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Enhanced Quinpirole Response in Rats Lesioned Neonatally With 5,7-DihydroxytryptamineBrus, Ryszard, Plech, Andrzej, Kostrzewa, Richard M. 01 January 1995 (has links)
The ontogenic destruction of dopamine (DA) neurons in rat brain is associated with supersensitization of DA D1 receptors. This effect is attenuated when rats are cotreated in ontogeny with the serotonin (5-HT) neurotoxin, 5,7-dihydroxytryptamine (5,7-DHT). In an attempt to determine whether 5-HT fibers might have a similar modulatory role on the sensitivity of the DA D2 receptor complex, we pretreated rats with desipramine HCl (20 mg/kg IP, base), 1 h before the DA neurotoxin, 6-hydroxydopamine (6-OHDA; 134 μg ICV, base) and/or 5,7-DHT (75 μg ICV) and/or vehicle. At about 3 months after birth dose-effect curves for quinpirole-induced oral activity were constructed for each group of rats. We found that quinpirole, an agonist for the DA D2 receptor complex, produced a dose-related increase in oral activity in all groups of rats. After a 200 μg/kg dose of quinpirole HCl, however, neonatal 5,7-DHT-lesioned rats had a peak oral response of 54.4 ± 5.1 (mean and SEM) vs. 22.6 ± 4.8 for control rats (p < 0.01). In neonatal 6-OHDA-lesioned rats this dose of quinpirole increased oral activity to 36.8 ± 5.8 oral movements (p < 0.05 vs. control). In rats lesioned with both 5,7-DHT and 6-OHDA, the oral response was not different from control. The enhanced oral response to quinpirole in 5,7-DHT-lesioned rats was attenuated by spiperone, an antagonist for the DA D2 receptor complex. These findings are believed to be the first to demonstrate that receptors of the DA D2 complex become sensitized after ontogenic injury to 5-HT fibers. This effect is opposite to the attenuated sensitivity of DA D1 receptors in rats with a similar 5-HT lesion.
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Proposed Animal Model of Attention Deficit Hyperactivity DisorderKostrzewa, Richard M., Brus, Ryszard, Kalbfleisch, John H., Perry, Ken W., Fuller, Ray W. 01 January 1994 (has links)
Dopamine (DA) neurons are implicated in the hyperlocomotion of neonatal 6-hydroxydopamine (6-OHDA)-lesioned rats, an animal model of attention deficit hyperactivity disorder (ADHD). Because serotonin (5-HT) neurons mediate some DA agonist effects, we investigated the possible role of 5-HT neurons on locomotor activity. Rats were treated at 3 days after birth with vehicle or 6-OHDA (134 μg ICV; desipramine pretreatment, 20 mg/kg IP, 1 h), and at 10 weeks with vehicle or 5,7-dihydroxytryptamine (5,7-DHT; 75 μg ICV; pretreatment with desipramine and pargyline, 75 mg/kg IP, 30 min), to destroy DA and/or 5-HT fibers. Intense spontaneous hyperlocomotor activity was produced in rats lesioned with both 6-OHDA and 5,7-DHT. Locomotor time in this group was 550 ± 17 s in a 600 s session, vs. 127 ± 13 s in the 6-OHDA group and <75 s in 5,7-DHT and intact control groups (p < 0.001). Oral activity dose-effect curves established that 5,7-DHT attenuated DA D1 receptor supersensitivity and further sensitized 5-HT2c receptors. Acute treatment with dextroamphetamine (0.25 mg/kg SC) reduced locomotor time in 6-OHDA+5,7-DHT-lesioned rats to 76 ± 37 s (p < 0.001). Striatal DA was reduced by 99% and 5-HT was reduced by 30% (vs. 6-OHDA group). Because combined 6-OHDA (to neonates) and 5,7-DHT (to adults) lesions produce intense hyperlocomotion that is attenuated by amphetamine, we propose this as a new animal model of ADHD. The findings suggest that hyperactivity in ADHD may be due to injury or impairment of both DA and 5-HT neurons.
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Amphetamine and mCPP Effects on Dopamine and Serotonin Striatal in Vivo Microdialysates in an Animal Model of HyperactivityNowak, Przemyslaw, Bortel, Aleksandra, Dabrowska, Joanna, Oswiecimska, Joanna, Drosik, Marzena, Kwiecinski, Adam, Opara, Józef, Kostrzewa, Richard M., Brus, Ryszard 01 December 2007 (has links)
In the neonatally 6-hydroxydopamine (6-OHDA)-lesioned rat hyperlocomotor activity, first described in the 1970s, was subsequently found to be increased by an additional lesion with 5,7-dihydroxytryptamine (5,7-DHT) (i.c.v.) in adulthood. The latter animal model (i.e., 134 μg 6-OHDA at 3 d postbirth plus 75 μg 5,7-DHT at 10 weeks; desipramine pretreatments) was used in this study, in an attempt to attribute hyperlocomotor attenuation by D,L-amphet-amine sulfate (AMPH) and m-chlorophenylpi-perazine di HCl (mCPP), to specific changes in extraneuronal (i.e., in vivo microdialysate) levels of dopamine (DA) and/or serotonin (5-HT). Despite the 98-99% reduction in striatal tissue content of DA, the baseline striatal microdialysate level of DA was reduced by 50% or less at 14 weeks, versus the intact control group. When challenged with AMPH (0.5 mg/kg), the microdialysate level of DA went either unchanged or was slightly reduced over the next 180 min (i.e., 20 min sampling), while in the vehicle group and 5,7-DHT (alone) lesioned group, the microdialysate level was maximally elevated by ∼225% and ∼450%, respectively - and over a span of nearly 2 h. Acute challenge with mCPP (1 mg/kg salt form) had little effect on microdialysate levels of DA, DOPAC and 5-HT. Moreover, there was no consistent change in the microdialysate levels of DA, DOPAC, and 5-HT between intact, 5-HT-lesioned rats, and DA-lesioned rats which might reasonably account for an attenuation of hyperlocomotor activity. These findings indicate that there are other important neurochemical changes produced by AMPH-and mCPP-attenuated hyperlocomotor activity, or perhaps a different brain region or multiple brain regional effects are involved in AMPH and mCPP behavioral actions.
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p-Chloroamphetamine-Enhanced Neostriatal Dopamine Exocytosis in Rats Neonatally Co-lesioned with 6-OHDA and 5,7-DHT: Relevance to Parkinson’s DiseaseKostrzewa, John P., Kostrzewa, Richard M. 01 March 2020 (has links)
Serotoninergic nerves are known to modulate sensitization of dopamine receptors (DA-R) in a rodent model of Parkinson’s disease (PD). However, serotoninergic nerves are not known to have a prominent role on DA exocytosis in intact rats. The current study was undertaken to explore the possible influence of serotoninergic nerves on DA exocytosis in Parkinsonian rats. Rat pups were treated at 3 days after birth with the neurotoxin 6-hydroxydopamine (6-OHDA; 134 μg icv, half into each lateral ventricle; desipramine, 1 h pretreatment), in order to produce marked long-lasting destruction of neostriatal dopaminergic innervation, as evidenced by the 90–95% depletion of DA (p < 0.001) [HPLC/ED] into adulthood. Controls received vehicle/desipramine in place of 6-OHDA. Other groups received the serotoninergic neurotoxin 5,7-dihydroxytryptamine (5,7-DHT; 25 μg base, icv, half in each lateral ventricle; desipramine, 1 h; 75 mg/kg pargyline HCl, 30 min) at 3 days post-birth; or both 6-OHDA+5,7-DHT treatments. In adulthood, an in vivo microdialysis study was undertaken to ascertain that p-chloroamphetamine (PCA, 1 mM in the microdialysate)-evoked DA release in the neostriatum was reduced approximately 50% in the 6-OHDA group, while PCA-evoked DA release in the 6-OHDA+5,7-DHT group was substantially increased, to a level equivalent to that of the vehicle control. The baseline neostriatal microdialysate level of 3,4-dihydroxyphenylacetic acid (DOPAC) was also higher in the 6-OHDA+5,7-DHT group vs 6-OHDA group; also, during the 2nd hour of PCA infusion. PCA-enhanced DA exocytosis occurred in the absence of changes in hydroxyl radical (HO·) in the microdialysate (i.e., assay of 2,3- and 2,5-dihydroxybenzoic acid, 2,3-DHBA; 2,5-DHBA). The overall findings demonstrate that an adulthood serotoninergic nerve lesion enhanced PCA-evoked DA exocytosis in a rodent model of severe PD, while susceptibility to oxidative stress was unchanged. The implication is that serotoninergic nerves may normally suppress the release of DA and/or act as an uptake site and storage sink for accumulated DA in parkinsonian-like neostriatum. Potentially, serotoninergic agonists or antagonists, targeting subtype-selective serotonin receptors, may be viable therapeutic adjuncts in PD.
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Serotoninergics Attenuate Hyperlocomotor Activity in Rats. Potential New Therapeutic Strategy for HyperactivityBrus, Ryszard, Nowak, Przemyslaw, Szkilnik, Ryszard, Mikolajun, Urszula, Kostrzewa, Richard M. 01 December 2004 (has links)
Hyperactivity is thought to be associated with an alteration of dopamine (DA) neurochemistry in brain. This conventional view became solidified on the basis of observed hyperactivity in DA-lesioned animals and effectiveness of the dopaminomimetics such as amphetamine (AMP) in abating hyperactivity in humans and in animal models of hyperactivity. However, because AMPreleases serotonin (5-HT) as well as DA, we investigated the potential role of 5-HT in an animal model of hyperactivity. We found that a greater intensity of hyperactivity was produced in rats when both DA and 5-HT neurons were damaged at appropriate times in ontogeny. Therefore, previously we proposed this as an animal model of attention deficit hyperactivity disorder (ADHD) - induced by destruction of dopaminergic neurons with 6-hydroxydopamine (6-OHDA (neonatally) and serotoninergic neurons with 5,7-dihydroxytryptamine (5,7-DHT) (in adulthood). In this model effects similar to that of AMP(attenuation of hyperlocomotion) were produced by m-chlorophenylpiperazine (m-CPP) but not by 1-phenylbiguanide (1-PG), respective 5-HT2 and 5-HT3 agonists. The effect of m-CPP was shown to be replicated by desipramine, and was largely attenuated by the 5-HT2 antagonist mianserin. These findings implicate 5-HT neurochemistry as potentially important therapeutic targets for treating human hyperactivity and possibly childhood ADHD.
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Stereotypic Progressions in Psychotic BehaviorKostrzewa, Richard M., Kostrzewa, John P., Kostrzewa, Rose Anna, Kostrzewa, Florence P., Brus, Ryszard, Nowak, Przemyslaw 01 February 2011 (has links)
Dopamine receptor supersensitivity (DARSS) often is invoked as a mechanism possibly underlying disordered thought processes and agitation states in psychiatric disorders. This review is focused on identified means for producing DARSS and associating the role of other monoaminergic systems in modulating DARSS. Dopamine (DA) receptors, experimentally, are prone to become supersensitive and to thus elicit abnormal behaviors when coupled with DA or a receptor agonist. In intact (control) rats repeated DA D1 agonist treatments fail to sensitize D1 receptors, while repeated D 2 agonist treatments sensitize D2 receptors. D2 RSS is attenuated by a lesion with DSP-4 (N-(2-chlorethyl)-N-ethyl-2- bromobenzylamine) in early postnatal ontogeny, indicating that noradrenergic nerves have a permissive effect on D2 DARSS. However, if DSP-4 is co-administered with 5,7-dihydroxytryptamine to destroy serotonin (5-HT) nerves, then D2 RSS is restored. In rats treated early in postnatal ontogeny with the neurotoxin 6-hydroxydopamine to largely destroy DA innervation of striatum, both repeated D1 and D2 agonists sensitize D1 receptors. 5-HT nerves appear to have a permissive effect on D1 DARSS, as a 5-HT lesion reduces the otherwise enhanced effect of a D1 agonist. The series of findings demonstrate that DARSS is able to be produced by repeated agonist treatments, albeit under different circumstances. The involvement of other neuronal phenotypes as modulators of DARSS provides the potential for targeting a variety of sites in the aim to prevent or attenuate DARSS. This therapeutic potential broadens the realm of approaches toward treating psychiatric disorders.
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NeurotoxinsKostrzewa, R. M. 01 January 2009 (has links)
A selective neurotoxin takes many forms: as an antibody to a neurotrophin, as an alkylator, as an excitotoxin, as a blocker of requisite neuronal excitation during ontogenetic development, as a generator of oxidative stress, as an inhibitor of vital intraneuronal processes, and as an agent adversely affecting a host of multiple sites in neurons. Neurotoxins have been invaluable for elucidating cellular mechanisms attending or preventing neuronal necrosis and apoptosis, and for modeling and thereby discerning mechanisms invoked in neurological and psychiatric disorders. Neuroprotectants, endogenous and exogenous, are being explored as potentially useful agents to ward off diseases. Finally, hypothesized as posing a risk to humans as environmental constituents, neurotoxins are now being remodeled as adjuncts for therapeutic intervention in a variety of human medical disorders.
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Tardive Dyskinesia: Outcome of Antipsychotic Treatment and Brain Damage?Kostrzewa, Richard M., Kostrzewa, John P., Brus, Ryszard 01 January 2014 (has links)
Tardive dyskinesia (TD), marked by abnormal involuntary movements and frequently expressed as perioral activity, represents an adverse outcome of prolonged antipsychotic therapy, occurring in approximately 5 % of patients per treatment year. Although neuronal mechanisms underlying TD are largely unknown, more recent experimental studies in animal models of TD are providing insight into the neuronal mechanisms associated with TD and implicating newer treatment approaches. It is now evident that a predominance in the ratio of dopamine (DA) D1:D2 receptor (R) activation accounts for induction of perioral movements in rodent models of TD, in nonhuman primate models of TD, and in humans with TD. Experimentally, TD is produced in animal models of TD, in a manner analogous to that by which TD is produced in humans - by continuous and prolonged administration of a DA D2R antagonist (i.e., an antipsychotic drug). More recently, in a rodent model of TD, it has been shown that a lesion of dopaminergic - mainly nigroneostriatal - neurons reduces the time latency for occurrence of TD, also increases the severity of perioral activity, and results in permanence of TD after complete removal of D2R antagonist treatment. The induction of perioral activity is related to DAR supersensitivity but unrelated to numbers of D2R and D2R in the neostriatum, a brain region associated with perioral activity. More apropos, serotoninergic systems are now recognized as having a greater role in effecting perioral activity, and it appears that 5-HT2C receptor antagonists are most effective in abating perioral activity in a rodent model of TD. These processes and mechanisms, topics addressed in this chapter, highlight a newer understanding of mechanisms underlying TD and provide insight into new approaches towards treatment of TD in humans.
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Neurotoxins and Neurotoxicity Mechanisms. An OverviewSegura-Aguilar, Juan, Kostrzewa, Richard M. 01 December 2006 (has links)
Neurotoxlns represent unique chemical tools, providing a means to 1) gain insight into cellular mechanisms of apopotosis and necrosis, 2) achieve a morphological template for studies otherwise unattainable, 3) specifically produce a singular phenotype of denervation, and 4) provide the starting point to delve into processes and mechanisms of nerve regeneration and sprouting. There are many other notable uses of neurotoxins in neuroscience research, and ever more being discovered each year. The objective of this review paper is to highlight the broad areas of neuroscience in which neurotoxins and neurotoxicity mechanism come into play. This shifts the focus away from neurotoxins per se, and onto the major problems under study today. Neurotoxins broadly defined are used to explore neurodegenerative disorders, psychiatric disorders and substance use disorders. Neurotoxic mechanisms relating to protein aggregates are indigenous to Alzheimer disease, Parkinson's disease. NeuroAIDS is a disorder in which microglia and macrophages have enormous import. The gap between the immune system and nervous system has been bridged, as neuroinflammation is now considered to be part of the neurodegenerative process. Related mechanisms now arise in the process of neurogenesis. Accordingly, the entire spectrum of neuroscience is within the purview of neurotoxins and neurotoxicity mechanisms. Highlights on discoveries in the areas noted, and on selective neurotoxins, are included, mainly from the past 2 to 3 years.
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Survey of Selective NeurotoxinsKostrzewa, Richard M. 01 January 2014 (has links)
There has been an awareness of nerve poisons from ancient times. At the dawn of the twentieth century, the actions and mechanisms of these poisons were uncovered by modern physiological and biochemical experimentation. However, the era of selective neurotoxins began with the pioneering studies of R. Levi-Montalcini through her studies of the neurotrophin "nerve growth factor" (NGF), a protein promoting growth and development of sensory and sympathetic noradrenergic nerves. An antibody to NGF, namely, anti-NGF - developed in the 1950s in a collaboration with S. Cohen - was shown to produce an "immunosympathectomy" and virtual lifelong sympathetic denervation. These Nobel Laureates thus developed and characterized the first identifiable selective neurotoxin. Other selective neurotoxins were soon discovered, and the compendium of selective neurotoxins continues to grow, so that today there are numerous selective neurotoxins, with the potential to destroy or produce dysfunction of a variety of phenotypic nerves. Selective neurotoxins are of value because of their ability to selectively destroy or disable a common group of nerves possessing (1) a particular neural transporter, (2) a unique set of enzymes or vesicular transporter, (3) a specific type of receptor or (4) membranous protein, or (5) other uniqueness. The era of selective neurotoxins has developed to such an extent that the very definition of a "selective" neurotoxin has warped. For example, (1) N-methyl-D- aspartate receptor (NMDA-R) antagonists, considered to be neuroprotectants by virtue of their prevention of excitotoxicity from glutamate receptor agonists, actually lead to the demise of populations of neurons with NMDA receptors, when administered during ontogenetic development. The mere lack of natural excitation of this nerve population, consequent to NMDA-R block, sends a message that these nerves are redundant - and an apoptotic cascade is set in motion to eliminate these nerves. (2) The rodenticide rotenone, a global cytotoxin that acts mainly to inhibit complex I in the respiratory transport chain, is now used in low dose over a period of weeks to months to produce relatively selective destruction of substantia nigra dopaminergic nerves and promote alpha-synuclein deposition in brain to thus model Parkinson's disease. Similarly, (3) glial toxins, affecting oligodendrocytes or other satellite cells, can lead to the damage or dysfunction of identifiable groups of neurons. Consequently, these toxins might also be considered as "selective neurotoxins," despite the fact that the targeted cell is nonneuronal. Likewise, (4) the dopamine D2-receptor agonist quinpirole, administered daily for a week or more, leads to development of D2-receptor supersensitivity - exaggerated responses to the D2-receptor agonist, an effect persisting lifelong. Thus, neuroprotectants can become "selective" neurotoxins; nonspecific cytotoxins can become classified as "selective" neurotoxins; and receptor agonists, under defined dosing conditions, can supersensitize and thus be classified as "selective" neurotoxins. More examples will be uncovered as the area of selective neurotoxins expands. The description and characterization of selective neurotoxins, with unmasking of their mechanisms of action, have led to a level of understanding of neuronal activity and reactivity that could not be understood by conventional physiological observations. This chapter will be useful as an introduction to the scope of the field of selective neurotoxins and provide insight for in-depth analysis in later chapters with full descriptions of selective neurotoxins.
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