Efeito do extrato aquoso de folhas de mogno (Swietenia macrophylla) em modelo in vivo de doença de Parkinson com lesão com 6-hidroxidopamina

A doença de Parkinson (DP) é caracterizada pela degeneração progressiva dos neurônios dopaminérgicos da substância negra e por presença de sinais clínicos clássicos, tais como bradicinesia, rigidez muscular, tremor em repouso e instabilidade postural. A etiologia ainda é desconhecida e as opções de tratamento disponíveis promovem apenas o alívio dos sintomas. Nesse sentido, os modelos experimentais de DP são fundamentais em estudos visando identificar os eventos moleculares envolvidos na doença e a descoberta de novas terapias neuroprotetoras. Este trabalho utilizou um modelo de hemiparkinsonismo, com lesão induzida por 6- hidroxidopamina (6-OHDA), e investigou os efeitos do extrato aquoso de folhas de mogno (Swietenia macrophylla) sobre as células dopaminérgicas da substância negra pars compacta (SNpc) e sobre parâmetros comportamentais avaliados no teste do campo aberto e no teste de rotações induzidas por apormofina. Os resultados mostraram que os animais lesionados com 6-OHDA apresentaram rotação contralateral induzida por apomorfina e redução significativa dos neurônios dopaminérgicos na SNpc. Entretanto, apenas o grupo injetado com 6-OHDA e tratado com mogno apresentou diminuição significante de neurônios no lado injetado em comparação com o grupo veículo/veículo. Houve também um decréscimo significante na ambulação e na bipedestação no grupo 6-OHDA/mogno. Com isso, nós concluímos que o extrato aquoso de mogno, nas condições utilizadas no presente estudo, potencializou o efeito citotóxico da 6-OHDA e ainda promoveu a piora do quadro comportamental dos animais.

Caracterização dos efeitos do extrato de folhas de Swietenia macrophylla em modelo experimental de doença de Parkinson

Estudos prévios indicam que o extrato de folhas de mogno Swietenia macrophylla possui composição química rica em substâncias antioxidantes com efeito neuroprotetor em cultura. Um dos principais mecanismos envolvidos na neurodegeração da Doença de Parkinson (DP) é o estresse oxidativo. Portanto, substâncias antioxidantes são candidatas potenciais para terapias que retardem o processo neurodegenerativo da doença. Este estudo tem por objetivo caracterizar os efeitos do extrato de folhas de mogno frente à degeneração nigroestriatal e alterações comportamentais de camundongos expostos a uma única injeção intraestriatal de 6-OHDA unilateralmente. Foram utilizados camundongos machos, os quais foram submetidos à cirurgia estereotáxica para a injeção de 20 μg de 6-OHDA no estriado esquerdo. Os animais foram subdivididos em 4 grupos, de acordo com a dose de extrato de mogno administrada. O extrato foi aplicado por via intraperitoneal nos 7 primeiros dias após a injeção de 6-OHDA nas doses de 0,0 (controle), 0,5 (G1), 1,0 (G2) e 5,0 mg/kg (G3). O grupo controle (GC) recebeu injeções de salina a 0,9% (veículo). Foi feita análise da ambulação no campo aberto antes, no 7º e no 21º dias e do número de rotações induzidas por apomorfina no 7º e no 21º dias após a cirurgia. Avaliação da neurodegeneração foi realizada através da contagem de neurônios dopaminérgicos TH+ na substância negra por estereologia. Como resultado, encontrou-se diferença estatisticamente significativa no 21º dia, onde os grupos G2 e G3 apresentaram redução no comportamento ambulatório em relação aos grupos G1 e GC; este dois últimos tiveram comportamento ambulatório equivalente entre si. Em relação às rotações induzidas por apomorfina, no 21º dia, o G1 apresentou média de rotações significativamente menor do que os grupos GC, G2 e G3. Na contagem de células, G1 apresentou diminuição na perda dos neurônios dopaminérgicos estatisticamente significativa em relação ao controle. Assim, concluímos que o extrato de mogno na concentração de 0,5 mg/kg promoveu neuroproteção na neurodegeneração do sistema nigroestriatal induzida por 6-OHDA.

Sintomas não motores na doença de Parkinson: modelo de lesão intraestriatal por 6-OHDA em camundongos

A doença de Parkinson (DP) é a segunda doença neurodegenerativa mais comum em idosos, caracterizada pela neurodegeneração de neurônios dopaminérgicos da substância negra (SN), com etiologia não claramente estabelecida, entretanto as causas podem estar associadas a exposição de toxinas ambientais e fatores genéticos. Os processos patológicos envolvidos na DP são disfunção mitocondrial, estresse oxidativo, inflamação e excitotoxicidade. A sintomatologia da DP são alterações motoras, cognitivas e autonômicas. Contudo, poucos estudos analisam os sintomas não-motores da DP, principalmente em modelos animais. Nesse contexto o objetivo deste trabalho foi avaliar sintomas não-motores da DP em modelo animal com lesão provocada pela neurotoxina 6-hidroxidopamina com duas doses diferentes, injetadas bilateralmente no estriado. Para alcançar nossos objetivos realizamos os testes de campo aberto, apomorfina, labirinto aquático de Morris e testes de discriminação olfativa, além de análises histológicas. Nossos resultados mostraram alterações motoras, déficits de memória e aprendizado, associadas a diminuição de células dopaminérgicas na SN, neurônios estriatais e neurônios da região hipocampal CA1. Dessa forma, esse modelo para os sintomas não-motores da DP pode ser utilizado para a compreensão dos mecanismos que envolvem a doença, assim como para avaliar medidas terapêuticas que possam retardar ou interromper a progressão da DP.

Variabilidade no andar com ultrapassagem de obstáculo de idosos com doença de Parkinson

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

NADPH Oxidase and Neurodegeneration

NADPH oxidase (Nox) is a unique, multi-protein, electron transport system that produces large amounts of superoxide via the reduction of molecular oxygen. Nox-derived reactive oxygen species (ROS) are known to be involved in a variety of physiological processes, including host defense and signal transduction. However, over the past decade, the involvement of (Nox)-dependent oxidative stress in the pathophysiology of several neurodegenerative diseases has been increasingly recognized. ROS produced by Nox proteins contribute to neurodegenerative diseases through distinct mechanisms, such as oxidation of DNA, proteins, lipids, amino acids and metals, in addition to activation of redox-sensitive signaling pathways. In this review, we discuss the recent literature on Nox involvement in neurodegeneration, focusing on Parkinson and Alzheimer diseases.

Different approaches, one target: understanding cellular mechanisms of Parkinson's and Alzheimer's diseases

Neurodegenerative disorders are undoubtedly an increasing problem in the health sciences, given the increase of life expectancy and occasional vicious life style. Despite the fact that the mechanisms of such diseases are far from being completely understood, a large number of studies; that derive from both the basic science and clinical approaches have contributed substantial data in that direction. In this review, it is discussed several frontiers of basic research on Parkinson's and Alzheimer's diseases, in which research groups from three departments of the Institute of Biomedical Sciences of the University of Sao Paulo have been involved in a multidisciplinary effort. The main focus of the review involves the animal models that have been developed to study cellular and molecular aspects of those neurodegenerative diseases, including oxidative stress, insulin signaling and proteomic analyses, among others. We anticipate that this review will help the group determine future directions of joint research in the field and, more importantly, set the level of cooperation we plan to develop in collaboration with colleagues of the Nucleus for Applied Neuroscience Research that are mostly involved with clinical research in the same field.

Molecular analysis of Sigma-1 receptor modulation of the dopamine transporter

Sigma (σ) receptors are well established as a non-opioid, non-phencyclidine, and haloperidol-sensitive receptor family with its own binding profile and a characteristic distribution in the central nervous system (CNS) as well as in endocrine, immune, and some peripheral tissues. Two σ receptors subtypes, termed σ1 and σ2, have been pharmacologically characterized, but, to date, only the σ1 has also been cloned. Activation of σ1 receptors alter several neurotransmitter systems and dopamine (DA) neurotrasmission has been often shown to constitute an important target of σ receptors in different experimental models; however the exact role of σ1 receptor in dopaminergic neurotransmission remains unclear. The DA transporter (DAT) modulates the spatial and temporal aspects of dopaminergic synaptic transmission and interprer the primary mechanism by wich dopaminergic neurons terminate the signal transmission. For this reason present studies have been focused in understanding whether, in cell models, the human subtype of σ1 (hσ1) receptor is able to directly modulate the human DA transporter (hDAT). In the first part of this thesis, HEK-293 and SH-SY5Y cells were permanently transfected with the hσ1 receptor. Subsequently, they were transfected with another plasmid for transiently expressing the hDAT. The hDAT activity was estimated using the described [3H]DA uptake assay and the effects of σ ligands were evaluated by measuring the uptaken [3H]DA after treating the cells with known σ agonists and antagonists. Results illustrated in this thesis demonstrate that activation of overexpressed hσ1 receptors by (+)-pentazocine, the σ1 agonist prototype, determines an increase of 40% of the extracellular [3H]DA uptake, in comparison to non-treated controls and the σ1 antagonists BD-1047 and NE-100 prevent the positive effect of (+)-pentazocine on DA reuptake DA is likely to be considered a neurotoxic molecule. In fact, when levels of intracellular DA abnormally invrease, vescicles can’t sequester the DA which is metabolized by MAO (A and B) and COMT with consequent overproduction of oxygen reactive species and toxic catabolites. Stress induced by these molecules leads cells to death. Thus, for the second part of this thesis, experiments have been performed in order to investigate functional alterations caused by the (+)-pentazocine-mediated increase of DA uptake; particularly it has been investigated if the increase of intracellular [DA] could affect cells viability. Results obtained from this study demonstrate that (+)-pentazocine alone increases DA cell toxicity in a concentration-dependent manner only in cells co-expressing hσ1 and hDAT and σ1 antagonists are able to revert the (+)-pentazocine-induced increase of cell susceptibility to DA toxicity. In the last part of this thesis, the functional cross-talking between hσ1 receptor and hDAT has been further investigated using confocal microscopy. From the acquired data it could be suggested that, following exposure to (+)-pentazocine, the hσ1 receptors massively translocate towards the plasma membrane and colocalize with the hDATs. However, any physical interaction between the two proteins remains to be proved. In conclusion, the presented study shows for the first time that, in cell models, hσ1 receptors directly modulate the hDAT activity. Facilitation of DA uptake induced by (+)-pentazocine is reflected on the increased cell susceptibility to DA toxicity; these effects are prevented by σ1 selective antagonists. Since numerous compounds, including several drugs of abuse, bind to σ1 receptors and activating them could facilitate the damage of dopaminergic neurons, the reported protective effect showed by σ1 antagonists would represent the pharmacological basis to test these compounds in experimental models of dopaminergic neurodegenerative diseases (i.e. Parkinson’s Disease).

Untersuchung neuer hochwirksamer neuroprotektiver Antioxidantien in experimentellen Modellen der Parkinsonschen Krankheit

Bei der Parkinsonschen Krankheit kommt es zu einer selektiven Degeneration der dopaminergen Neurone in der Substantia nigra pars compacta. Die Rolle des oxidativen Stresses in der Pathogenese dieser Erkrankung konnte an post mortem Untersuchungen der Parkinson-Patienten, wie auch an zahlreichen in vitro und in vivo Modellen bestätigt werden. Die Anwendung von Antioxidantien wurde als therapeutische Strategie der Parkinsonschen Krankheit vorgeschlagen. In dieser Hinsicht wurden bereits antioxidative Substanzen in klinischen Studien evaluiert. Klinische Studien mit Antioxidantien haben jedoch bislang nur wenig überzeugende Ergebnisse erbracht, mit Ausnahme des Einsatzes des Ubichinons (Coenzym Q). Eine kritische Analyse der klinischen Studien lässt zusammenfassen, dass auf Seiten der verwendeten Antioxidantien noch massiver Optimierungsbedarf besteht. Für einen erfolgreichen therapeutischen Einsatz von Antioxidantien bei dieser Krankheit sind folgende Eigenschaften der Substanzen von höchster Bedeutung: i) maximale neuroprotektive Aktivität bei geringen Dosen; ii) geringe Nebenwirkungen; iii) eine hohe Blut-Hirn-Schrankengängigkeit.In dieser Arbeit wurde das neuroprotektive Potential von drei Bisarylimin-basierten antioxidativen Strukturen (Phenothiazin, Iminostilben und Phenoxazin) in in vitro und in vivo Parkinson-Modellsystemen evaluiert. Beide experimentellen Modelle basieren auf der Wirkung der mitochondrialen Komplex I Inhibitoren 1-Methyl-4-Phenylpyridin (MPP+) und Rotenon, welche pathophysiologische Charakteristika der Parkinsonschen Krankheit reproduzieren. Unsere in vitro Untersuchungen an primären Neuronen des Mittelhirns und der klonalen SH-SY5Y-Neuroblastomazelllinie konnten zeigen, dass die Komplex I Inhibition krankheitsspezifische zelluläre Merkmale induziert, wie die Abnahme der antioxidativen Verteidigungskapazität und Verlust des mitochondrialen Membranpotentials. Zusätzlich kommt es in primären Neuronen des Mittelhirns zur selektiven Degeneration dopaminerger Neurone, welche in der Parkinsonschen Erkrankung besonders betroffen sind. Ko-Inkubation der in vitro Modelle mit Phenothiazin, Iminostilben und Phenoxazin in niedrigen Konzentrationen (50 nM) halten die pathologischen Prozesse fast vollständig auf. In vivo Untersuchungen am MPP+- und Rotenon-basierten Caenorhabditis elegans (C. elegans) Modell bestätigen das neuroprotektive Potential der Bisarylimine. Hierfür wurde eine transgene C. elegans Linie mithilfe einer dopaminerg spezifischen DsRed2- (Variante des rot fluoreszierenden Proteins von Discosoma sp.)-Expression und pan-neuronaler CFP- (cyan fluoreszierendes Protein)-Expression zur Visualisierung der dopaminergen Neuronenpopulation in Kontrast zum Gesamtnervensystem erstellt. Behandlung des C. elegans mit MPP+ und Rotenon im larvalen und adulten Stadium führt zu einer selektiven Degeneration dopaminerger Neurone, sowie zum Entwicklungsarrest der larvalen Population. Die dopaminerge Neurodegeneration, wie auch weitere phänotypische Merkmale des C. elegans Modells, können durch Phenothiazin, Iminostilben und Phenoxazin in niedrigen Konzentrationen (500 nM) komplett verhindert werden. Ein systemischer Vergleich aromatischer Bisarylimine mit bekannten, gut charakterisierten Antioxidantien, wie α-Tocopherol (Vitamin E), Epigallocatechingallat und β-Catechin, zeigt, dass effektive Konzentrationen für Phenothiazin, Iminostilben und Phenoxazin um Zehnerpotenzen niedriger liegen im Vergleich zu natürlichen Antioxidantien. Der Wirkungsmechanismus der Bisarylimine konnte in biochemischen und in vitro Analysen, sowie in Verhaltensuntersuchungen an C. elegans von der Wirkungsweise strukturell ähnlicher, neuroleptisch wirkender Phenothiazin-Derivate differenziert werden. Die Analyse des dopaminerg-gesteuerten Verhaltens (Beweglichkeit) in C. elegans konnte verdeutlichen, dass antioxidative und Dopaminrezeptor-bindende Eigenschaften der Bisaryliminstrukturen sich gegenseitig ausschließen. Diese qualitativen Merkmale unterscheiden Bisarylimine fundamental von klinisch angewandten Neuroleptika (Phenothiazin-Derivate), welche als Dopaminrezeptor-Antagonisten zur Behandlung psychischer Erkrankungen klinisch eingesetzt werden.Aromatische Bisarylimine (Phenothiazin, Iminostilben und Phenoxazin) besitzen günstige strukturelle Eigenschaften zur antioxidativ-basierter Neuroprotektion. Durch die Anwesenheit der antioxidativ wirkenden, nicht-substituierten Iminogruppe unterscheiden sich Bisarylimine grundlegend von neuroleptisch-wirkenden Phenothiazin-Derivaten. Wichtige strukturelle Voraussetzungen eines erfolgreichen antioxidativen Neuropharmakons, wie eine hohe Radikalisierbarkeit, die stabile Radikalform und der lipophile Charakter des aromatischen Ringsystems, werden in der Bisaryliminstruktur erfüllt. Antioxidative Bisarylimine könnten in der Therapie der Parkinsonschen Krankheit als eine effektive neuroprotektiv-therapeutische Strategie weiter entwickelt werden.

Funktionelle Analyse der Plasmamembran-Ca 2+-ATPase 2 -PMCA2- in Modellen der Neurodegeneration

Calcium (Ca2+) ist ein ubiquitär vorkommendes Signalmolekül, das an der Regulation zahlreicher zellulärer Prozesse, von der Proliferation bis zum programmierten Zelltod, beteiligt ist. Daher müssen die intrazellulären Ca2+-Spiegel streng kontrolliert werden. Veränderungen der Ca2+-Homöostase während der altersassoziierten Neurodegeneration können dazu beitragen, dass Neuronen vulnerabler sind. So wurden erhöhte Ca2+-Konzentrationen in gealterten Neuronen, begleitet von einer erhöhten Vulnerabilität, beobachtet (Hajieva et al., 2009a). Weiterhin wird angenommen, dass der selektive Untergang von dopaminergen Neuronen bei der Parkinson Erkrankung auf eine erhöhte Ca2+-Last zurückzuführen sein könnte, da diese Neuronen einem ständigen Ca2+-Influx,rnaufgrund einer besonderen Isoform (CaV 1.3) spannungsgesteuerter Ca2+-Kanäle des L-Typs, ausgesetzt sind (Chan et al., 2007). Bislang wurden die molekularen Mechanismen, die einem Ca2+-Anstieg zu Grunde liegen und dessen Auswirkung jedoch nicht vollständig aufgeklärt und daher in der vorliegenden Arbeit untersucht. Um Veränderungen der Ca2+-Homöostase während der altersassoziiertenrnNeurodegeneration zu analysieren wurden primäre Mittelhirnzellen aus Rattenembryonen und SH-SY5Y-Neuroblastomazellen mit dem Neurotoxin 1-Methyl-4-Phenyl-Pyridin (MPP+), das bei der Etablierung von Modellen der Parkinson-Erkrankung breite Anwendung findet, behandelt. Veränderungen der intrazellulären Ca2+-Konzentration wurden mit einem auf dem grün fluoreszierenden Protein (GFP)-basierten Ca2+-Indikator,rn„Cameleon cpYC 3.6“ (Nagai et al., 2004), ermittelt. Dabei wurde in dieser Arbeit gezeigt, dass MPP+ die Abregulation der neuronenspezifischen ATP-abhängigen Ca2+-Pumpe der Plasmamembran (PMCA2) induziert, die mit der Ca2+-ATPase des endoplasmatischen Retikulums (SERCA) und dem Na+/Ca2+-Austauscher (NCX) das zelluläre Ca2+-Effluxsystem bildet, was zu einer erhöhten zytosolischen Ca2+-Konzentration führt. Die PMCA2-Abnahme wurde sowohl auf Transkriptionsebene als auch auf Proteinebene demonstriert, während keine signifikanten Veränderungen der SERCA- und NCX-Proteinmengen festgestellt wurden. Als Ursache der Reduktion der PMCA2-Expression wurde eine Abnahme des Transkriptionsfaktors Phospho-CREB ermittelt, dessen Phosphorylierungsstatus abhängig von der Proteinkinase A (PKA) war. Dieser Mechanismus wurde einerseits unter MPP+-Einfluss und andererseits vermittelt durch endogene molekulare Modulatoren gezeigt. Interessanterweise konnten die durch MPP+ induzierte PMCA2-Abregulation und der zytosolische Ca2+-Anstieg durch die Aktivierung der PKA verhindert werden. Parallel dazu wurde eine MPP+-abhängige verringerte mitochondriale Ca2+-Konzentration nachgewiesen, welche mit einer Abnahme des mitochondrialen Membranpotentials korrelierte. Darüber hinaus kam es als Folge der PMCA2-Abnahme zu einem verminderten neuronalen Überleben.rnVeränderungen der Ca2+-Homöostase wurden auch während der normalen Alterung inrnprimären Fibroblasten und bei Mäusen nachgewiesen. Dabei wurden verringerte PMCA und SERCA-Proteinmengen in gealterten Fibroblasten, einhergehend mit einem Anstieg der zytosolischen Ca2+-Konzentration demonstriert. Weiterhin wurden verringerte PMCA2-Proteinmengen im Mittelhirn von gealterten Mäusen (C57B/6) detektiert.rnDer zelluläre Ca2+-Efflux ist somit sowohl im Zuge der physiologischen Alterung als auch in einem altersbezogenen Krankheitsmodell beeinträchtigt, was das neuronale Überleben beeinflussen kann. In zukünftige Studien soll aufgeklärt werden, welche Auswirkungen einer PMCA2-Reduktion genau zu dem Verlust von Neuronen führen bzw. ob durch eine PMCA2-Überexpression neurodegenerative Prozesse verhindert werden können.

Motor control system in Parkinson’s disease: a modeling approach

Parkinson’s disease is a neurodegenerative disorder due to the death of the dopaminergic neurons of the substantia nigra of the basal ganglia. The process that leads to these neural alterations is still unknown. Parkinson’s disease affects most of all the motor sphere, with a wide array of impairment such as bradykinesia, akinesia, tremor, postural instability and singular phenomena such as freezing of gait. Moreover, in the last few years the fact that the degeneration in the basal ganglia circuitry induces not only motor but also cognitive alterations, not necessarily implicating dementia, and that dopamine loss induces also further implications due to dopamine-driven synaptic plasticity got more attention. At the present moment, no neuroprotective treatment is available, and even if dopamine-replacement therapies as well as electrical deep brain stimulation are able to improve the life conditions of the patients, they often present side effects on the long term, and cannot recover the neural loss, which instead continues to advance. In the present thesis both motor and cognitive aspects of Parkinson’s disease and basal ganglia circuitry were investigated, at first focusing on Parkinson’s disease sensory and balance issues by means of a new instrumented method based on inertial sensor to provide further information about postural control and postural strategies used to attain balance, then applying this newly developed approach to assess balance control in mild and severe patients, both ON and OFF levodopa replacement. Given the inability of levodopa to recover balance issues and the new physiological findings than underline the importance in Parkinson’s disease of non-dopaminergic neurotransmitters, it was therefore developed an original computational model focusing on acetylcholine, the most promising neurotransmitter according to physiology, and its role in synaptic plasticity. The rationale of this thesis is that a multidisciplinary approach could gain insight into Parkinson’s disease features still unresolved.

Functional effect of FGF2- and FGF8-expanded ventral mesencephalic precursor cells in a rat model of Parkinson's disease

Ventral mesencephalic (VM) precursor cells are of interest in the search for transplantable dopaminergic neurons for cell therapy in Parkinson's disease (PD). In the present study we investigated the survival and functional capacity of in vitro expanded, primary VM precursor cells after intrastriatal grafting to a rat model of PD. Embryonic day 12 rat VM tissue was mechanically dissociated and cultured for 4 or 8 days in vitro (DIV) in the presence of FGF2 (20 ng/ml), FGF8 (20 ng/ml) or without mitogens (control). Cells were thereafter differentiated for 6 DIV by mitogen withdrawal and addition of serum. After differentiation, significantly more tyrosine hydroxylase-immunoreactive (TH-ir), dopamine-producing neurons were found in FGF2- and FGF8-expanded cultures compared to controls. Moreover, expansion for 4 DIV resulted in significantly more TH-ir cells than expansion for 8 DIV both for FGF2 (2.4 fold; P<0.001) and FGF8 (3.8 fold; P<0.001) treated cultures. The functional potential of the expanded cells (4 DIV) was examined after grafting into striatum of aged 6-hydroxydopamine-lesioned rats. Amphetamine-induced rotations performed 3, 6 and 9 weeks postgrafting revealed that grafts of FGF2-expanded cells induced a significantly faster and better functional recovery than grafts of FGF8-expanded cells or control cells (P<0.05 for both). Grafts of FGF2-expanded cells also contained significantly more TH-ir cells than grafts of FGF8-expanded cells (P<0.05) or control cells (P<0.01). In conclusion, FGF2-mediated pregrafting expansion of primary VM precursor cells considerably improves dopaminergic cell survival and functional restoration in a rat model of PD.

Comparison of mesencephalic free-floating tissue culture grafts and cell suspension grafts in the 6-hydroxydopamine-lesioned rat

Ventral mesencephalon (VM) of fetal rat and human origin grown as free-floating roller-tube (FFRT) cultures can survive subsequent grafting to the adult rat striatum. To further explore the functional efficacy of such grafts, embryonic day 13 ventral mesencephalic tissue was grafted either after 7 days in culture or directly as dissociated cell suspensions, and compared with regard to neuronal survival and ability to normalize rotational behavior in adult rats with unilateral 6-hydroxydopamine (6-OHDA) lesions. Other lesioned rats received injections of cell-free medium and served as controls. The amphetamine-induced rotational behavior of all 6-OHDA-lesioned animals was monitored at various time points from 18 days before transplantation and up to 80 days after transplantation. Tyrosine hydroxylase (TH) immunostaining of the histologically processed brains served to assess the long-term survival of grafted dopaminergic neurons and to correlate that with the behavioral effects. Additional cultures and acutely prepared explants were also fixed and stored for histological investigation in order to estimate the loss of dopaminergic neurons in culture and after transplantation. Similar behavioral improvements in terms of significant reductions in amphetamine-induced rotations were observed in rats grafted with FFRT cultures (127%) and rats grafted with cell suspensions (122%), while control animals showed no normalization of rotational behavior. At 84 days after transplantation, there were similar numbers of TH-immunoreactive (TH-ir) neurons in grafts of cultured tissue (775 +/- 98, mean +/- SEM) and grafts of fresh, dissociated cell suspension (806 +/- 105, mean +/- SEM). Cell counts in fresh explants, 7-day-old cultures, and grafted cultures revealed a 68.2% loss of TH-ir cells 7 days after explantation, with an additional 23.1% loss after grafting, leaving 8.7% of the original number of TH-ir cells in the intracerebral grafts. This is to be compared with a survival rate of 9.1% for the TH-ir cells in the cell-suspension grafts. Immunostaining for the calcium-binding proteins calretinin, calbindin, and parvalbumin showed no differences in the neuronal expression of these proteins between the two graft types. In conclusion, we found comparable dopaminergic cell survival and functional effects of tissue-culture grafts and cell-suspension grafts, which currently is the type of graft most commonly used for experimental and clinical grafting. In this sense the result is promising for the development of an effective in vitro storage of fetal nigral tissue, which at the same time would allow neuroprotective and neurotrophic treatment prior to intracerebral transplantation.

Expression of trefoil factor 1 in the developing and adult rat ventral mesencephalon

Trefoil factor 1 (TFF1) belongs to a family of secreted peptides with a characteristic tree-looped trefoil structure. TFFs are mainly expressed in the gastrointestinal tract where they play a critical role in the function of the mucosal barrier. TFF1 has been suggested as a neuropeptide, but not much is known about its expression and function in the central nervous system. We investigated the expression of TFF1 in the developing and adult rat midbrain. In the adult ventral mesencephalon, TFF1-immunoreactive (-ir) cells were predominantly found in the substantia nigra pars compacta (SNc), the ventral tegmental area (VTA) and in periaqueductal areas. While around 90% of the TFF1-ir cells in the SNc co-expressed tyrosine hydroxylase (TH), only a subpopulation of the TH-ir neurons expressed TFF1. Some TFF1-ir cells in the SNc co-expressed the calcium-binding proteins calbindin or calretinin and nearly all were NeuN-ir confirming a neuronal phenotype, which was supported by lack of co-localization with the astroglial marker glial fibrillary acidic protein (GFAP). Interestingly, at postnatal (P) day 7 and P14, a significantly higher proportion of TH-ir neurons in the SNc co-expressed TFF1 as compared to P21. In contrast, the proportion of TFF1-ir cells expressing TH remained unchanged during postnatal development. Furthermore, significantly more TH-ir neurons expressed TFF1 in the SNc, compared to the VTA at all four time-points investigated. Injection of the tracer fluorogold into the striatum of adult rats resulted in retrograde labeling of several TFF1 expressing cells in the SNc showing that a significant fraction of the TFF1-ir cells were projection neurons. This was also reflected by unilateral loss of TFF1-ir cells in SNc of 6-hydroxylase-lesioned hemiparkinsonian rats. In conclusion, we show for the first time that distinct subpopulations of midbrain dopaminergic neurons express TFF1, and that this expression pattern is altered in a rat model of Parkinson's disease.

Localization and production of peptide endocannabinoids in the rodent CNS and adrenal medulla.

The endocannabinoid system (ECS) comprises the cannabinoid receptors CB1 and CB2 and their endogenous arachidonic acid-derived agonists 2-arachidonoyl glycerol and anandamide, which play important neuromodulatory roles. Recently, a novel class of negative allosteric CB1 receptor peptide ligands, hemopressin-like peptides derived from alpha hemoglobin, has been described, with yet unknown origin and function in the CNS. Using monoclonal antibodies we now identified the localization of RVD-hemopressin (pepcan-12) and N-terminally extended peptide endocannabinoids (pepcans) in the CNS and determined their neuronal origin. Immunohistochemical analyses in rodents revealed distinctive and specific staining in major groups of noradrenergic neurons, including the locus coeruleus (LC), A1, A5 and A7 neurons, which appear to be major sites of production/release in the CNS. No staining was detected in dopaminergic neurons. Peptidergic axons were seen throughout the brain (notably hippocampus and cerebral cortex) and spinal cord, indicative of anterograde axonal transport of pepcans. Intriguingly, the chromaffin cells in the adrenal medulla were also strongly stained for pepcans. We found specific co-expression of pepcans with galanin, both in the LC and adrenal gland. Using LC-MS/MS, pepcan-12 was only detected in non-perfused brain (∼40 pmol/g), suggesting that in the CNS it is secreted and present in extracellular compartments. In adrenal glands, significantly more pepcan-12 (400-700 pmol/g) was measured in both non-perfused and perfused tissue. Thus, chromaffin cells may be a major production site of pepcan-12 found in blood. These data uncover important areas of peptide endocannabinoid occurrence with exclusive noradrenergic immunohistochemical staining, opening new doors to investigate their potential physiological function in the ECS. This article is part of a Special Issue entitled 'Fluorescent Neuro-Ligands'.

Characterization of fetal antigen 1/delta-like 1 homologue expressing cells in the rat nigrostriatal system: effects of a unilateral 6-hydroxydopamine lesion.

Fetal antigen 1/delta-like 1 homologue (FA1/dlk1) belongs to the epidermal growth factor superfamily and is considered to be a non-canonical ligand for the Notch receptor. Interactions between Notch and its ligands are crucial for the development of various tissues. Moreover, FA1/dlk1 has been suggested as a potential supplementary marker of dopaminergic neurons. The present study aimed at investigating the distribution of FA1/dlk1-immunoreactive (-ir) cells in the early postnatal and adult midbrain as well as in the nigrostriatal system of 6-hydroxydopamine (6-OHDA)-lesioned hemiparkinsonian adult rats. FA1/dlk1-ir cells were predominantly distributed in the substantia nigra (SN) pars compacta (SNc) and in the ventral tegmental area. Interestingly, the expression of FA1/dlk1 significantly increased in tyrosine hydroxylase (TH)-ir cells during early postnatal development. Co-localization and tracing studies demonstrated that FA1/dlk1-ir cells in the SNc were nigrostriatal dopaminergic neurons, and unilateral 6-OHDA lesions resulted in loss of both FA1/dlk1-ir and TH-ir cells in the SNc. Surprisingly, increased numbers of FA1/dlk1-ir cells (by 70%) were detected in dopamine-depleted striata as compared to unlesioned controls. The higher number of FA1/dlk1-ir cells was likely not due to neurogenesis as colocalization studies for proliferation markers were negative. This suggests that FA1/dlk1 was up-regulated in intrinsic cells in response to the 6-OHDA-mediated loss of FA1/dlk1-expressing SNc dopaminergic neurons and/or due to the stab wound. Our findings hint to a significant role of FA1/dlk1 in the SNc during early postnatal development. The differential expression of FA1/dlk1 in the SNc and the striatum of dopamine-depleted rats could indicate a potential involvement of FA1/dlk1 in the cellular response to the degenerative processes.