Neurodegenerative diseases with an iron accumulation component: A wide variety of neurological diseases are characterized by the accumulation of iron in different areas of the central nervous system, include Parkinson’s disease, Huntington disease, Alzheimer’s disease, Friedreich’s ataxia, amyotrophic lateral sclerosis, pantothenate kinase-associated neurodegeneration and other neuropathologies associated with brain iron accumulation (Hayflick et al., 2018).

In this perspective, we focus on Parkinson’s disease, a neurodegenerative disorder characterized by the death of dopaminergic neurons of the sustantia nigra pars compacta, which results in the decreased release of the neurotransmitter dopamine at the centers of movement control in the striatum. These neurons are particularly vulnerable to degeneration because of their extensive branching and the large amounts of energy required to keep ionic gradients along this network: a prototype sustantia nigra dopaminergic neuron is estimated to have an average total neuritic tree length of about 4.5 meters and to give rise to 1–2.4 million synapses (Mamelak, 2018).

Iron accumulation and iron-induced damage in idiopathic Parkinson’s disease: Idiopatic Parkinson’s disease is the best characterized form of this disease in which a link between iron accumulation and its associated pathology has been established (Ward et al., 2014). In dopaminergic neurons, iron acts as a double-edged sword. These neurons require an ample supplement of iron for energy production in the mitochondrion and for dopamine synthesis. Notwithstanding, iron in its redox-active form reacts with hydrogen peroxide produced by dopamine catabolism and mitochondria as a byproduct of the electron transport chain, generating through the Fenton reaction the noxious hydroxyl radical. The Fenton reaction is a fast, thermodynamically favorable nonenzymatic reaction that obeys mass action law. These characteristics of the reaction result in a direct relationship between the concentration of redox-active iron and the production of hydroxyl radical (Uranga and Salvador, 2018).

Idiopathic Parkinson’s disease treatment: The introduction of levodopa, the natural precursor of dopamine, was the most important milestone in the current therapy paradigm of idiopathic Parkinson’s disease. In the central nervous system levopoda generates dopamine through the enzyme 3,4-dihydroxyphenyl-l-alanine (DOPA) decarboxylase. The association of levodopa with a peripheral DOPA decarboxylase inhibitor (carbidopa or benserazide), increases the bioavailability of cerebral dopamine especially at the striatal level, and substantially improves the tolerance of patients to levodopa treatment. The combination of levodopa/carbidopa or benserazide is currently the most potent therapy for treating idiopathic Parkinson’s disease patients, whom when receiving this treatment experience an improvement in motor symptoms that remains stable throughout the day and persists during the first months or years of levodopa treatment (Chana, 2009). Unfortunately, this initial success decays after a few years of treatment due to the development of motor and mental complications, which do not respond to levodopa therapy. Among the alternative therapies available, good control of motor symptoms is achieved using dopamine agonists, MAOB and COMT inhibitors (https://www.mayoclinic.org/diseases-conditions/parkinsons-disease/diagnosis-treatment/drc-20376062). Alternative treatments include deep brain stimulation and spinal cord stimulation.

Considering the neurodegenerative nature of Parkinson’s disease, and the purely symptomatic treatment of current therapies, the first question we must ask ourselves is how to advance from symptomatic to neuroprotective treatments.

The current standard for the validation of a neuroprotective effect is a delayed-start design, in which the Unified Parkinson’s Disease Rating Scale score is used as the dependent variable [Figure 1]A. A neuroprotective effect is evidenced if at month 9 of treatment the curve presents differences between the early onset (9-month treatment) and the delayed onset (6-month treatment) groups. If these curves come together the treatment effect is just symptomatic. In all groups there may be an initial small improvement due to a placebo effect.{Figure 1}

To date, no neuroprotective treatment with demonstrable efficacy has been demonstrated, although its search is a very active focus of current research (Kulisevsky et al., 2018). Because of the heterogeneous and multifactorial nature of the disease, probably there is no single treatment that will stop the neurodegenerative process. Nevertheless, the earlier we can intervene the progress of the disease, ideally in pre-clinical stages, the greater the probability of success. A recent analysis suggests that all attempts to develop an effective therapy have failed because the molecular determinants of the disease will manifest differentially in each individual patient. The authors propose the use of drug cocktails to attack different molecular targets, and the selection of sub-populations of patients enriched in the intended drug target (Lang and Espay, 2018).

Clinical trials using iron chelation: Positive experiences validate the use of iron chelation therapy for the treatment of systemic diseases such as thalassemia major, sickle cell disease and cardiomyopathy associated with hereditary hemochromatosis. Recently, iron chelation has been introduced as a new therapeutic concept for the treatment of neurodegenerative diseases that have a component of iron accumulation (Nunez and Chana-Cuevas, 2018).

A current search in (https://clinicaltrials.gov.) yielded 16 ongoing or finished trials of iron chelation for the treatment of neurodegenerative diseases: 5 trials for Parkinson’s disease, 3 for Friedreich’s ataxia, 3 for amyotrophic lateral sclerosis, 1 for mild Alzheimer’s disease, 2 for pantothenate kinase-associated neurodegeneration and 2 for neurodegeneration with brain iron accumulation. These numbers disclose the present times relevance of the use of iron chelation therapy for the treatment of neurodegenerative diseases that have an iron accumulation component.

Until now, the results on the use of chelators for the treatment of neurodegenerative diseases are largely inconclusive. Clinical trials using the iron chelator deferiprone for the treatment of Parkinson’s disease almost unanimously draw the same conclusion: results in slowing disease progression are sufficiently significant to prompt larger studies that might provide clinical benefits to Parkinson’s disease patients (Devos et al., 2014). In this respect, a probe of concept that iron chelation therapy is here to stay is the FAIR PARK II trial, now in the recruiting phase (www.fairpark2.eu). The FAIR PARK II is a large (338 patients) phase 2 European clinical trial aimed at evaluating whether deferiprone can slow Parkinson’s disease progress in patients (Moreau et al., 2018).

Putative neuroregenerative properties of iron chelators: Progressive neuronal death in Parkinson’s disease occurs by a process of dying-back, characterized by progressive neurite loss and axon shortening; the death of the neuronal body is the last step in this process. Accordingly, at the onset of motor symptoms, the loss of dopaminergic fiber density in the dorsal putamen was found to be considerably larger compared to the loss of neuron bodies in the sustantia nigra (Grosch et al., 2016). If cell body death is delayed compared to axonal degeneration, alive but dysfunctional neurons could be rescued by neuritogenic stimuli.

Only a few studies have reported the putative capacity of iron chelators to generate neurite growth. In recent years, the group of Moussa Youdim at Technion – Israel Institute of Technology, has developed a family of iron chelating agents, represented by M30. M30 stabilizes hypoxia-inducible factor-1α, by inactivating the prolyl hydrolase that initiates its degradation, which activity depends on oxygen and Fe. In cell systems, the stabilization of hypoxia-inducible factor-1α by M30 induces the expression of the neurotrophic factors glial cell line-derived neurotrophic factor and brain-derived neurotrophic factor. M30 treatment also induces survival signaling factors such as protein kinase C, extracellular signal-regulated kinase 1/2, Akt and GSK-3β. Therefore, by chelating Fe, M30 has a large neuroprotective effect through stabilization of hypoxia-inducible factor-1α.

If the capacity of iron chelators to produce neuritogenesis holds in in vivo treatments, the expected effect of iron chelation therapy will be a slow-down of the neurodegeneration process [Figure 1]B1. Moreover, if connections between damaged neurons in the substantia nigra and movement control centers in the striatum are reestablished, then a reverse of the neurodegenerative process is to be expected. Considering the process of dying-back, the earlier the iron chelation therapy starts the better will be the neuroregenerative outcome [Figure 1]B2.

Perspective: Iron chelation therapy offers the chance of providing a critical change in the paradigm for the treatment of Parkinson’s disease, from a symptomatic treatment to another that slows or stops the disease progression. Nevertheless, because of the multifactorial nature of the disease, a “single target drug”, as an iron chelator, may not be sufficient to induce complete neuroprotection. In this context, clinical evaluation of multifunctional iron chelators that in animal models slow or deter the neurodegenerative process is needed (Nunez and Chana-Cuevas, 2018). Also needed is an early diagnosis of the disease, since the neuroprotective effects of these compounds will be higher if treatment starts when neuronal death is lower. [13]

This work was supported by FONDEF 17I10095 grant from Comisión Nacional de Investigación Científica y Tecnológica (CONICYT, to MTN).

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Peer review: Externally peer reviewed.

Open peer reviewers: Mónica Sanchez, Universidad Nacional de Córdoba, Argentina; Basant K. Puri, Imperial College London, London, UK.