Stephen J. Kish

Bio: Stephen J. Kish is an academic researcher from Centre for Addiction and Mental Health. The author has contributed to research in topics: Dopamine & Putamen. The author has an hindex of 78, co-authored 282 publications receiving 19304 citations. Previous affiliations of Stephen J. Kish include Karolinska Institutet & University of Arizona.

Uneven pattern of dopamine loss in the striatum of patients with idiopathic Parkinson's disease. Pathophysiologic and clinical implications.

Abstract: Autografting of dopamine-producing adrenal medullary tissue to the striatal region of the brain is now being attempted in patients with Parkinson's disease. Since the success of this neurosurgical approach to dopamine-replacement therapy may depend on the selection of the most appropriate subregion of the striatum for implantation, we examined the pattern and degree of dopamine loss in striatum obtained at autopsy from eight patients with idiopathic Parkinson's disease. We found that in the putamen there was a nearly complete depletion of dopamine in all subdivisions, with the greatest reduction in the caudal portions (less than 1 percent of the dopamine remaining). In the caudate nucleus, the only subdivision with severe dopamine reduction was the most dorsal rostral part (4 percent of the dopamine remaining); the other subdivisions still had substantial levels of dopamine (up to approximately 40 percent of control levels). We propose that the motor deficits that are a constant and characteristic feature of idiopathic Parkinson's disease are for the most part a consequence of dopamine loss in the putamen, and that the dopamine-related caudate deficits (in "higher" cognitive functions) are, if present, less marked or restricted to discrete functions only. We conclude that the putamen--particularly its caudal portions--may be the most appropriate site for intrastriatal application of dopamine-producing autografts in patients with idiopathic Parkinson's disease.

Striatal dopamine nerve terminal markers in human, chronic methamphetamine users

Abstract: Methamphetamine is a drug that is significantly abused worldwide, Although long-lasting depletion of dopamine and other dopamine nerve terminal markers has been reported in striatum of nonhuman primates receiving very high doses of the psychostimulant, no information is available for humans. We found reduced levels of three dopamine nerve terminal markers (dopamine, tyrosine hydroxylase and the dopamine transporter) in post-mortem striatum (nucleus accumbens, caudate, putamen) of chronic methamphetamine users. However, levels of DOPA decarboxylase and the vesicular monoamine transporter, known to be reduced in Parkinson's disease, were normal. This suggests that chronic exposure to methamphetamine does not cause permanent degeneration of striatal dopamine nerve terminals at the doses used by the young subjects in our study. However, the dopamine reduction might explain some of the dysphoric effects of the drug, whereas the decreased dopamine transporter could provide the basis for dose escalation occurring in some methamphetamine users.

Frataxin is Reduced in Friedreich Ataxia Patients and is Associated with Mitochondrial Membranes

Abstract: Friedreich ataxia is a progressive neurodegenerative disorder caused by loss of function mutations in the frataxin gene. In order to unravel frataxin function we developed monoclonal antibodies raised against different regions of the protein. These antibodies detect a processed 18 kDa protein in various human and mouse tissues and cell lines that is severely reduced in Friedreich ataxia patients. By immunocytofluorescence and immunocytoelectron microscopy we show that frataxin is located in mitochondria, associated with the mitochondrial membranes and crests. Analysis of cellular localization of various truncated forms of frataxin expressed in cultured cells and evidence of removal of an N-terminal epitope during protein maturation demonstrated that the mitochondrial targetting sequence is encoded by the first 20 amino acids. Given the shared clinical features between Friedreich ataxia, vitamin E deficiency and some mitochondriopathies, our data suggest that a reduction in frataxin results in oxidative damage.

Brain cytochrome oxidase in Alzheimer's disease.

Abstract: A recent demonstration of markedly reduced (-50%) activity of cytochrome oxidase (CO; complex 4), the terminal enzyme of the mitochondrial enzyme transport chain, in platelets of patients with Alzheimer's disease (AD) suggested the possibility of a systemic and etiologically fundamental CO defect in AD To determine whether a CO deficiency occurs in AD brain, we measured the activity of CO in homogenates of autopsied brain regions of 19 patients with AD and 30 controls matched with respect to age, postmortem time, sex, and, as indices of agonal status, brain pH and lactic acid concentration Mean CO activity in AD brain was reduced in frontal (-26%: p less than 001), temporal (-17%; p less than 005), and parietal (-16%; not significant, p = 0055) cortices In occipital cortex and putamen, mean CO levels were normal, whereas in hippocampus, CO activity, on average, was nonsignificantly elevated (20%) The reduction of CO activity, which is tightly coupled to neuronal metabolic activity, could be explained by hypofunction of neurons, neuronal or mitochondrial loss, or possibly by a more primary, but region-specific, defect in the enzyme itself The absence of a CO activity reduction in all of the examined brain areas does not support the notion of a generalized brain CO abnormality Although the functional significance of a 16-26% cerebral cortical CO deficit in human brain is not known, a deficiency of this key energy-metabolizing enzyme could reduce energy stores and thereby contribute to the brain dysfunction and neurodegenerative processes in AD

Preferential loss of serotonin markers in caudate versus putamen in Parkinson's disease

Abstract: Interest in serotonergic involvement in Parkinson's disease (PD) has focussed recently on the possibility that the remaining serotonin neurons innervating striatum (caudate and putamen) might release dopamine as a 'false transmitter'--an action that could have both beneficial and harmful (e.g. promotion of levodopa-induced dyskinesias) consequences. Evidence for a brain serotonergic disturbance in PD is derived in large part from findings of decreased binding of different radioligands to the serotonin transporter (SERT), one 'marker' of serotonin neurons. However, it is not known whether the reported changes in SERT binding reflect actual changes in levels of SERT protein or whether concentrations of all serotonin markers are similarly and markedly decreased in the two striatal subdivisions. We measured levels of SERT immunoreactivity, and for comparison, protein levels of tryptophan hydroxylase (TPH; the marker synthetic enzyme) using a Western blot procedure, as well as concentrations of serotonin, its metabolite 5-hydroxyindoleacetic acid (5-HIAA), and dopamine by HPLC in post-mortem striatum of patients with PD and normal controls. Whereas concentrations of dopamine were severely decreased (caudate, -80%; putamen, -98%) and showed little (caudate) or no (putamen) overlap between individual control and patient values, levels of all four serotonin markers were less markedly reduced (-30% to -66%) with some patients having distinctly normal levels. Unlike the preferential loss of dopamine in putamen, the caudate was affected more than putamen by loss of all serotonin markers: serotonin (-66% versus -51%), 5-HIAA (-42% versus -31%), SERT (-56% versus -30%) and TPH (-59% versus -32%). Striatal serotonin concentration was similar in the subset of patients reported to have had dyskinesias versus those not reported to have had this drug complication. Previous findings of decreased SERT binding are likely explained by loss of SERT protein. Reduced striatal levels of all of the key serotonergic markers (neurotransmitter and metabolite, transporter protein, synthesizing enzyme protein) provide strong evidence for a serotonergic disturbance in PD, but with some patients affected much more than others. The more marked caudate reduction suggests that raphe neurons innervating this area are more susceptible to 'damage' than those innervating putamen and that any functional impairment caused by striatal serotonin loss might primarily involve the caudate. Questions related to the, as yet undetermined, clinical consequences in PD of a striatal serotonin deficiency (caudate: cognitive impairment?) and preservation (putamen: levodopa-induced dyskinesias?) should be addressed in prospective brain imaging and pharmacological studies.

α-Synuclein Locus Triplication Causes Parkinson's Disease

Abstract: Mutations in the α-synuclein gene ( SNCA ) in the Contursi kindred ([ 1 ][1]) implicated this gene in Parkinson's disease (PD). Subsequently, α-synuclein was identified as the major component of Lewy bodies, the pathological hallmark of PD, and of glial cell cytoplasmic inclusions ([ 2 ][2]). We

Ageing and parkinson's disease: substantia nigra regional selectivity

Abstract: The micro-architecture of the substantia nigra was studied in control cases of varying age and patients with parkinsonism. A single 7 mu section stained with haematoxylin and eosin was examined at a specific level within the caudal nigra using strict criteria. The pars compacta was divided into a ventral and a dorsal tier, and each tier was further subdivided into 3 regions. In 36 control cases there was a linear fallout of pigmented neurons with advancing age in the pars compacta of the caudal substantia nigra at a rate of 4.7% per decade. Regionally, the lateral ventral tier was relatively spared (2.1% loss per decade) compared with the medial ventral tier (5.4%) and the dorsal tier (6.9%). In 20 Parkinson's disease (PD) cases of varying disease duration there was an exponential loss of pigmented neurons with a 45% loss in the first decade. Regionally, the pattern was opposite to ageing. Loss was greatest in the lateral ventral tier (average loss 91%) followed by the medial ventral tier (71%) and the dorsal tier (56%). The presymptomatic phase of PD from the onset of neuronal loss was estimated to be about 5 yrs. This phase is represented by incidental Lewy body cases: individuals who die without clinical signs of PD or dementia, but who are found to have Lewy bodies at post-mortem. In 7 cases cell loss was confined to the lateral ventral tier (average loss 52%) congruent with the lateral ventral selectivity of symptomatic PD. It was calculated that at the onset of symptoms there was a 68% cell loss in the lateral ventral tier and a 48% loss in the caudal nigra as a whole. The regional selectivity of PD is relatively specific. In 15 cases of striatonigral degeneration the distribution of cell loss was similar, but the loss in the dorsal tier was greater than PD by 21%. In 14 cases of Steele-Richardson-Olszewski syndrome (SRO) there was no predilection for the lateral ventral tier, but a tendency to involve the medial nigra and spare the lateral. These findings suggest that age-related attrition of pigmented nigral cells is not an important factor in the pathogenesis of PD.

A Mitochondrial Paradigm of Metabolic and Degenerative Diseases, Aging, and Cancer: A Dawn for Evolutionary Medicine

Abstract: Life is the interplay between structure and energy, yet the role of energy deficiency in human disease has been poorly explored by modern medicine. Since the mitochondria use oxidative phosphorylation (OXPHOS) to convert dietary calories into usable energy, generating reactive oxygen species (ROS) as a toxic by-product, I hypothesize that mitochondrial dysfunction plays a central role in a wide range of age-related disorders and various forms of cancer. Because mitochondrial DNA (mtDNA) is present in thousands of copies per cell and encodes essential genes for energy production, I propose that the delayed-onset and progressive course of the agerelated diseases results from the accumulation of somatic mutations in the mtDNAs of post-mitotic tissues. The tissue-specific manifestations of these diseases may result from the varying energetic roles and needs of the different tissues. The variation in the individual and regional predisposition to degenerative diseases and cancer may result from the interaction of modern dietary caloric intake and ancient mitochondrial genetic polymorphisms. Therefore the mitochondria provide a direct link between our environment and our genes and the mtDNA variants that permitted our forbears to energetically adapt to their ancestral homes are influencing our health today.