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Transcranial magnetic stimulation (TMS) is a non-invasive technique which can be used to study different intracortical excitatory and inhibitory neuronal circuits in the intact human being. In the primary motor cortex, there are essentially three different TMS measures of inhibitory neuronal circuits as determined by paired-pulse TMS: short-interval intracortical inhibition (SICI), long-interval intracortical inhibition (LICI) and interhemispheric inhibition (IHI). It was hypothesized that SICI is a GABAA receptor mediated inhibition (Ilic et al., 2002) whereas LICI and IHI are mediated by GABAB receptors (Daskalakis et al., 2002; McDonnell et al., 2006). Additionally, it was shown that these inhibitory circuits interact negatively, possible due to presynaptic GABAB receptor mediated inhibition (Sanger et al., 2001; Daskalakis et al., 2002). Which neuronal populations exactly underlie SICI, LICI and IHI, is not completely clear and by which mechanism these inhibitory circuits interact has never been tested pharmacologically so far. Thus, the effects of a single oral dose of Diazepam (DZP), a specific positive allosteric modulator at the GABAA receptor, and of Baclofen (BAC), a specific GABAB receptor agonist, on SICI, LICI and IHI as well as their interactions were tested here in a randomized, placebo controlled, double-blinded crossover study. SICI significantly increased after intake of DZP whereas BAC did not change SICI. Conversely, LICI significantly increased after intake of BAC but did not change after intake of DZP. IHI showed only a trend towards a decrease after intake of DZP but no change after intake of BAC. The interactions IHI-SICI, LICI-IHI and LICI-SICI were all negative at baseline. SICI and IHI were partially suppressed in the presence of IHI and LICI, respectively, and SICI in the presence of LICI was almost completely blocked. BAC did not change any of these interactions, whereas DZP significantly increased SICI in the presence of LICI. This study is the first to examine by means of pharmacological testing the complex interactions between different inhibitory circuits in the human motor cortex. The effects of DZP and BAC on SICI and LICI confirmed the notion that SICI is a GABAA receptor mediated intracortical inhibition whereas LICI depends on GABAB receptor mediated neurotransmission. The pharmacology of IHI at short interstimulus intervals of < 20 ms (12 ms in this study) remains still inconclusive and warrants further investigation. Findings further suggest that SICI, LICI and IHI represent three different inhibitory neuronal circuits which can be tested non-invasively by means of paired-pulse TMS. Furthermore, the data support the idea that the negative interactions IHI-SICI, LICI-IHI and LICI-SICI are most likely due to presynaptic GABAB receptor mediated autoinhibition.
Prostaglandin D2 (PGD2) is involved in a variety of physiological and pathophysiological processes, but its role in fever is poorly understood and the data obtained so far are rather controversial. Here we investigated the effects of central PGD2 delivery and of systemic prostaglandin D synthase (PGDS) or cyclooxygenase (COX) inhibition on core body temperature (TC) and on prostaglandin levels in the cerebrospinal fluid (CSF) of rats. Both PGE2 and PGD2 were detectable in CSF samples from control rats (6.2 ± 1.1 and 17.3 ± 3.1 pg/ml, respectively). Lipopolysaccharide (LPS) injection (50 μg i.p.) induced fever during the 5-hour observation period. Five hours after LPS injection, the levels of PGE2 and PGD2 were increased in the CSF about 90-fold (541.0 ± 47.5 pg/ml) and 5-fold (95.4 ± 23.1 pg/ml), respectively. Administration of PGD2 (50 - 500 ng) into the cisterna magna (i.c.m) evoked a delayed fever response in a dose-dependent manner that was accompanied by increased levels of PGE2 in the CSF. RT-PCR analyses revealed that the increased levels of PGE2 after PGD2 administration were not caused by up-regulation of COX-2 or microsomal prostaglandin E synthase 1 (mPGES-1) in the hypothalamus. Interestingly, i.c.m. pretreatment of animals with PGD2 considerably sustained the pyrogenic effects of i.c.m. administered PGE2. Pretreatment with a novel PGDS inhibitor, EDJ300520 (10 – 40 mg/kg p.o.), 1 h prior to the LPS injection impaired the LPS-induced increase of both PGD2 and PGE2 in the CSF and inhibited the fever response. In contrast, administration of EDJ300520 3 h after LPS injection did not ameliorate the LPS-induced fever. Accordingly, the concentration of PGE2 in the CSF was not decreased after EDJ300520 treatment. However, the CSF levels of PGD2 were reduced after administration of a high dose of EDJ300520 (40 mg/kg). We also investigated the effects of antipyretic drugs on the CSF levels of PGE2 and PGD2 during LPS-induced fever. Four antipyretic drugs with different mechanisms of action were used, including ibuprofen (5 - 20 mg/kg), celecoxib (10 - 50 mg/kg), SC560 5 - 20 mg/kg), and paracetamol (50 - 150 mg/kg). Each drug was used in three different doses and was orally administered 3 h after the LPS injection. All drugs were capable to attenuate the LPS-induced fever. The decrease of TC paralleled the reduction of PGE2 levels in the CSF. Of note, there was a tendency to reduced PGD2 levels in the CSF after treatment with the antipyretic drugs. However, only SC560 and the high dose of celecoxib (50 mg/kg) reduced the PGD2 levels significantly. In summary, our experiments underscore the pivotal role of PGE2 as the principal downstream mediator of fever. Moreover, we demonstrate that PGD2 is also involved in the mechanisms underlying fever. Our data suggest that PGD2 exerts an indirect pyrogenic effect by modulating the availability of PGE2 in the CSF. Additional studies are needed to explore the exact mechanism by
Spontaneous carotid artery dissection-associated medial changes in a selected autopsy population
(2006)
Spontaneous carotid artery dissection (SCAD) is a major cause of stroke in young adults, yet its pathogenesis remains unclear. Hereditary connective tissue diseases, hormonal influences, sympathomimetic drugs or upper respiratory tract infections may predispose to dissection. Mechanical stress or minimal trauma may also act as a trigger. Various lesions of the arterial wall have been described in association with SCAD, but no prospective autopsy study to evaluate the presence of these lesions in normal controls was found. We performed a histologic evaluation of the carotid bifurcation and the aortic arch in an autopsy series to establish a baseline anatomy of the bifurcation and to determine whether similar lesions could be observed. In seven of 54 (12.96%) selected cases we observed isolated changes closely resembling those described for medionecrosis, fibromuscular dysplasia, mucoid degeneration and elastinolysis; and in one case, prior carotid artery dissection and coiling with a patent false lumen. Generally, vascular microanatomy in the carotid bifurcation can be highly variable. Lesions similar to those associated with spontaneous dissection are present in controls and appear non-specific for spontaneous dissection. They can be explained as reactive changes of smooth muscle cells (SMC) and the vascular wall in response to various stressors. Recent advances in vascular physiology are discussed to illustrate the concept of SMC phenotypic modulation. Forensic pathology can provide a large control population for extensive vascular analyses and further the understanding of normal and pathological vascular wall changes to help elucidate spontaneous arterial dissection.
Background: False aneurysms at the puncture site develop in up to 8 % after catheter procedures. They can be treated surgically or by ultrasound guided manual compression. A new method is to inject thrombin into the aneurysm under ultrasound guidance. We evaluated safety and efficacy of this approach in a multicenter registry. Methods: In 595 consecutive patients (age: 31-94 years, median 70) a pseudoaneurysm (593 femoral arteries, 2 brachial arteries) was diagnosed 0 to 250 days (median 3 days) after a catheter procedure. The diameter of the aneurysm ranged from 0.5 x 0.5 x 0.5 (L x W x D) to 8x11x16 cm (median 2 x 2 x1.6 cm). 20 U to 4000 U of thrombin solution (median 400 U) were injected percutaneously into the aneurysm under ultrasound guidance. Results: The procedure was technically successful in 587/595 (99%) patients. The aneurysms were thrombosed after the first injection in 531 patients (89 %). Thirty-eight (6%) patients needed a second injection and 8 (1%) patients a third injection because residual flow in the aneurysm was visible at follow-up. In 4 additional patients (0.7%) the thrombosis of the aneurysms was delayed and occurred only after 24 hours to 7 days. 6 (1%) patients surgery was performed after successful closure of the aneurysm to remove the resulting haematoma. The overall technical success rate was 99% (587/595) and clinical success was achieved in 572/595 (96%) patients. Eight (1%) other patients underwent surgery due to thrombin injection failure. Complications occurred in 9 patients (1.5%): Intravascular thrombus formation (n=3), deep venous thrombosis (n=3), pulmonary embolism due to deep venous thrombosis (n=1), transient paresthesia in the leg during injection (n=3). Conclusion: Ultrasound guided thrombin injection is a safe, painless, effective and rapid alternative to treat false aneurysms. Complications and recurrent pseudoaneurysms are very rare. It has become the treatment of choice in our institution.
IL-12-related cytokines produced by dendritic cells are considered to be major inducers of adaptive immune system activation upon innate antigen-sensing. IL-23 specifically is currently being discussed to support the differentiation of potentially auto-aggressive Th17 cells. Prostaglandins as bystander cell products are known to modulate the translation of this process. While previous studies focused therefore on IL-12, ignoring the existence of new IL-12-related cytokines IL-23 and IL-27, this study analysed effects of prostaglandin E2, D2 and 15d-PGJ2 on the secretion pattern of these subunits in the murine immature Langerhans cell line XS52 and the murine immature myeloid dendritic cell line JawsII under TLR4 (LPS) and TLR9 (CpG) stimulation as well as effects of prostaglandins on the murine Th1 cell line IF12 in coculture and upon Con A treatment. In serial semi-quantitative RT-PCR of the IL-12 related cytokines of the XS52 cell line and the JawsII cell line, the p40 subunit was upregulated in both DC cell lines upon TLR-stimulation, the IL-23p19 subunit constantly expressed in XS52 and upregulated in JawsII upon TLR-stimulation, while the IL-27p28 subunit was only weekly expressed under additional stimulating aCD40 Ab treatment. IL-12p35 could only be detected in the immature myeloid cell line. The protein expression of the p40 subunit was measured in Western blot assays following SDS-PAGE under reducing conditions in XS52. The Western blot-based antibody specification allowed the establishment of a p40-specific ELISPOT assays, where overadditive upregulation of the number of LPS-stimulated spot forming XS52 cells was observed under stimulation with PGE2 while PGD2 depressed the number of LPS-stimulated cytokine secreting cells. Contrary IL-12p40 could not be detected in supernatants of the JawsII cell line. Both DC cell lines were further tested for differential response towards different TLR stimulation described as a defining feature of DC subsets. While subunit expression on transcription level did not differ, only LPS-treatment led to constant IL-12p40 expression in supernatants of XS52. CpG-treatment of XS52 cells led to constantly high IL-12p40 levels under additional aCD40 Ab treatment. In IFN-g ELISPOT assays, prostaglandin effects were further analysed in IF12 Th1 cells upon Con A treatment or alternatively upon treatment in a coculture model with the syngeneic cell line XS52 and the T lymphocyte-specific protein ovalbumin. While PGE2 depressed the amount of activated Th1, PGD2 showed no effect. In conclusion, a coculture model has been generated that allows the analysis of DC and TC interactions. The importance of prostaglandins as differential regulators in time- and tissue-dependence in inflammatory processes has been demonstrated. These results accord with recent observations of an upregulation of IL-23 secretion upon PGE2 treatment.
Molecular mechanism of intracellular signal transduction by the angiotensin-converting enzyme
(2007)
The angiotensin converting enzyme (ACE) is an important component of the renin-angiotensin system (RAS) and is crucially involved in the homeostasis of fluid and electrolyte balance and thus in the regulation of blood pressure. The zinc metallopeptidase is involved in the generation of angiotensin II, a potent vasoconstrictor and in the degradation of bradykinin, a potent vasodilator. It is worth noting that ACE more readily hydrolyzes bradykinin than it does angiotensin I thus culminating in the net physiological effect of the production of a vasoconstrictor and the decrease in the availability of a vasodilator. ACE inhibitors have become one of the most successful therapeutic approaches as a first line of therapy in hypertension, and are also widely used in treating heart failure, myocardial infarction, stroke, coronary artery disease and impaired left ventricular function. However, one unexpected clinically relevant finding related to ACE inhibitors is their ability to delay the onset of type II diabetes that was revealed by various large clinical trials. However, the mechanisms underlying these beneficial effects of ACE inhibitor therapy are currently unclear and cannot be explained by the prevention of angiotensin II formation or the attenuated degradation of bradykinin. Thus the potential beneficial effects attributed to ACE inhibitors may occur independent of reductions in blood pressure paving way for new and/or unknown mechanism. Our group has recently redefined ACE as a signal transduction molecule which upon binding to ACE inhibitor turns on a signalling cascade leading to phosphorylation of Ser1270 by CK2, activation of JNK and changes in gene expression in endothelial cells. However the mechanism by which ACE inhibitor initiates the signalling cascade was not clear. It was hypothesized that ACE, which is anchored to the membrane with a single transmembrane domain should dimerize prior to initiating further downstream signalling events in endothelial cells. Therefore, we sought to explore whether or not ACE forms dimers in endothelial cells and whether ACE dimerization is essential for the initiation of ACE signalling in endothelial cells. Using native gel electrophoresis, we found that ACE forms dimers in endothelial cells and that there is an increase in the dimer formation upon treatment of endothelial cells with ACE inhibitors. ACE homodimerization was also demonstrated using the split-ubiquitin system and chemical cross-linking experiments. ACE dimers are also formed in endothelial cells overexpressing the non-phosphorylatable ACE, wherein ACE signalling was abolished indicating that dimerization process is not influenced by the phosphorylation of the serine residue residing in the cytoplasmic tail. Monosaccharides like glucose, galactose and mannitol did not have any influence on ACE-inhibitor induced dimerization. Making use of different monoclonal antibodies directed to the epitopes of N-domain which harbours carbohydrate recognizing domain, also did not affect dimerization. However, inactivation of the C-domain active site by introducing mutation of the key histidine residues in HEMGH consensus sequences, which complexes the zinc ions, abolished enzyme dimerization both in the basal state and in response to ramiprilat. Mutation of the C-domain also resulted in the loss of ACE inhibitor-induced ACE signalling, that is we failed to observe ramiprilat-induced increase in the phosphorylation of the Ser1270 and the subsequent JNK activation. ACE-inhibitor induced dimerization precedes the phosphorylation of Ser1270 and activation of JNK. Thus the ACE-inhibitor induced dimerization via the C-domain of ACE represents the initial step in the ACE signalling pathway which involves the activation of JNK/c-Jun pathway and leading to the changes in the gene expression in endothelial cells. Our group previously identified ACE itself as well as cyclooxygenase-2 (COX-2) as two “ACE signalling-regulated” genes. To screen for additional genes regulated in a similar manner we used DNA microarray technology, to assess ramiprilat-induced changes in the endothelial cell gene expression. 21 genes were identified to be differentially regulated of which, 7 were upregulated and 14 were downregulated by ramiprilat. However, when screened at the protein level, we found no significant differences between the untreated control cells and those treated with ramiprilat. As several other cells and tissues possess a fully functional RAS we screened plasma samples from healthy volunteers as well as from patients with coronary artery disease for the proteins identified in the microarray. We observed that the cellular retinal binding protein-1 (CRBP-1) was detectable at low levels in plasma from patients and that ramipril markedly increased serum levels of this protein. Endothelial cells overexpressing CRBP-1 demonstrated increased RXRE and PPRE activity when stimulated with 9-cis retinoic acid and rosiglitazone respectively suggesting that CRBP-1 might affect gene expression via heterodimerization of PPAR elements with RXR elements by virtue of its function as a transport protein of retinoic acid. Studies aimed at determining the consequences of elevated CRBP-1 expression on endothelial cell homeostasis are ongoing. Although the RAS has been described in many other tissues apart from endothelial cells, ACE signalling has not yet been addressed in tissues such as monocytes/macrophages, which have an increased ACE expression in an atherosclerotic setting. We observed that upon stimulation of cultured ACE expressing monocytes with ramiprilat, JNK is activated suggesting the occurrence of ACE signalling in human monocytes. It is worth noting that ACE inhibitors delay the onset of type II diabetes in spite of moderate decrease in blood pressure. To further elucidate the mechanism underlying this effect, we found that ACE inhibitors increase the PPARgamma levels in the nuclear extracts of ACE expressing monocytes which were also reproduced in human endothelial cells overexpressing human somatic ACE. However, ramiprilat did not have any direct effect on the activity of a luciferase-coupled promoter containing several copies of the PPRE in human endothelial cells. These results contrasted with the actions of the PPARgamma agonist suggesting that ramiprilat enhances PPARgamma levels through an indirect mechanism. We next hypothesized that ramiprilat might increase the levels of 15-deoxy-D12,14-prostaglandin J2 (15dPGJ2) which is a natural ligand for PPARgamma via COX enzymes in monocytes. We observed that ramiprilat was able to decrease the diminution of COX-2 levels upto 48 hours of treatment but the levels of 15dPGJ2 were too low to be detected by ELISA. However ramiprilat enhanced the plasma levels of adiponectin, a downstream target of PPARgamma, which is a anti-atherogenic and anti-inflammatory adipokine, in patients with coronary artery disease. Though adiponectin is a PPARgamma-regulated gene, the observed increase in adiponectin might be attributed to the increase in RXR rather than via PPARgamma. Taken together, the results of this investigation have revealed that ACE inhibitors initiate ACE signalling by eliciting the dimerization of the enzyme, more specifically via its C-domain active centers. The ACE signalling cascade when activated leads to the enhanced expression of ACE, COX-2 and CRBP-1 which in turn favours the heterodimerization of PPARgamma with RXR and thus results in the increased expression of “PPARgamma regulated” genes such as adiponectin. The latter results provide a molecular basis for the observation that ACE inhibitors can delay the onset of type 2 diabetes in as much as it was possible to link ramipril with CRBP-1, RXR activity and the expression of adiponectin, an adipokine associated with improved insulin sensitivity. Further work is however required to elucidate the consequences of ACE inhibitors in monocytes and adipocytes as well as in intact animals.
All living organisms exhibit daily fluctuations in biochemical, physiological and behavioural parameters driven by endogenous oscillators, residing in the organism itself. In mammals, the core circadian oscillator is located in the paired suprachiasmatic nuclei (SCN) of the hypothalamus. Circadian rhythm generation in the SCN depends upon the expression of clock genes interacting in positive and negative transcriptional/translational feedback loops. The SCN governs the timing of peripheral circadian oscillators by neuronal pathways and by neuroendocrine mechanisms. An important neuroendocrine hand of the core circadian oscillator is melatonin, which is produced in and secreted from the pineal gland night by night. The adenohypophysis represents a peripheral circadian oscillator and the secretion of one of its hormones, prolactin, is known to be regulated by melatonin. The aim of the present study was to analyze a putative influence of melatonin on the activity state and diurnal variations of identified cell types in the hypophysis. Particular attention was paid to lactotroph, gonadotroph and pars intermedia cells. Experiments were performed with young male mice of different strains: melatonin-proficient C3H, melatonin-deficient C57BL, melatonin-proficient C3H with targeted deletions of the Mel1a receptor (MelaaBB), Mel1b receptor (MelAAbb) or both receptors (Melaabb). Cells producing prolactin (PRL), follicle stimulating hormone (FSH) were immunocytochemically identified and the presence of phosphorylated CREB protein (pCREB) and clock gene protein PER1 was demonstrated by double immunolabeling at different time points during the light/dark cycle in melatonin deficient, melatonin proficient and melatonin receptor knockout mice. Melatonin influence on Prl mRNA levels was investigated by means of in situ hybridization. At night the percentage of lactotroph cells showing a positive nuclear pCREB- and PER1-immunoreaction is significantly smaller in C57BL than in C3H mice. In both mouse strains, the percentage of pCREB –immunoreactive cells is minimal in the early morning and gradually increases to reach a maximum in the late night. PER1 levels show a parallel temporal variation in C3H, but in C57BL, they are drastically reduced in the early afternoon. The percentage of FSH-immunoreactive cells showing pCREB immunoreaction was significantly lower in the melatonin-deficient C57Bl mice than in the melatonin-proficient C3H mice during the second part of the day and during the night. In each strain, the percentage of FSH-immunoreactive cells was lowest at the early morning and gradually increases until the maximum at late night. In wild type (MelAABB) and MelAAbb mice the percentage of lactotroph cells with nuclear pCREB immunoreactions varied significantly over 24 h period, whereas in MelaaBB and Melaabb mice no significant differences were found between the five time points analyzed. The number of Prl mRNA expressing cells was significantly higher in MelaaBB and MelAAbb than in their wild type (MelAABB) littermates. pCREB levels in the pars intermedia did not show rhythmic variation in wild type or Melaabb animals, but wild type mice had higher pCREB levels than Melaabb. The observation that, during darkness, the percentage of lactotroph cells with nuclear pCREB immunoreaction is significantly higher in C3H than in C57BL mice suggests the existence of a distinct cell population that is under the control of melatonin-dependent intrapituitary signaling. Results with melatonin receptor knockout mice indicate that Mel1a and Mel1b melatonin receptors are involved in the control of the activity state of lactotroph cells, but to a differing degree. Analysis of cells expressing Prl mRNA showed that inhibitory action on the Prl expression is mostly mediated through the Mel1a receptor. The significant difference between pCREB immunoreaction in gonadotroph cells of C3H and C57BL mice might suggest that, like lactotrophes, FSH cells represent a heterogeneous population and only a subpopulation is under control of melatonin signaling. The present study is first to show that melatonin signaling also affects pCREB levels in pars intermedia of mice.
To determine the effects of inhaled IL-10 at different doses and different time points on the pulmonary and systemic inflammatory response during endotoxemia, 48 ventilated, anaesthetized rats (mean body weight ± standard deviation, 500 ± 33g) were randomly assigned to six groups (n = 8, each). Interleukin-10 was nebulised either prior to or following the intravenous injection of LPS (5mg/kg) at two doses (5.0 mycro-g or 0.5 mycro-g) in our groups. Eight rats received the same insult with no further treatment (LPS-only group). Another eight rats served as controls without endotoxemia but with aerosolized phosphate-buffered saline, the solvent of IL-10 (Sham group). Concentrations of TNF-alpha, IL-1beta, IL-6, and IFN-gamma were analyzed in plasma and bronchoalveolar lavage fluid (BALF). In addition, the nitrite release from ex-vivo cultured alveolar macrophages was determined. As compared to the LPS-only group, the concentrations of the proinflammatory cytokines TNF-alpha, IL-1beta, IL-6, and IFN-gamma in plasma were significantly reduced in the group, which inhaled 5 mycro-g IL-10 before LPS injection (p< 0.0125). Spontaneous nitrite release from exvivo cultured alveolar macrophages was suppressed in this group (p< 0.0125). Inhalation of 0.5 mycro-g IL-10 before LPS injection and both dosages of IL-10 inhalation (5 mycro-g or 0.5 mycro-g) after LPS injection did not significantly influence either inflammatory cytokine concentrations in BALF, in plasma or the nitrite release from ex-vivo cultured alveolar macrophages. In this study, inhaled IL-10 only demonstrated anti-inflammatory effects when it was administered at 5 mycro-g prior to the induction of experimental endotoxemia. Interleukin-10 aerosol had no effect when it was given either following induction of endotoxemia or given at a lower dosage (which here was 0.5 mycro-g) either before or following injection of lipopolysaccharide.
HELEX Septal Occluder for transcatheter closure of patent foramen ovale : multicenter experience
(2006)
Aims Patients with cryptogenic embolic events and a patent foramen ovale (PFO) are at risk of paradoxical embolism causing recurrent cerebral events; however, transcatheter PFO closure remains controversial. The aim of this multicenter trial was to demonstrate the feasibility and safety of transcatheter closure of PFO with the HELEX Septal Occluder. Methods and results The study enrolled 128 patients (66 female; mean age, 50 years). Mean (± SD) PFO size was 10±3.7 mm; 38 patients also had an atrial septal aneurysm. Device implantation was successful in 127 patients. Device-related events during implantation or follow-up were device embolisation, wire-frame fracture, and retrieval cord breaks (two cases each; no sequelae). Other adverse events included atrial arrhythmia (two patients), migraine, convulsion, and transient ischaemic attack (one case each). There were no recurrent strokes, deaths, perforations, or accumulations of thrombi on the device. Within a mean follow-up period of 21±11 months, complete PFO closure using one device was achieved in 114 patients (90%). Five patients with a moderate to large residual shunt received a second device. Conclusion The HELEX Occluder can be used for PFO closure. Device- and procedure-related complications are rare. The closure procedure appears to reduce recurrence rates of stroke and transient ischaemic attack.
The substantia nigra is not the induction site in the brain of the neurodegenerative process that underlies Parkinson’s disease. Instead, the results of this semiquantitative study of 30 autopsy cases with incidental Lewy body pathology indicate that Parkinson’s disease in the brain commences with the formation of the very first immunoreactive Lewy neurites and Lewy bodies in noncatecholaminergic visceromotor neurons of the dorsal glossopharyngeusvagus complex, in projection neurons of the intermediate reticular zone, and in specific nerve cell types of the gain setting system (coeruleussubcoeruleus complex, caudal raphe nuclei, gigantocellular reticular nucleus), olfactory bulb, olfactory tract, and/or anterior olfactory nucleus in the absence of nigral involvement. The topographical parcellation of the nuclear grays described here is based upon known architectonic analyses of the human brain stem and takes into consideration the pigmentation properties of a few highly susceptible nerve cell types involved in Parkinson’s disease. In this sample and in all 58 ageand gendermatched controls, Lewy bodies and Lewy neurites do not occur in any of the known telencephalic Parkinson’s disease predilection sites (hippocampal formation, temporal mesocortex, proneocortical cingulate areas, amygdala, basal nucleus of Meynert, interstitial nucleus of the diagonal band of Broca, hypothalamic tuberomamillary nucleus).