Title: Erythropoietin & Neuronal Recovery
1ErythropoietinNeuronal Recovery
- Matthew Barber Michael Mienaltowski
- VIPS V Presentation
- October 11, 2002
2What is EPO?- hematopoiesis -
3What is EPO?- recombinant human EPO -
- The cloning and expression of human
erythropoietin (EPO) was first described by Lin
et al. in 1985.
- Recombinant erythopoietin (r-hEPO) is used to
treat patients with EPO-dependent nonregenerative
anemia.
4What is EPO?- recombinant human EPO -
- Recombinant human EPO therapy has been successful
with humans and of limited success in animals. - A large proportion of treated animals develop an
anti-hEPO immune response.
Is there a solution to the immunogenicity dilemma
for dogs and cats?
5What is EPO?- recombinant cEPO fEPO -
- Dog and cat therapies are being developed.
Results of early clinical trials are favorable.
- Cloning and expression of canine and feline
erythropoietin genes were first described by the
MacLeod Lab in 1998. - Right Data from MacLeod Lab at Cornell University
6What is EPO?- An alternative therapy? -
- Erythropoietin has also been shown to
- Reduce inflammation
- Inhibit apoptosis
- Promote growth and development in neural stem
cells.
7Nerve Damage Apoptosis
Two Phases of Neuronal Death 1) Immediate
necrosis of most severely affected neurons (due
to glutamate-mediated excitotoxicity, free
radical production, inflammatory mediators) 2)
Apoptosis of neurons outside of
ground zero due to prolonged
hypoxia
8Nerve Damage Apoptosis
- Proapoptotic
- TR3
- Caspase-1 3
- bax, bak, bid, bad
- p53
- Antiapoptotic
- NF-?B
- TRAF 1 2
- c-IAP 1 2
- Bcl-2 Bcl-w
TUNEL assay for apoptosis
9Nerve Damage Apoptosis
- Proposed Process of Ischemia Induced Apoptosis
- Buildup of nuclease in the nucleus
- Synthesis of transglutaminase
- Release of transcription factor TR3
- Increase in mitochondrial membrane permeability
- Release of caspase enzymes and cytochrome C
- Activation of caspase cascade and nuclease
- Apoptosis
10Nerve Damage Apoptosis
TR3
11Nerve Damage Apoptosis
- Cleanup of Cellular Debris After Neuronal Insult
- Removal of debris from immediate necrosis is
mediated primarily by PMNs due to the release of
proinflammatory cytokines released at initial
insult - Removal of apoptotic debris is mediated almost
exclusively by macrophages, so inflammation is
greatly reduced
12Cellular EPO Recovery
- Treatments to Date for CNS Injury
- Primarily supportive
- High-dose glucocorticoid therapy has been shown
to be effective, although mechanisms are unclear - Ex Methylprednisolone
13Cellular EPO Recovery
- Possible treatments in the future include IL-1ra
and especially EPO, the topic of todays
discussion
14Cellular EPO Recovery
- EPO induced neuronal Recovery
- Phosphorylation of I-?B
- Nuclear translocation of NF-?B
- Initiation of transcription of neuroprotective
genes and their subsequent translation-thus
resulting in ischemic tolerance - Also, EPO receptors on endothelial cells
initiates vascular actions to preserve blood
supply to ischemic areas, thus lessening ischemic
damage
15EPOs Role InNeuronal Recovery
Goldman Nedergaard. Nature (2002) 8 785-787.
16EPONeuronal Recovery
Recombinant human erythropoietin counteracts
secondary injury and markedly enhances
neurological recovery from experimental spinal
cord trauma Alfredo Gorio, Necati Gokmen, Serhat
Erbayraktar, Osman Yilmaz, Laura Madaschi, Cinzia
Cichetti, Anna Maria Di Guilo, Enver Vardar,
Anthony Cerami, and Michael Brines. Proc. Natl.
Acad. Sci., USA (2002) 99 9450-9455.
- Researchers experimentally injured rats to model
- Aneurysm
- Traumatic Spinal Cord Injury
17EPONeuronal Recovery
Aneurysm Clip Model (48 animals)
Sham (n 6) No aneurysm (just incision)
Control (n 14) Aneurysm Immediate Saline
i.p.
Exp 1a (n 14) Aneurysm Immediate 1000
U/kg r-hEPO, i.p.
Exp 2a (n 14) Aneurysm 1000 U/kg r-hEPO,
i.p. SID for 3 days
18PNAS fig 1-- Treatment after removing aneurysm
clip --
- Good short-term neuro response to EPO at doses of
1000U/kg (Exp 1a) and 3000U/ml (Exp 2a). - Likewise, a favorable neurological recovery (18
out of 21) beginning at days 20-28.
0 no observable hindlimb movements 21
normal gait
19EPONeuronal Recovery
Gorio et al. (2002), Fig 5
Traumatic Spinal Cord Injury Model (56 animals)
Control (n 14) Impaction Saline i.p. 1 hr
post-injury
Exp 1t (n 14) Impaction 5000 U/kg r-hEPO,
i.p., 1 hr post-injury
Exp 2t (n 14) Impaction 5000 U/kg r-hEPO,
i.p. SID for 7 days
Exp 3t (n 14) Impaction 500 U/kg r-hEPO,
i.p. SID for 7 days
20PNAS fig 2-- TSCI treatment studies --
- Favorable short-term neuro response seen with EPO
treatment (intermediate to significant) - Favorable neurological recovery after one month
with HI EPO dose given once.
21PNAS fig 3-- TSCI treatment studies --
- Swimming studies show significance of 5000 U/kg
r-hEPO dose. - 500 U/kg r-hEPO SID for 3 days produces a
response comparable to saline treatment (control) - BOTTOM LINE
- Dose-dependence suggested
22PNAS fig 4-- EPO is a neuroprotectant --
- Upper 5000 U/kg r-hEPO i.p. for 7 days. White
matter is preserved. - Lower Saline treatment. Cavitation with
widespread degnereration and swollen myelin
sheaths.
23ArticleSummary
These observations suggest that r-hEPO provides
early recovery of function, especially after
spinal cord compression, as well as
longer-latency neuroprotective, antiinflammatory
and antiapoptotic functions. - Gorio et al.
Proc. Natl. Acad. Sci., USA (2002) 99 9450-9455.
24Just A Few Possible Future Indications For EPO
- EPO-dependent anemia, of course
- Spinal Cord Injury
- HBC
- Vessel nerve damage due to prolonged surgery
- retinopathies
25EPONeuronal Recovery
Beneficial effects of systemic administration of
recombinant human erythropoietin in rabbits
subjected to subarachnoid hemorrhage Giovanni
Grasso et al. Proc. Natl. Acad. Sci., USA (2002)
99 5627-5631.
After an aneurysmal subarachnoid hemorrhage,
cerebral vasoconstrictions leads to ischemia,
impairment of neurological function, and then
death
26PNASSAH fig 2
A control B control placebo C control
r-hEPO
D SAH E SAH placebo F SAH r-hEPO
EPO eases vasoconstriction
27PNAS SAH BBB access
- Also Increased CSF concentrations of EPO in
rabbits with SAH - Possible mechanism
SAH
Administration of r-hEPO
BBB allows increased EPO access to CSF
Endothelial EPO receptor activation
Neuroprotection
28EPO Nerve Regeneration
- Erythropoietin and VEGF Promote Neural Outgrowth
from Retinal Explants in Postnatal Rats - Simone Böcker-Meffert, Philip Rosenstiel, Claudia
Röhl, Nils Warneke, Janka Held-Feindt, Jobst
Sievers and Ralph Lucius - From the Institute of Anatomy,
Christian-Albrechts-University of Kiel, Kiel,
Germany.
29EPO Nerve Regeneration
Addition of EPO to retinal explants in vitro
increased the number of neurites up to 169
19, a hitherto unknown function of EPO in the
CNS
Bocker-Meffert et al. (2002) Fig. 1
30Summary
- Erythropoietin is a hormone produced by the
kidney which was commercially developed for
treating EPO-dependent anemia. - Basic research into apoptosis and the regulatory
role of EPO has sparked interest into
erythropoietins potential roles in
neuroprotective mechanisms.
31Indications for Further Research
- Proper dosage?
- Timing of administration?
- Will EPO regenerate neurons in the spinal cord?
- Can EPO be used to protect retinas in animals w/
glaucoma, central artery occlusion, and diabetic
retinopathy?
32References
- MacLeod JN, Tetrault JW, Lorschy KAS, Gu DN.
Expression and bioactivity of recombinant canine
erythropoietin. American Journal of Veterinary
Research (1998) 59 1144-1148. - Piercy RJ, Swardon CJ, Hinchcliff KW. Erythroid
hypoplasia and anemia following administration of
recombinant human erythropoietin to two horses.
JAVMA (1998) 212 244-247. - Randolph JF, Stokol T, Scarlett JM, MacLeod JN.
Comparison of biological activity and safety of
recombinant canine erythropoietin in clinically
normal dogs. American Journal of Veterinary
Research (1999) 60 636-642. - Gorio A, Gokmen N, Erbayraktar S, Yilmaz O,
Madaschi L, Cichetti C, Di Guilo AM, Vardar E,
Cerami A, Brines M. Recombinant human
erythropoietin counteracts secondary injury and
markedly enhances neurological recovery from
experimental spinal cord trauma. PNAS, USA (2002)
99 9450-9455.
33References
- Goldman SA Nedergarrd M. Erythropoietin
strikes a new cord. Nature (2002) 8 785-787. - Bocker-Meffert S, Rosenstiel P, Rohl C, Warneke
N, Held-Feindt J, Sievers J, Lucius R.
Erythropoietin and VEGF Promote Neural Outgrowth
from Retinal Explants in Postnatal Rats.
Investigative Ophthalmology and Visual Science
(2002) 43 2021-26. - Wang CY Baldwin Jr. AS. NF-kappa-B
antiapoptosis induction of TRAF1 and TRAF2 and
c-IAP1 and c-IAP2 to suppress caspase-8
activation. Science (1998) 281 1680-4. - Barinaga M. Stroke-damaged neurons may commit
cellular suicide. Science (1998) 281 1302. - Brenner C and Kroemer G. Mitochondriathe Death
Signal Integrators. Science (2000) 289 1150
34References
- Li H, Kolluri SK, Gu J, Dawson MI, Cau X, Hobbs
PD, Lin B, Chen G, Lu J, Lin F, Xie Z, Fontana
JA, Reed JC, Zhang X. Cytochrome c Release and
Apoptosis Induced by Mitochondrial targeting of
Nuclear Orphan Receptor TR3. Science (2000)
289 1159. - Pray L. Life or Death in Cells. The Scientist
(2001) 15 1. - Adams JM Cory S. The Bcl-2 Protein Family
Arbiters of Cell Survival. Science (1998) 281
1322-5. - Grasso G, Buemi M, Alafaci C, Sfacteria C,
Passalacqua M, Sturiale A, Calapai G, De Vico G,
Piedimonte G, Salpietro F, Tomasello F.
Beneficial effects of systemic administration of
recombinant human erythropoietin in rabbits
subjected to subarachnoid hemorrhage. PNAS, USA
(2002) 99 5627-5631.