • α-synuclein UCHL1 (ubiquitin carboxy-terminal hydrolase L1) • Parkin – ubiquitin E3 ligase that prepares proteins for degradation • DJ1: a parkin associated protein involved with oxidative stress • PINK1: Phosphatase and tensin homolog–INduced Kinase;putative serine threonine kinase • possible pathogenic mechanisms?

  45. PD Etiology • 10% of cases: genes • α-synuclein • Parkin • DJ-1 • 90% of cases – unknown • Age • Environment (toxic exposure, drug use)

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