Levodopa, fertility, and longevity

Transcriptomic and metabolomic analyses reveal that lemon extract prolongs Drosophila lifespan by affecting metabolism

Ageing is an evolutionarily conserved and irreversible biological process in different species. Numerous studies have reported that taking medicine is an effective approach to slow ageing. Lemon extract (LE) is a natural extract of lemon fruit that contains a variety of bioactive phytochemicals. Various forms of LE have been shown to play a role in anti-ageing and improving ageing-related diseases. However, studies on the molecular mechanism of LE in Drosophila ageing have not been reported. In this study, we found that 0.05 g/L LE could significantly extend Drosophila lifespan and greatly improve antioxidative and anti-heat stress abilities. Furthermore, transcriptome and metabolome analyses of 10 d flies between the LE-fed and control groups suggested that the differentially expressed gene ppo1 (Prophenoloxidase 1) and metabolite L-DOPA (Levodopa) were co-enriched in the tyrosine metabolism pathway. Overall, our results indicate that affecting metabolism was the main reason for LE extending Drosophila lifespan.

Carving the senescent phenotype by the chemical reactivity of catecholamines: An integrative review

Macromolecules damaged by covalent modifications produced by chemically reactive metabolites accumulate in the slowly renewable components of living bodies and compromise their functions. Among such metabolites, catecholamines (CA) are unique, compared with the ubiquitous oxygen, ROS, glucose and methylglyoxal, in that their high chemical reactivity is confined to a limited set of cell types, including the dopaminergic and noradrenergic neurons and their direct targets, which suffer from CA propensities for autoxidation yielding toxic quinones, and for Pictet-Spengler reactions with carbonyl-containing compounds, which yield mitochondrial toxins. The functions progressively compromised because of that include motor performance, cognition, reward-driven behaviors, emotional tuning, and the neuroendocrine control of reproduction. The phenotypic manifestations of the resulting disorders culminate in such conditions as Parkinson's and Alzheimer's diseases, hypertension, sarcopenia, and menopause. The reasons to suspect that CA play some special role in aging accumulated since early 1970-ies. Published reviews address the role of CA hazardousness in the development of specific aging-associated diseases. The present integrative review explores how the bizarre discrepancy between CA hazardousness and biological importance could have emerged in evolution, how much does the chemical reactivity of CA contribute to the senescent phenotype in mammals, and what can be done with it.

Degradation of Tyrosine Hydroxylase by the Ubiquitin-Proteasome System in the Pathogenesis of Parkinson's Disease and Dopa-Responsive Dystonia

Nigrostriatal dopaminergic systems govern physiological functions related to locomotion, and their dysfunction leads to movement disorders, such as Parkinson’s disease and dopa-responsive dystonia (Segawa disease). Previous studies revealed that expression of the gene encoding nigrostriatal tyrosine hydroxylase (TH), a rate-limiting enzyme of dopamine biosynthesis, is reduced in Parkinson’s disease and dopa-responsive dystonia; however, the mechanism of TH depletion in these disorders remains unclear. In this article, we review the molecular mechanism underlying the neurodegeneration process in dopamine-containing neurons and focus on the novel degradation pathway of TH through the ubiquitin-proteasome system to advance our understanding of the etiology of Parkinson’s disease and dopa-responsive dystonia. We also introduce the relation of α-synuclein propagation with the loss of TH protein in Parkinson’s disease as well as anticipate therapeutic targets and early diagnosis of these diseases.

L-DOPA in the hu man ovarian follicular fluid acts as an antioxidant factor on granulosa cells

BACKGROUND

A previous study showed that dopamine (DA), which is contained in follicular fluid (FF) from IVF patients, strongly increased the production of reactive oxygen species (ROS) by cultured human granulosa cells (GCs). ROS, including H₂O₂, are assumed to play roles in ovarian physiology and pathology. Ovarian DA could be derived from the circulation, ovarian innervation and/or unknown ovarian sources. L-DOPA is the direct precursor of DA in its synthetic pathway. It was not yet described in FF. We examined L-DOPA levels in FF from IVF patients. As it may exert anti-oxidative and ROS-scavenging functions, we studied whether it exerts such actions in human GCs and whether DOPA-decarboxylase (DDC), the enzyme converting L-DOPA to DA, is expressed in the human ovary.

RESULTS

ELISA measurements revealed that human IVF-derived FF contains L-DOPA. In cultured human GCs automated confluence analyses showed that L-DOPA enhanced their survival. This is in contrast to the actions of DA, which reduced cell survival. A dose-dependent mode of action of L-DOPA was identified using a fluorescent ROS indicator. The results showed that it antagonized intracellular ROS accumulation induced by exogenous H₂O₂. DDC was absent in follicular GCs, but immunohistochemistry identified it in theca cells (TCs) of large follicles in the human ovary. Laser micro-dissection followed by RT-PCR corroborated the expression. DDC was also identified in the steroidogenic cells of the corpus luteum.

CONCLUSIONS

L-DOPA in FF is an antioxidant factor and exerts positive influences on GCs. Ovarian DA is derived from L-DOPA and has opposite actions. Exogenous L-DOPA is a standard therapy for Parkinson's disease, and the results raise the possibility that it may be able to exert positive actions as an antioxidant in ovarian conditions, as well.

The sensory system: More than just a window to the external world

While the traditional importance of the sensory system lies in its ability to perceive external information about the world, emerging discoveries suggest that sensory perception has a greater impact on health and longevity than was previously appreciated. These effects are conserved across species. In this mini-review, we discuss the specific sensory cues that have been identified to significantly impact organismal physiology and lifespan. Ongoing work in the aging field has begun to identify the downstream molecules that mediate the broad effects of sensory signals. Candidates include FOXO, neuropeptide F (NPF), adipokinetic hormone (AKH), dopamine, serotonin, and octopamine. We then discuss the many implications that arise from our current understanding of the effects of sensory perception on health and longevity.

Four pioneers of L-dopa treatment: Arvid Carlsson, Oleh Hornykiewicz, George Cotzias, and Melvin Yahr

Four individuals stand out as pioneers of the early work that led to levodopa becoming a revolutionary new treatment for Parkinson's disease: Arvid Carlsson, Oleh Hornykiewicz, George C. Cotzias, and Melvin D. Yahr. All four were MDs. The first three had extra training in pharmacology, and in fact did their research in pharmacology. The fourth was a clinical neurologist, the only one in this group with those credentials. The story starts with Carlsson, who became interested in studying the mechanism of reserpine's sedative effect, now recognized as a drug-induced parkinsonian state. A key experiment in 1957 showed that levodopa (l-dopa) could alleviate the immobility induced by reserpine in animals. Carlsson then showed that reserpine depleted brain dopamine, and that l-dopa restored it. Carlsson developed a sensitive fluorescent technique to measure dopamine levels, and his laboratory also showed the distribution of dopamine in animal brain to be highest in the striatum. Within a year, Carlsson postulated that dopamine appears to play a role in motor function. His proposal that dopamine serves as a neurotransmitter in brain was met with much skepticism, but he persisted and continued to study brain dopamine, eventually leading to being awarded the Nobel Prize in Medicine in 2000. Hornykiewicz also went into pharmacology research after graduating from medical school. Fortuitously, his assigned first project was on the blood pressure effects of dopamine, recognized as a precursor of norepinephrine. When he completed his postdoctoral studies, Carlsson's work on the reserpinized animal and on the regional distribution of brain dopamine was published. This inspired Hornykiewicz to determine dopamine levels in patients with Parkinson's disease. He obtained postmortem material, and his 1960 paper showed a marked depletion of dopamine in the striatum in this disorder. He went on in subsequent papers to correlate severity of parkinsonian features with the amount of striatal dopamine depletion. In the meantime, after his discovery of low dopamine in brains of patients with Parkinson's disease, Hornykiewicz persuaded Walther Birkmayer to inject l-dopa into patients. They reported success and continued this treatment, usually combining it with the use of a monoamine oxidase inhibitor. However, the response was limited in duration, and subsequent trials by others were not achieving similar success, and many failed to find any benefit. The fulfilment of the l-dopa story stemmed from the hypothesis held by Cotzias that Parkinson's disease was caused by loss of brain neuromelanin in the substantia nigra. Although Cotzias's research had been in pharmacology, he also headed a clinical pharmacology research group at a federal laboratory on Long Island, New York, USA. He decided to try to restore this pigment in patients, not animals, and one of the three drugs he tried was d,l-dopa. As reported in his 1967 article, d,l-dopa proved to be dramatically successful in reversing the symptoms, but at extremely high dosages and with considerable hematologic adverse effects. Cotzias immediately tested l-dopa and found the same benefit with half the dosage and without the hematologic problems. Yahr was a clinical neurologist who had been treating patients with PD with available therapy and also headed a federally financed research group investigating the disorder. Always on the lookout for potential new treatments, he was initially skeptical about l-dopa when studies with low doses were being reported. Seeing videos of patients presented by Cotzias, however, he realized that the results needed confirmation through a double-blind controlled clinical trial. He proceeded to develop and execute such a trial with l-dopa, duplicating Cotzias's success. Both Cotzias and Yahr had encountered motor fluctuations and dyskinesias, but the amelioration of bradykinesia, rigidity, and tremor was so pronounced that these adverse effects did not prevent regulatory approval of l-dopa, and almost 50 years later l-dopa remains the most effective pharmacologic agent for treating Parkinson's disease. This article relates the personal stories of these four pioneers and how they achieved their success.

Evaluation of resveratrol, green tea extract, curcumin, oxaloacetic acid, and medium-chain triglyceride oil on life span of genetically heterogeneous mice

The National Institute on Aging Interventions Testing Program (ITP) was established to evaluate agents that are hypothesized to increase life span and/or health span in genetically heterogeneous mice. Each compound is tested in parallel at three test sites. It is the goal of the ITP to publish all results, negative or positive. We report here on the results of lifelong treatment of mice, beginning at 4 months of age, with each of five agents, that is, green tea extract (GTE), curcumin, oxaloacetic acid, medium-chain triglyceride oil, and resveratrol, on the life span of genetically heterogeneous mice. Each agent was administered beginning at 4 months of age. None of these five agents had a statistically significant effect on life span of male or female mice, by log-rank test, at the concentrations tested, although a secondary analysis suggested that GTE might diminish the risk of midlife deaths in females only.

Review of the literature and suggestions for the design of rodent survival studies for the identification of compounds that increase health and life span

Much of the literature describing the search for agents that increase the life span of rodents was found to suffer from confounds. One-hundred-six studies, absent 20 contradictory melatonin studies, of compounds or combinations of compounds were reviewed. Only six studies reported both life span extension and food consumption data, thereby excluding the potential effects of caloric restriction. Six other studies reported life span extension without a change in body weight. However, weight can be an unreliable surrogate measure of caloric consumption. Twenty studies reported that food consumption or weight was unchanged, but it was unclear whether these data were anecdotal or systematic. Twenty-nine reported extended life span likely due to induced caloric restriction. Thirty-six studies reported no effect on life span, and three a decrease. The remaining studies suffer from more serious confounds. Though still widely cited, studies showing life span extension using short-lived or "enfeebled" rodents have not been shown to predict longevity effects in long-lived animals. We suggest improvements in experimental design that will enhance the reliability of the rodent life span literature. First, animals should receive measured quantities of food and its consumption monitored, preferably daily, and reported. Weights should be measured regularly and reported. Second, a genetically heterogeneous, long-lived rodent should be utilized. Third, chemically defined diets should be used. Fourth, a positive control (e.g., a calorically restricted group) is highly desirable. Fifth, drug dosages should be chosen based on surrogate endpoints or accepted cross-species scaling factors. These procedures should improve the reliability of the scientific literature and accelerate the identification of longevity and health span-enhancing agents.

L-DOPA: a scapegoat for accelerated neurodegeneration in Parkinson's disease?

There is consensus that amelioration of the motor symptoms of Parkinson's disease is most effective with L-DOPA (levodopa). However, this necessary therapeutic step is biased by an enduring belief that L-DOPA is toxic to the remaining substantia nigra dopaminergic neurons by itself, or by specific metabolites such as dopamine. The concept of L-DOPA toxicity originated from pre-clinical studies conducted mainly in cell culture, demonstrating that L-DOPA or its derivatives damage dopaminergic neurons due to oxidative stress and other mechanisms. However, the in vitro data remain controversial as some studies showed neuroprotective, rather than toxic action of the drug. The relevance of this debate needs to be considered in the context of the studies conducted on animals and in clinical trials that do not provide convincing evidence for L-DOPA toxicity in vivo. This review presents the current views on the pathophysiology of Parkinson's disease, focusing on mitochondrial dysfunction and oxidative/proteolytic stress, the factors that can be affected by L-DOPA or its metabolites. We then critically discuss the evidence supporting the two opposing views on the effects of L-DOPA in vitro, as well as the animal and human data. We also address the problem of inadequate experimental models used in these studies. L-DOPA remains the symptomatic 'hero' of Parkinson's disease. Whether it contributes to degeneration of nigral dopaminergic neurons, or is a 'scapegoat' for explaining undesirable or unexpected effects of the treatment, remains a hotly debated topic.

Between destiny and disease: genetics and molecular pathways of human central nervous system aging

Aging of the human brain is associated with "normal" functional, structural, and molecular changes that underlie alterations in cognition, memory, mood and motor function, amongst other processes. Normal aging also imposes a robust constraint on the onset of many neurological diseases, ranging from late onset neurodegenerative diseases, such as Alzheimer's (AD) and Parkinson's diseases (PD), to early onset psychiatric disorders, such as bipolar disorder (BPD) and schizophrenia (SCZ). The molecular mechanisms and genetic underpinnings of age-related changes in the brain are understudied, and, while they share some overlap with peripheral mechanisms of aging, many are unique to the largely non-mitotic brain. Hence, understanding mechanisms of brain aging and identifying associated modulators may have profound consequences for the prevention and treatment of age-related impairments and diseases. Here we review current knowledge on age-related functional and structural changes, their molecular and genetic underpinnings, and discuss how these pathways may contribute to the vulnerability to develop age-related neurological diseases. We highlight recent findings from human post-mortem brain microarray studies, which we hypothesize, point to a potential genetically controlled transcriptional program underlying molecular changes and age-gating of neurological diseases. Finally, we discuss the implications of this model for understanding basic mechanisms of brain aging and for the future investigation of therapeutic approaches.

Rasagiline, Parkinson neuroprotection, and delayed-start trials: still no satisfaction?

Rasagiline has been studied as a Parkinson disease (PD) neuroprotective agent in 2 major clinical trials, utilizing the delayed-start design in an attempt to separate symptomatic drug benefits from a disease-modifying effect. The ostensibly positive outcomes of these studies, however, are obscured by potential confounding factors that seem intrinsic to this trial design, including 1) very small changes in clinical outcome measures that could easily be overshadowed by other influences; 2) probable incomplete blinding to study end; 3) subjective components of the Unified Parkinson's Disease Rating Scale (UPDRS) scoring system; and 4) practice influences from repeated scoring. Interpretation of the recent Attenuation of Disease Progression with Azilect Given Once-daily (ADAGIO) trials is especially problematic given 1) divergent results with the 2 symptomatically beneficial doses and 2) variability in UPDRS scores with active rasagiline, which was twice the magnitude of the major finding of the study. These studies further illustrate the difficulty in documenting a disease-modifying effect when considering a PD drug with symptomatic benefit.

Atrazine and reproductive function: mode and mechanism of action studies

Atrazine, a chlorotriazine herbicide, is used to control annual grasses and broadleaf weeds. In this review, we summarize our laboratory's work evaluating the neuroendocrine toxicity of atrazine (and related chlorotriazines) from an historic perspective. We provide the rationale for our work as we have endeavored to determine: 1) the underlying reproductive changes leading to the development of mammary gland tumors in the atrazine-exposed female rat; 2) the cascade of physiological events that are responsible for these changes (i.e., the mode of action for mammary tumors); 3) the potential cellular mechanisms involving adverse effects of atrazine; and 4) the range of reproductive alterations associated with this pesticide.

Challenging conventional wisdom: the etiologic role of dopamine oxidative stress in Parkinson's disease

Oxidative stress is well documented in Parkinson's disease (PD) and has been attributed to dopamine oxidative metabolism. However, evidence of oxidative stress is found in a variety of neurodegenerative disorders, suggesting that more general factors are responsible or that cytodestructive processes secondarily generate oxyradical products. Increasing evidence points away from dopamine metabolism as an important contributor to PD neurodegeneration. Predictions from the dopamine oxidative stress hypothesis of PD reveal multiple inconsistencies. Although the clinical and therapeutic importance of the nigrostriatal dopaminergic system is undeniable, PD neuropathology is much more widespread.

Parkinson's Disease: Initial Treatment with Levodopa or Dopamine Agonists

The question of whether to use levodopa (LD) or dopamine agonists as initial therapy in Parkinson's disease has been a controversy for nearly 20 years. There are several issues relating to this treatment regimen that may effect ones decision. Review of them results in the following conclusions: LD does not cause the onset of motor fluctuations and dyskinesia; it probably relates to disease progression. Tolerance does not develop with long-term LD therapy. LD is not toxic. LD decreases mortality in Parkinson's disease. Motor fluctuations can occur with dopamine-agonist monotherapy, but the actual frequency is as yet unknown. Dopamine agonists are not neuroprotective. Clinical trials have indicated that LD remains the most potent symptomatic therapeutic agent available. Dopamine agonists do provide some symptomatic relief when used alone in early Parkinson's disease. Standard preparations of LD have the same effect on early disease as controlled release preparations. Dopamine agonists cause less dyskinesia and fluctuations. These conclusions indicate that both drugs are effective symptomatic agents with their own positive and negative aspects. There is no incorrect choice. It is reasonable to start young onset patients (younger than 50 years of age) with an agonist, because they seem to be more prone to develop motor fluctuations and dyskinesia. However, if employment is in jeopardy then LD may be needed. Because agonists cause more hallucinations, freezing, and somnolence, problems of particular relevance to the elderly (older than 70 years), then LD would be the best agent for older onset patients. In general, but particularly for those falling in between these age groups, treatment should be individualized. In this time of cost effectiveness, LD remains the least expensive of these agents.

Parkinson's disease: medical and surgical treatment

It has been over three decades since the introduction of L-dihydroxyphenylalanine or levodopa therapy for Parkinson's disease (PD). The early levodopa trials were driven by recognition of a profound cerebral dopamine deficiency state in this disorder. Whereas dopamine fails to cross the blood brain barrier and hence is ineffective as therapy, the amino acid precursor, dopa, is transported across this barrier and provides a substrate for dopamine synthesis. Levodopa is converted to dopamine within the brain by dopa decarboxylase, replenishing central dopamine stores and potentially reversing the motor symptoms of PD.

Life span extension and cancer risk: myths and reality

A significant increase in the number of old people in the populations of developed countries was followed by an increase in morbidity and mortality resulting from main age-related diseases -- cardiovascular, cancer, neurodegenerative, diabetes mellitus, decrease in resistance to infections. Obviously, the development of the means of prevention of the premature aging of humans is crucial for the realization of this program. However, data available on such kind of means are rather scarce, contradictory and are often not reliable from the points of view of the adequacy of the experiments to current scientific requirements as well as the interpretation of the results and safety. Data available on the increase in life span and the adverse effects of the following geroprotectors were critically analyzed: antioxidants, chelate agents and lathyrogens, succinate, adaptogens and herbs, neurotropic drugs, inhibitors of monoamine oxidase, glucocorticoids, dehydroepiandrosterone, sex and growth hormones, melatonin, pineal peptide preparations, protein inhibitors, antidiabetic biguanides, thymic hormones and peptides, immunomodulators, enteroadsorbents, lypofuscin inhibitors, as well as calorie intake restriction and special diets. Most of the available results were insufficient and could not provide convincing evidence for the life span extension and the safety of the suggested geroprotectors. Drugs and means prolonging the life span could be subdivided into three groups: (a) geroprotectors prolonging the life span equally in all the members of the population: these postponed the beginning of the population's aging; (b) geroprotectors decreasing the mortality rate in a long-lived subpopulation, which raised their maximal life span: these slowed down the population's aging rate; (c) geroprotectors increasing the survival rate in a short-lived subpopulation without changes in the maximal life span: in this case, the aging rate increased. There was a high positive correlation between the type of geroprotector-induced aging delay and the pattern of tumour development in the same population of animals. The first type of geroprotectors did not influence the incidence of tumour but increased tumour latency. The second type of geroprotectors was effective both in the inhibition of spontaneous carcinogenesis and the increase in tumour latency. Certain drugs of the third type raised tumour incidence in the exposed populations. According to the multistage model, geroprotectors either inhibit or accelerate the passage of carcinogen-exposed cells form one stage to another. Thus, the efficacy of geroprotectors as preventive means of cancer development will decrease with respect to the age of exposure onset. Recommendations of the available drugs and means of life span increase should be carefully reconsidered under the international scientific control.

Does levodopa accelerate Parkinson's disease?

Therapeutic options for the treatment of Parkinson's disease (PD) have expanded tremendously over the last 5 years, although levodopa remains the gold standard of therapy. A major therapeutic controversy has been the question of levodopa's potential to cause toxic effects on nigrostriatal cells, thus potentiating the progression of the disease. The answer to that question will guide physicians in the timing of levodopa initiation and its dosage. The issue of levodopa toxicity was initially raised because of its potential to cause long term adverse effects (dyskinesias and motor fluctuations), which are not observed in untreated patients. Levodopa-induced toxicity can be related to its potential to produce free radicals, which are known to be toxic to cells, in the process of its conversion to dopamine. In vitro data reveals some evidence of the toxic effect of levodopa although recent studies suggest that levodopa toxicity is dependent on its concentration and can be ameliorated in the presence of glial cells. In vivo data from healthy animals and humans does not convincingly demonstrate levodopa toxicity. There is no evidence of levodopa-induced neurotoxicity in patients with PD. Despite the absence of toxic effect in patients with PD, levodopa can cause long term complications like motor fluctuations and dyskinesias and should be used judiciously in the minimal clinically effective dose. In this article we review evidence for and against levodopa neurotoxicity and the implications of the 'levo-dopa controversy' on clinical practice.

Involvement of brain dopaminergic structures in neuroimmunomodulation

Bilateral electrolytic destruction of the brain areas containing dopamine (DA) cell bodies (nuclei A9 and A10) as well as terminal regions of the nigrostriatal and mesolimbic DAergic systems (nuclei caudatus and accumbens) resulted in a considerable decrease in the intensity of the immune response in rats immunized with sheep red blood cells (SRBC). Administration of SRBC (5 x 10(8) i.p.) to rats produced a marked rise in activity of central DAergic system at early stage of the immune response formation. The most pronounced elevation in the concentration of DA and its metabolites, measured by the method of high performance liquid chromatography with electrochemical detection, was observed in the terminal regions of the nigrostriatal and mesolimbic DAergic systems (nuclei caudatus and accumbens), hypothalamus, hippocampus, amygdala within 20 min following antigen inoculation. By 60 min after immunization DA metabolism has been retained at a high level in all brain regions examined. The concentration of DA returned to control level in the amygdala and hypothalamus 24 hours after antigen administration and had a tendency to reach control values in the rest of the structures. The present results indicate that nigrostriatal and mesolimbic DAergic systems and DAergic structures of the hypothalamus are involved in the mechanisms of neuroimmunomodulation.

Levodopa induces apoptosis in cultured neuronal cells--a possible accelerator of nigrostriatal degeneration in Parkinson's disease?

Apoptosis is an active, intrinsic cell suicide program. We recently suggested that it may have a role in the death of nigrostriatal dopaminergic neurons in Parkinson's disease (PD). We now report that levodopa, the current major therapy for PD, is a potent inducer of apoptosis in cultured postmitotic chick sympathetic neurons. Levodopa, in a concentration range of 0.01-0.3 mM, caused the characteristic apoptotic cascade of cell shrinkage, massive membrane blebbing, and nuclear fragmentation, as evident by nuclear flow cytometry and fluorescence microscopy. Levodopa-induced apoptosis was inhibited by antioxidants, indicating that it may be mediated by autooxidation-reactive species. Levodopa treatment for PD may therefore constitute an additional challenge for the defective apoptosis-inhibiting systems in the nigrostriatal neurons. Despite reassuring data from some, but not all, previous studies, these findings suggest that the possible in vivo toxic effects of levodopa on the survival of the remaining nigral neurons should be further explored.

Longevity effect of chromium picolinate--'rejuvenation' of hypothalamic function?

The first rodent longevity study with the insulin-sensitizing nutrient chromium picolinate has reported a dramatic increase in both median and maximal lifespan. Although the observed moderate reductions in serum glucose imply a decreased rate of tissue glycation reactions, it is unlikely that this alone can account for the substantial impact on lifespan; an effect on central neurohormonal regulation can reasonably be suspected. Recent studies highlight the physiological role of insulin as a modulator of brain function. I postulate that aging is associated with a reduction of effective insulin activity in the brain, and this contributes to age-related alterations of hypothalamic functions that result in an 'older' neurohormonal milieu; consistent with this possibility, diabetes leads to changes of hypothalamic regulation analogous to those seen in normal aging. Conversely, promoting brain insulin activity with chromium picolinate may help to maintain the hypothalamus in a more functionally youthful state; increased hypothalamic catecholamine activity, sensitization of insulin-responsive central mechanisms regulating appetite and thermogenesis, and perhaps trophic effects on brain neurons may play a role in this regard. Since both the pineal gland and thymus are dependent on insulin activity, chromium may aid their function as well. Thus, the longevity effect of chromium picolinate may depend primarily on delay or reversal of various age-related changes in the body's hormonal and neural milieu. A more general strategy of hypothalamic 'rejuvenation' is proposed for extending healthful lifespan.

An ultrastructural study of dopamine-immunoreactive nerve fibres in milky spots of the human greater omentum

An ultrastructural study was performed to examine the presence and distribution of dopamine-immunoreactive nerve fibres in milky spots of the human greater omentum. Non-myelinated nerve fibres were located perivascularly as well as throughout the milky spots. Dopamine immunoreactivity was demonstrated in the nerve fibres and in a portion of the macrophage population. These results demonstrate a discrepancy between human and non-human milky spots.

Toxic and protective effects of L-dopa on mesencephalic cell cultures

The autoxidation of L-DOPA or dopamine (DA) and the metabolism of DA by monoamine oxidase generate a spectrum of toxic species, namely, hydrogen peroxide, oxy radicals, semiquinones, and quinones. When primary dissociated cultures of rat mesencephalon were incubated with L-DOPA (200 microM) for 48 h, the number of tyrosine hydroxylase-positive neurons (DA neurons) was reduced to 69.7% of control values, accompanied by a decrease in [3H]DA uptake to 42.3% of control values; the remaining DA neurons exhibited reduced neurite length and overall deterioration. Lack of simultaneous change in the number of neurons stained with neuron-specific enolase indicated that toxicity was relatively specific for DA neurons. At the same time, the level of GSH, a major cellular antioxidant, rose to 125.2% of control values. Thus, exposure of mesencephalic cultures to L-DOPA results in both damaging and antioxidant actions. Ascorbate (200 microM), an antioxidant, prevented the rise in GSH. The effect of ascorbate on GSH points to an oxidative signal to initiate the rise in GSH content. On the other hand, neither inhibition of monoamine oxidase with pargyline nor addition of superoxide dismutase or catalase to the culture medium prevented the rise in GSH level or the loss in [3H]DA uptake. The latter results tend to exclude the products of monoamine oxidase activity or the presence of hydrogen peroxide or superoxide in the medium as responsible agents for the rise in GSH or neuronal toxicity. In cultures treated with L-buthionine sulfoximine (L-BSO), an inhibitor of GSH synthesis, L-DOPA prevented cell death by L-BSO.

Neuroimmunopharmacologic effects of drugs of abuse

Direct studies linking drugs of abuse with changes in neurotransmitters and subsequent effects on the immune system are not abundant. One can, however, hypothesize that an indirect effect can occur since a variety of neurotransmitters known to be acted on by various drugs of abuse can, in turn, be correlated with changes in immunity. These changes most likely are mediated via alterations in the autonomic nervous system or the ratio of hormones regulated by the pituitary gland. In addition, there is sound evidence to suspect that the immune system might be capable of altering either the induction of tolerance or the severity of withdrawal symptoms. An increasing body of evidence indicates that IL-1, IFN-alpha, as well as C3a and C5a of the complement cascade, are capable of acting on central catecholamines within the brain. The possibility that immune system peptides are capable of regulating neurotransmitters is further suggested by the evidence of neuropsychiatric side effects during the course of clinical trials. Since a variety of drugs of abuse can directly alter immunocompetence as evidenced by the results of in vitro protocols described elsewhere in this volume, one could speculate that certain behavioral manifestations of drug addiction may be modulated, in part, by immunologic status.

Striatal dopamine, sexual activity and lifespan. Longevity of rats treated with (-)deprenyl

The influence of longterm deprenyl treatment on the sexual performance and lifespan of male rats was studied. One hundred and thirty two rats were treated from the end of their 2nd year of life either with saline (1 ml/kg, s.c.) (n = 66) or with deprenyl (0.25 mg/kg, s.c.) (n = 66) three times a week until death. Whereas none of the two-year-old saline-treated rats displayed full scale sexual activity, this appeared in 64 out of 66 rats on deprenyl. The longest living rat in the saline-treated group lived 164 weeks. The lifespan of the group was 147.05 +/- 0.56 weeks. The shortest living animal in the (-)deprenyl-treated group lived 171 weeks and the longest living rat died during the 226th week of its life. The lifespan was 191.91 +/- 2.31 weeks. This is the first instance that a well aimed medication prolonged lifespan of members of a species beyond their maximum age of death (182 weeks in the rat). A close relation between sexual activity and lifespan was detected.

The striatal dopamine dependency of life span in male rats. Longevity study with (-)deprenyl

Long-term experiments on male rats revealed that better performers in the mating test are better learners in the shuttle box and the more active animals live significantly longer than their less active peers. It was established by the aid of (-)deprenyl, a highly specific chemical tool, which increases superoxide dismutase activity in the striatum, facilitates the activity of the nigrostriatal dopaminergic neurons with utmost selectivity, and protects these neurons from their age-related decay, that the efficiency of a male rat in behavioral tests, as well as the duration of its life are striatal dopamine dependent functions. As a measure of striatal function, sexual activity was tested once a week in a group of male rats (n = 132) from the 24th month of their life. Because of the age-related decay of this function none of the 2-year-old animals displayed full scale sexual activity. By dividing the group equally the rats were treated with saline (1 ml/kg, s.c.) and deprenyl (0.25 mg/kg, s.c.), respectively, three times a week. In the saline-treated group (n = 66) the last signs of sexual activity vanished to the 33rd week of treatment. (-)Deprenyl treatment restored full scale sexual activity in 64 out of 66 rats. The longest living rat in the saline-treated group lived 164 weeks. The average lifespan of the group was 147.05 +/- 0.56 weeks. The shortest living animal in the (-)deprenyl-treated group lived 171 weeks and the longest living rat died during the 226th week of its life. The average lifespan was 197.98 +/- 2.36 weeks, i.e. higher than the estimated maximum age of death in the rat (182 weeks). This is the first instance that by the aid of a well-aimed medication members of a species lived beyond the known lifespan maximum.

Reduced disease in aged rats treated chronically with ibopamine, a catecholaminergic drug

As part of preclinical safety testing for carcinogenicity, postpubertal (50 days old) rats were dosed (0, 30, 90 or 180 mg/kg/day) with ibopamine (N-methyldopamine, 0,0'-diisobutyroyl ester.HCl; SK&F 100168) for 730 consecutive days. Neoplastic and nonneoplastic lesions were identified histologically in all rats that died during the period of dosing, as well as in those that were killed after it was completed. Six neoplastic lesions (adrenal cortical, mammary, and pituitary adenoma, skin papilloma, pheochromocytoma and mammary adenocarcinoma) and five nonneoplastic lesions (chronic glomerulonephropathy, renal pelvic mineralization, hepatocellular proliferative nodule, galactoceles and chronic cardiomyopathy) were significantly reduced in a dose-related fashion in at least one sex of ibopamine-treated rats. In addition, age-related alopecia and atrophy of the adrenal zona glomerulosa were retarded by ibopamine treatment. Squamous cell skin carcinoma was the only lesion that was significantly (p less than 0.05) increased in the treated groups. Mortality during the study was not significantly different in treated and control groups, indicating that the lower incidence of disease in ibopamine-treated rats was a drug effect and not an artifact of differential survival. Although life span was not measured, ibopamine-treated rats had significantly less malignant lesions than controls at the end of dosing, suggesting a potentially positive effect of treatment on population survival. As the result of these beneficial effects, ibopamine may be useful for future study of factors affecting the occurrence of disease during aging.

Multi-center study of Parkinson mortality with early versus later dopa treatment

Four geographically diverse centers provided data on mortality in 359 patients with Parkinson's disease, the majority of whom began dopa treatment during the early experimental trials of 1968 to 1970. Patients were classified into three groups based on the duration of symptoms prior to starting dopa treatment: Group 1, 1 to 3 years; Group 2, 4 to 6 years; Group 3, 7 to 9 years. After 15 years of treatment and 3,689 person-years of observation, Group 1 had an observed-to-expected mortality ratio of 1.43; Group 2, 2.44; and Group 3, 2.95 (p less than 0.05). This result confirmed that increased duration of disease was associated with increased mortality risk. To examine the effect of the time of initiation of dopa treatment, duration of disease was held constant at 17 years for all three groups. Observed-to-expected mortality ratios were 1.43 for Group 1; 2.66 for Group 2; 2.63 for Group 3. This statistically significant advantage for Group 1 (p less than 0.0001) led to the conclusion that early treatment with dopa has a beneficial effect on life expectancy. After 17 years of disease, causes of death in Group 1 were less likely (p = 0.027) to be due to Parkinson's disease than was found in the other groups.

The modulation of dopamine-sensitive adenylate cyclase activity in the mouse caudate nucleus by estradiol

When levodopa (L-DOPA) is administered to mice, the central nervous system responses to the dopamine stimulation were less sensitive in female than in the male mice. The sensitivity is reflected both behaviorally and biochemically. The behavioral response were measured by scores recorded after intraperitoneal injection of a standard dose of L-DOPA. The biochemical studies included the determination of the cyclic AMP produced by in vitro experiments after incubating dopamine with mouse caudate nucleus homogenates. This insensitivity to dopamine stimulation in female animals can be reversed by ovariectomy. Estradiol treatment in vivo suppressed the dopamine stimulation, while estradiol directly added to the caudate nucleus homogenate does not affect the dopamine-sensitive adenylate cyclase activity. These findings indicate that the estradiol-induced effects on the brain enzyme are indirect. The female sex hormone does have an effect on the central dopaminergic system. However, the underlying mechanism(s) cannot be delineated by the present studies.

Effects of dietary restriction on presbyacusis in the mouse

If dietary restriction can extend the human life span, it would be useful to know whether presbyacusis would continue its normal pace. This question was experimentally addressed, using the mouse as a model. Alternate-day feeding and fasting resulted in restricted mice of the AKR and AU/Ss inbred strains weighing less than their continuously fed controls. Restriction did not increase the life span or alter presbyacusis of the AKR mouse, but it improved both functions in the AU/Ss mouse. Their life spans were increased by 40%, and cochlear functions were better than controls at every age at which animals of both groups were still alive. Nonetheless, the oldest remaining restricted AU/Ss mouse had greater cochlear loss than was seen in any AU/Ss control mice. This study demonstrates that dietary restriction can slow the cochlear losses in a mammal which has a presbyacusis condition similar to that of humans.

Neuroimmunomodulatory interactions of norepinephrine and serotonin

Monoamine neuroleptics alter rodents responses to immunization, suggesting that norepinephrine (NE) and serotonin (5HT) are neuroimmunomodulatory in these animals. Although endocrine factors participate in their mechanism(s) of action, recent studies suggest that NE and 5HT also interact more directly with immunocompetent cells. This review provides an overview of evidence for a direct regulatory link between the nervous and immune systems and further speculates on the process by which NE and 5HT realize in part, their neuroimmunomodulatory potential. Anatomical data show that noradrenergic fibers of the sympathetic nervous system innervate lymphoid organs providing a channel of communication between neurons and lymphocytes. Presumably neural signals transmitted by NE are received by platelets that in turn, transduce them via 5HT into immunomodulatory messages. It is proposed that NE alters the capacity of platelets to sequester and/or catabolize 5HT, thus regulating its physiologically active pool in the plasma. Macrophages possess a 5HT uptake system, the kinetic properties of which make them sensitive to changes in plasma levels of the amine. Thus, through its ability to regulate plasma levels of 5HT, an immunosuppressive amine with access to macrophages, the nervous system can influence cells involved in antigen recognition. Support for this hypothetical immunomodulatory mechanism is gleaned from clinical and experimental studies. For example, individuals suffering emotional trauma are more susceptible than others to developing physical illness. It is of interest that platelet 5HT pharmacodynamics are often abnormal in patients with psychological disorders characterized by catecholamine deficits. Similar platelet changes have been achieved experimentally by treating rats with catecholamine antimetabolites. Additional support for the hypothesis derives from aging research since 'monoamine imbalance' and immune dysfunction are co-characteristics of senescence. In aging rodents and humans, central catecholamine deficits are associated with a decreased platelet affinity for 5HT and an increased plasma content of 5HT. Thus, emotional, spontaneous (age-related), or experimental changes in monoamine homeostasis have the potential to increase the risk of disease in affected individuals. Perhaps part of this effect results from endocrine perturbations associated with the trauma. However, a direct interaction between the nervous and immune systems involving monoamines is also possible, and a need for future study of this potentially significant mechanism for neuroimmunomodulation is indicated.

Nigrostriatal dopaminergic neurons remain undamaged in rats given high doses of L-DOPA and carbidopa chronically

Rats were fed maximally tolerated doses of L-3,4-Dihydroxyphenylalanine (L-DOPA) and carbidopa daily for 120 days in order to achieve a sustained elevation in brain dopamine levels. Some animals were also given buthionine sulfoximine, a gamma-glutamylcysteine synthetase inhibitor, in an unsuccessful effort to reduce brain glutathione contents. L-DOPA- and carbidopa-treated animals displayed no behavioral changes suggestive of nigrostriatal dopaminergic neuronal loss. When sacrificed 60 days after L-DOPA treatment ended, all rats had normal tyrosine hydroxylase activities and dopamine contents in their striata, and cell counts were normal in the substantia nigra. It therefore seems unlikely that a model of Parkinson's disease, suitable for exploring the etiological importance of glutathione deficiency, can be produced in rats merely by administering the largest tolerable doses of L-DOPA.

Impact of age-related changes in serotonin and norepinephrine metabolism on reproductive function in female rats: an analytical review

This review attempts to reconcile changes in brain NE and 5HT metabolism with the effects of aging, drug treatment and altered photoperiods on phasic and tonic release of LH in the female. A hypothesis is presented in which 5HT has "indirect" and "direct" effects on LH surges. The "indirect" ones facilitate LH surges via a generalized effect of 5HT on temporal organization within multiple neuroendocrine axes. Thus, 5HT promotes circadian rhythmicity in many systems due to its participation in the biological "clock" mechanism of the hypothalamus. The "direct" ones that are specific to the LH releasing mechanism also occur for 5HT (inhibitory) as well as for NE (facilitory) due to the interaction of these transmitters with LH-RH secreting neurons. It is proposed that metabolic changes during aging that favor 5HT at the expense of NE obliterate the facilitatory effects of both amines while enhancing the inhibitory component of 5HT's influence on LH secretion.

Food intake reduction and immunologic alterations in mice fed dehydroepiandrosterone

A diet containing 0.4% DHEA was fed to male mice of a long-lived strain from 3 weeks until 18 weeks of age. These mice were compared with others fed a control diet ad libitum and with mice pair-fed the control diet in amounts approximating the intake of the DHEA-fed group. Mice fed the DHEA diet failed to eat all of the food presented to them whereas the pair-fed mice ate all of their food. All mice were studied at 18 weeks of age for two age-sensitive immune parameters (spleen lymphocyte proliferation induced by T-cell mitogens [PHA or ConA] and natural killer cell lysis of an allogeneic tumor). DHEA feeding led to: 1) a decrease in food intake (approximately 30% less than for mice fed the control diet ad libitum), 2) a lower body weight at 18 weeks of age (approximately 40% lower than for ad libitum controls) due to a decrease in the body weight gained from 3 weeks through 18 weeks of age (approximately 55% lower than controls), 3) a lower spleen weight (approximately 30% lower than controls) but without lower numbers of nucleated cells per spleen, 4) an increase in PHA-induced proliferation by spleen lymphocytes (approximately 100% higher than for controls) and, 5) no influence on splenic natural killer cell activity. The inhibition of body weight gain for mice fed DHEA appeared due to both a reduction in food intake and a metabolic effect since mice eating DHEA gained less body weight per gram of food eaten than did mice in either group eating the control diet.

Effect of suloctidil on dopaminergic transmission in various rat brain areas: possible uses as drug for the elderly

Suloctidil is a drug used in the elderly endowed with a mechanism of action at neuronal level which has not been completely explored. The results of the present study indicate that acute treatment with suloctidil induces a decrease of serum prolactin levels and a decrease of 3,4-diidroxyphenylacetic acid concentrations in various rat brain areas. In addition, the repeated injection of small Suloctidil doses produces a down-regulation of dopaminergic receptors. These data suggest that Suloctidil has dopamino-mimetic properties in vivo. This pharmacological activity may be of importance in the clinical action of Suloctidil in the elderly.

The route and significance of endogenous synthesis of alkaloids in animals

There is now substantial evidence that several TIQs and beta-carbolines are present in vivo and increase during certain pathological conditions. It still remains to be determined, however, precisely what roles they play in endogenous functions and whether or not they are critical for the expression of these pathological conditions. Accumulating biochemical information continues to support the notion that these compounds can act as false transmitters. The exciting new findings, which will certainly receive a great deal more attention, concern the interaction of some of the beta-carbolines with the benzodiazepine receptor. Determining if a beta-carboline is an endogenous receptor ligand will attract further research interest on the theoretical and specifically clinically-directed levels. Biochemical, morphological, and behavioral data indicate that some of the condensation products can act as neurotoxins. Very few experiments have included an examination of long-term effects of exposure to one of these alkaloids, so the amount of information on this issue is limited. Chronic rather than acute administration of an alkaloid is more likely to mimic the pathological states in which these compounds are hypothesized to play a role. Biochemically, both the dopaminergic and serotonergic systems have been shown to be affected by chronic treatments with certain alkaloids. Progressive and long-term behavioral alterations also have been reported. Such changes may reflect an adaptation to an increase or decrease in activity of particular systems or a neurotoxic action.

Aging process affects a single class of dopamine receptors

[3H]Spiroperidol and [3H](-)-sulpiride specific binding have been used to assay for D1 and D2 dopaminergic recognition sites in striatal membranes of aged rats. While [3H]spiroperidol binding shows a decreased number of binding sites, no changes have been detected in [3H](-)-sulpiride binding, which is a marker for D2 dopaminergic receptors. Data obtained with GTP and DA-dependent adenylyl cyclase activity confirm the hypothesis that aging selectively affects in rats those dopaminergic receptors coupled to the formation of cyclic AMP (D1).

Impairment of brain neurotransmitter receptors in aged rats

Dopamine and gamma-aminobutyric acid (GABA) receptor functions have been measured in various brain areas of aged rats. [3H] Spiroperidol binding is decreased in various dopaminergic brain areas, particularly in striatum and tuberculum olfactorium. In striatum the number of binding sites for [3H] spiroperidol is similar in both groups of animals, while the affinity is reduced in senescent rats. Moreover, in the pituitary a 50% increase of [3H] spiroperidol binding was detected in the group of senescent animals. On the other hand, [3H] GABA binding is significantly decreased in substantia nigra and hypothalamus of aged rats, while it is unmodified in cerebral cortex, cerebellum, striatum and nucleus accumbens.

Stress and coping factors influence tumor growth

Growth of syngeneic P815 mastocytoma in DBA/2J male mice was evaluated as a result of various stress regimens. A single session of inescapable shock resulted in earlier tumor appearance, exaggeration of tumor size, and decreased survival time in recipient animals. Escapable shock had no such effects. The effects of the inescapable shock were mitigated if mice received long-term shock treatment.