Nils Freundlieb

Dopaminergic Substantia Nigra Neurons Project Topographically Organized to the Subventricular Zone and Stimulate Precursor Cell Proliferation in Aged Primates

The subventricular zone of the adult primate brain contains neural stem cells that can produce new neurons. Endogenous neurogenesis might therefore be used to replace lost neurons in neurodegenerative diseases. This would require, however, a precise understanding of the molecular regulation of stem cell proliferation and differentiation in vivo. Several regulatory factors, including dopamine, have been identified in rodents, but none in primates. We have, therefore, studied the origin and function of the dopaminergic innervation of the subventricular zone in nonhuman primates. Tracing experiments in three macaques revealed a topographically organized projection from the substantia nigra pars compacta (SNpc), but not the adjacent retrorubral field, to the subventricular zone: the anteromedial SNpc projects to the anteroventral subventricular zone, the posterolateral SNpc to the posterodorsal subventricular zone. Double immunolabeling for tyrosine hydroxylase and BrdU (5-bromo-2′deoxyuridine) incorporated into the DNA of proliferating cells showed that dopaminergic fibers approach proliferating cells in the subventricular zone. We investigated the effect of this nigro-subventricular projection on cell proliferation in six aged macaques, because the rate of neurogenesis differs between young adult and aged primates and because neurodegenerative diseases mainly affect aged humans. Three macaques were treated with MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) to decrease dopaminergic innervation of the subventricular zone. A significant decrease in the number of PCNA+ (proliferating cell nuclear antigen-positive) proliferating cells (−44%) and PSA-NCAM+ (polysialylated neural cell adhesion molecule-positive) neuroblasts (−59%) was found in the denervated regions of the subventricular zone, suggesting that an intact dopaminergic nigro-subventricular innervation is crucial for sustained neurogenesis in aged primates.

Adult Neurogenesis and Parkinsons Disease

Parkinsons disease is a neurodegenerative disorder characterized by a progressive neuronal loss affecting preferentially the dopaminergic neurons of the nigrostriatal projection. Transplantation of fetal dopaminergic precursor cells has provided the proof of principle that a cell replacement therapy can ameliorate clinical symptoms in affected patients. Recent years have provided evidence for the existence of neural stem cells with the potential to produce new neurons, particularly of a dopaminergic phenotype, in the adult mammalian brain. Such stem cells have been identified in so called neurogenic brain areas, where neurogenesis is constitutively ongoing, but also in primarily non-neurogenic areas, such as the midbrain and the striatum, where neurogenesis does not occur under normal physiological conditions. We review here presently published evidence to evaluate the concept that endogenous neural stem cells may have the potential to be instrumentalized for a non-invasive cell replacement therapy with autologous neurons to repair the damaged nigrostriatal dopaminergic projection in Parkinsons disease.

Neurogenesis in Substantia Nigra of Parkinsonian Brains

The clinical motor dysfunction in Parkinsons disease is primarily the consequence of a progressive degeneration of dopaminergic neurons in the substantia nigra of the nigrostriatal pathway. The degeneration of this tract provokes a depletion of dopamine in the striatum, where it is required as a permissive factor for normal motor function. Despite intense investigations, no effective therapy is available to prevent the onset or to halt the progression of the neuronal cell loss. Therefore, recent years have seen research into the mechanisms of endogenous repair processes occurring in the adult brain, particularly in the substantia nigra. Neurogenesis occurs in the adult brain in a constitutive manner under physiological circumstances within two regions: the dentate gyrus of the hippocampus and the subventricular zone of the lateral ventricles. In contrast to these two so-called neurogenic areas, the remainder of the brain is considered to be primarily nonneurogenic in nature, implying that no new neurons are produced there under normal conditions. The occurrence of adult neurogenesis in the substantia nigra under the pathological conditions of Parkinsons disease, however, remains controversial. Here, we review the published evidence of whether adult neurogenesis exists or not within the substantia nigra, where dopaminergic neurons are lost in Parkinsons disease.

No Association of the BDNF Val66met Polymorphism with Implicit Associative Vocabulary and Motor Learning

Brain-derived neurotrophic factor (BDNF) has been suggested to play a major role in plasticity, neurogenesis and learning in the adult brain. The BDNF gene contains a common val66met polymorphism associated with decreased activity-dependent excretion of BDNF and a potential influence on behaviour, more specifically, on motor learning. The objective of this study was to determine the influence of the BDNF val66met polymorphism on short-term implicit associative learning and whether its influence is cognitive domain-specific (motor vs. language). A sample of 38 young healthy participants was genotyped, screened for background and neuropsychological differences, and tested with two associative implicit learning paradigms in two different cognitive domains, i.e., motor and vocabulary learning. Subjects performed the serial reaction time task (SRTT) to determine implicit motor learning and a recently established associative vocabulary learning task (AVL) for implicit learning of action and object words. To determine the influence of the BDNF polymorphism on domain-specific implicit learning, behavioural improvements in the two tasks were compared between val/val (n = 22) and met carriers (val/met: n = 15 and met/met: n = 1). There was no evidence for an impact of the BDNF val66met polymorphism on the behavioural outcome in implicit short-term learning paradigms in young healthy subjects. Whether this polymorphism plays a relevant role in long-term training paradigms or in subjects with impaired neuronal plasticity or reduced learning capacity, such as aged individuals, demented patients or patients with brain lesions, has to be determined in future studies.

Ipsilesional motor area size correlates with functional recovery after stroke: A 6-month follow-up longitudinal TMS motor mapping study

PURPOSE Transcranial magnetic stimulation (TMS) and measurements of upper limb function were longitudinally applied to gain further insights into processes involved in functional recovery from the acute to the chronic stage after stroke. METHODS 10 acute stroke patients were monitored over 6 months behaviourally and with established TMS protocols. By using neuronavigated motor mapping, behavioural parameters, and a mixed model analysis, the role of the frontal and parietal part of the motor area of both hemispheres for functional recovery was determined. RESULTS Size and volume of the ipsilesional motor area (MAipsi) were significantly decreased in the acute phase compared to the contralesional motor area (MAcontra). Size of MAipsi, especially its frontal part, changed over time and was positively correlated with functional recovery, whereas resting motor threshold, volume of both MA or the shift of its center of gravity did not show any association with recovery. CONCLUSION The present data suggests the presence of a positive correlation between changes of the motor representation of the lesioned hemisphere and functional recovery after stroke. A possible interpretation is that rather (re-)activated corticomotor outputs are substrates of functional recovery after stroke than increased efficacy of residual, non-lesioned pathways.

Associative Vocabulary Learning: Development and Testing of Two Paradigms for the (Re-) Acquisition of Action- and Object-Related Words

Despite a growing number of studies, the neurophysiology of adult vocabulary acquisition is still poorly understood. One reason is that paradigms that can easily be combined with neuroscientfic methods are rare. Here, we tested the efficiency of two paradigms for vocabulary (re-) acquisition, and compared the learning of novel words for actions and objects. Cortical networks involved in adult native-language word processing are widespread, with differences postulated between words for objects and actions. Words and what they stand for are supposed to be grounded in perceptual and sensorimotor brain circuits depending on their meaning. If there are specific brain representations for different word categories, we hypothesized behavioural differences in the learning of action-related and object-related words. Paradigm A, with the learning of novel words for body-related actions spread out over a number of days, revealed fast learning of these new action words, and stable retention up to 4 weeks after training. The single-session Paradigm B employed objects and actions. Performance during acquisition did not differ between action-related and object-related words (time*word category: p = 0.01), but the translation rate was clearly better for object-related (79%) than for action-related words (53%, p = 0.002). Both paradigms yielded robust associative learning of novel action-related words, as previously demonstrated for object-related words. Translation success differed for action- and object-related words, which may indicate different neural mechanisms. The paradigms tested here are well suited to investigate such differences with neuroscientific means. Given the stable retention and minimal requirements for conscious effort, these learning paradigms are promising for vocabulary re-learning in brain-lesioned people. In combination with neuroimaging, neuro-stimulation or pharmacological intervention, they may well advance the understanding of language learning to optimize therapeutic strategies.

Differential effects of BDNF val(66)met in repetitive associative learning paradigms.

In healthy young subjects, the brain derived neurotropic factor (BDNF) val(66)met polymorphism negatively affects behavioural outcome in short-term motor cortex or hippocampus-based learning paradigms. In repetitive training paradigms over several days this effect can be overcome, in tests involving other brain areas even positive effects were found. To further specify the role of this polymorphism in cognitive processes, we used an associative vocabulary learning paradigm over four consecutive days and tested 38 young healthy subjects and 29 healthy elderly subjects. As a control paradigm, we designed a nonverbal haptic Braille letter-learning paradigm based on the same principles. Behavioural outcome was then associated with the BDNF-genotype. In the vocabulary learning task, met carrier (met/val and met/met) benefitted more from the repetitive training than val/val subjects. This was paralleled by a higher reduction of delayed answers during the course of the study, an effect that was also present in the haptic paradigm. However, in a group of healthy elderly subjects, no similar tendency was found. We conclude that the BDNF val(66)met polymorphism alters highly circumscribed answer behaviours in young healthy subjects. This might partly explain the high variability of previously published results.

tDCS Over the Motor Cortex Shows Differential Effects on Action and Object Words in Associative Word Learning in Healthy Aging

Healthy aging is accompanied by a continuous decline in cognitive functions. For example, the ability to learn languages decreases with age, while the neurobiological underpinnings for the decline in learning abilities are not known exactly. Transcranial direct current stimulation (tDCS), in combination with appropriate experimental paradigms, is a well-established technique to investigate the mechanisms of learning. Based on previous results in young adults, we tested the suitability of an associative learning paradigm for the acquisition of action- and object-related words in a cohort of older participants. We applied tDCS to the motor cortex (MC) and hypothesized an involvement of the MC in learning action-related words. To test this, a cohort of 18 healthy, older participants (mean age 71) engaged in a computer-assisted associative word-learning paradigm, while tDCS stimulation (anodal, cathodal, sham) was applied to the left MC. Participants’ task performance was quantified in a randomized, cross-over experimental design. Participants successfully learned novel words, correctly translating 39.22% of the words after 1 h of training under sham stimulation. Task performance correlated with scores for declarative verbal learning and logical reasoning. Overall, tDCS did not influence associative word learning, but a specific influence was observed of cathodal tDCS on learning of action-related words during the NMDA-dependent stimulation period. Successful learning of a novel lexicon with associative learning in older participants can only be achieved when the learning procedure is changed in several aspects, relative to young subjects. Learning success showed large inter-individual variance which was dependent on non-linguistic as well as linguistic cognitive functions. Intriguingly, cathodal tDCS influenced the acquisition of action-related words in the NMDA-dependent stimulation period. However, the effect was not specific for the associative learning principle, suggesting more neurobiological fragility of learning in healthy aging compared with young persons.

Diesterified derivatives of 5-iodo-2'-deoxyuridine as cerebral tumor tracers.

With the aim to develop beneficial tracers for cerebral tumors, we tested two novel 5-iodo-2′-deoxyuridine (IUdR) derivatives, diesterified at the deoxyribose residue. The substances were designed to enhance the uptake into brain tumor tissue and to prolong the availability in the organism. We synthesized carrier added 5-[125I]iodo-3′,5′-di-O-acetyl-2′-deoxyuridine (Ac2[125I]IUdR), 5-[125I]iodo-3′,5′-di-O-pivaloyl-2′-deoxyuridine (Piv2[125I]IUdR) and their respective precursor molecules for the first time. HPLC was used for purification and to determine the specific activities. The iodonucleoside tracer were tested for their stability against human thymidine phosphorylase. DNA integration of each tracer was determined in 2 glioma cell lines (Gl261, CRL2397) and in PC12 cells in vitro. In mice, we measured the relative biodistribution and the tracer uptake in grafted brain tumors. Ac2[125I]IUdR, Piv2[125I]IUdR and [125I]IUdR (control) were prepared with labeling yields of 31–47% and radiochemical purities of >99% (HPLC). Both diesterified iodonucleoside tracers showed a nearly 100% resistance against degradation by thymidine phosphorylase. Ac2[125I]IUdR and Piv2[125I]IUdR were specifically integrated into the DNA of all tested tumor cell lines but to a less extend than the control [125I]IUdR. In mice, 24 h after i.p. injection, brain radioactivity uptakes were in the following order Piv2[125I]IUdR>Ac2[125I]IUdR>[125I]IUdR. For Ac2[125I]IUdR we detected lower amounts of radioactivities in the thyroid and stomach, suggesting a higher stability toward deiodination. In mice bearing unilateral graft-induced brain tumors, the uptake ratios of tumor-bearing to healthy hemisphere were 51, 68 and 6 for [125I]IUdR, Ac2[125I]IUdR and Piv2[125I]IUdR, respectively. Esterifications of both deoxyribosyl hydroxyl groups of the tumor tracer IUdR lead to advantageous properties regarding uptake into brain tumor tissue and metabolic stability.