GDNF Powers Neuron Sprouting in Human Brain
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For the first time, researchers have witnessed dopaminergic neuron sprouting in a Parkinson disease (PD) patient treated with the neurotrophic factor GDNF. A postmortem examination of the brain of a man who showed clinical neurological improvement after receiving GDNF revealed upregulation of the dopaminergic neuron marker tyrosine hydroxylase in the striatum. The results, coming from Stephen Gill’s group in London and published July 3 in Nature Medicine, may provide additional fuel to the fire now raging over the development of GDNF for PD, which was stopped last fall despite protests from clinicians and patients (see ARF related news story).
In the study, first author Seth Love and colleagues examined the brain of a 62-year-old man who had received GDNF infusion into the right posterior putamen for 43 months before the trial was halted, and subsequently died just 3 months later of a heart attack. Over the course of treatment, the man experienced improvement in most measures of neurological functioning and quality of life. Imaging studies during treatment showed increased uptake of labeled dopamine on the infusion side.
Immunostaining of brain sections for tyrosine hydroxylase (TH) revealed fivefold higher levels of the marker in the right (infused) posterior putamen over the left, untreated side. Enhanced TH immunoreactivity was seen up to 10 mm from the tip of the infusion catheter. Most labeling was in a fine, granular pattern, but some larger nerve fibers, axonal swellings, and cell bodies were also labeled. The analysis also revealed a small increase in the axon growth marker Gap43 on the infused side, supporting the idea that neuron sprouting was occurring in the area. Alternatively, existing dysfunctional fibers could have upregulated TH in response to GDNF. “In either case, however, the findings provide a possible substrate for the sustained clinical improvement and enhanced 18F-dopa uptake in humans receiving intraputamenal infusion of GDNF,” the authors write.
The observations reproduced results seen in animal models, which supported the development of GDNF for Parkinson disease in humans. The path has had its twists and turns, however. When promising results from an early, open-label human trial were not replicated in a phase II placebo-controlled design—patients showed no significant difference in neurological outcome between GDNF and placebo after 6 months' treatment—the trial was stopped last fall. Amgen subsequently pulled all patients off the drug for safety reasons, after reporting that high doses of GDNF caused neuron loss in monkeys. Patients who had experienced improvement clamored for the drug and sued Amgen to continue treatment. After a ruling handed down in Amgen’s favor in the US District Court in Manhattan, New York, on June 6, the patients vowed to appeal.—Pat McCaffrey
Comments
University of Bristol
I understand that further animal toxicity studies are in progress. However, over 100 patients have received intracerebral GDNF infusion by one route or another with no clinical toxicity and I can't believe that GDNF treatment won't be available again, at least in some form, in the medium term. To date, the immunogenicity of the recombinant GDNF has not proven to be of clinical significance, but could in any case be circumvented by implantation of autologous or encapsulated eukaryotic cells, genetically modified to secrete GDNF. Stimulating metabolic pathways that induce the synthesis of GDNF sounds attractive but poses problems of targeting, delivery, and specificity. I suggest that this is a less promising option, but would be happy to be proven wrong.
Toronto Western Hospital
The report by Love and colleagues in Nature Medicine provides intriguing preliminary evidence for a biological effect of GDNF in humans with Parkinson disease. The greater area of staining for tyrosine hydroxylase in the striatum on the side previously most affected by Parkinson disease suggests that GDNF stimulated neuronal sprouting and that this accounted for the increase in fluorodopa uptake seen on positron emission tomography. These observations are exciting but leave many unanswered questions. Is the change in striatal tyrosine hydroxylase and fluorodopa PET sufficient to account for the 38 percent reduction (i.e., improvement) in motor scores? Even more impressive changes in both of these parameters are seen following fetal nigral transplantation, but clinical benefit has been disappointing in double-blind placebo-controlled trials. Love and colleagues present additional results of GFAP and GAP43 immunohistochemistry; however, similar control data from normal and untreated parkinsonian brains were not provided for comparison. Finally, although the results are potentially important in demonstrating a biological effect of this treatment, they also raise questions about the early and bilaterally symmetrical clinical benefit reported following open-label unilateral infusion by Slevin et al., since Love’s patient showed very clear progression on the non-infused side.
The double-blind placebo-controlled trial failed to demonstrate significant efficacy of bilateral intraputamenal GDNF infusion. Importantly, this trial utilized a different catheter and somewhat different doses than were used in the patient reported by the Bristol group. It is not known whether these differences could account for the contrasting results of the open-label and double-blind studies. In addition, a similar change in fluorodopa PET to that originally reported by Gill and colleagues) was obtained in the double-blind trial despite the lack of benefit. During this trial and its open-label extension, 10 percent of patients developed blocking antibodies to GDNF, and subsequently, studies in primates demonstrated evidence for an unusual cerebellar toxicity. The clinical implications of these two findings for humans with Parkinson disease are unknown. In the face of a negative double-blind clinical trial and the development of these safety issues, Amgen chose to discontinue further use of this treatment in Parkinson disease. Subsequently, two patients from New York took the company to court demanding that continued treatment with GDNF be made available to them. The court found in favor of Amgen and the lawsuit was dismissed. Unfortunately, the current formulation of recombinant GDNF as manufactured by Amgen will probably not be used again in patients with Parkinson disease unless further basic studies can resolve these potentially important safety issues. It is hoped that other trophic factors or other methods of applying GDNF (e.g., gene therapy or cell-based therapies) will fulfill the promise of this approach in Parkinson disease. Finally, it should be emphasized that many of the problems we face in managing late-stage Parkinson disease do not stem from striatal dopamine deficiency, and therefore would not be expected to respond to even the most effective rejuvenation or replacement of the nigrostriatal dopamine system.
References:
Gill SS, Patel NK, Hotton GR, O'Sullivan K, McCarter R, Bunnage M, Brooks DJ, Svendsen CN, Heywood P. Direct brain infusion of glial cell line-derived neurotrophic factor in Parkinson disease. Nat Med. 2003 May;9(5):589-95. PubMed.
Slevin JT, Gerhardt GA, Smith CD, Gash DM, Kryscio R, Young B. Improvement of bilateral motor functions in patients with Parkinson disease through the unilateral intraputaminal infusion of glial cell line-derived neurotrophic factor. J Neurosurg. 2005 Feb;102(2):216-22. PubMed.