Xanthurenic acid: A role in brain intercellular signaling.

Xanthurenic acid (XA) raises a growing multidisciplinary interest based upon its oxidizing properties, its ability to complex certain metal ions, and its detoxifier capacity of 3-hydroxykynurenine (3-HK), its brain precursor. However, little is still known about the role and mechanisms of action of XA in the central nervous system (CNS). Therefore, many research groups have recently investigated XA and its central functions extensively. The present paper critically reviews and discusses all major data related to XA properties and neuronal activities to contribute to the improvement of the current knowledge on XA's central roles and mechanisms of action. In particular, our data showed the existence of a specific G-protein-coupled receptor (GPCR) for XA localized exclusively in brain neurons exhibiting Ca2+ -dependent dendritic release and specific electrophysiological responses. XA properties and central activities suggest a role for this compound in brain intercellular signaling. Indeed, XA stimulates cerebral dopamine (DA) release contrary to its structural analog, kynurenic acid (KYNA). Thus, KYNA/XA ratio could be fundamental in the regulation of brain glutamate and DA release. Cerebral XA may also represent an homeostatic signal between the periphery and several brain regions where XA accumulates easily after peripheral administration. Therefore, XA status in certain psychoses or neurodegenerative diseases seems to be reinforced by its brain-specific properties in balance with its formation and peripheral inputs.

Myelin in Alzheimer's disease: culprit or bystander?

Alzheimer's disease (AD) is a neurodegenerative disorder with neuronal and synaptic losses due to the accumulation of toxic amyloid ß (Αß) peptide oligomers, plaques, and tangles containing tau (tubulin-associated unit) protein. While familial AD is caused by specific mutations, the sporadic disease is more common and appears to result from a complex chronic brain neuroinflammation with mitochondriopathies, inducing free radicals' accumulation. In aged brain, mutations in DNA and several unfolded proteins participate in a chronic amyloidosis response with a toxic effect on myelin sheath and axons, leading to cognitive deficits and dementia. Αß peptides are the most frequent form of toxic amyloid oligomers. Accumulations of misfolded proteins during several years alters different metabolic mechanisms, induce chronic inflammatory and immune responses with toxic consequences on neuronal cells. Myelin composition and architecture may appear to be an early target for the toxic activity of Aß peptides and others hydrophobic misfolded proteins. In this work, we describe the possible role of early myelin alterations in the genesis of neuronal alterations and the onset of symptomatology. We propose that some pathophysiological and clinical forms of the disease may arise from structural and metabolic disorders in the processes of myelination/demyelination of brain regions where the accumulation of non-functional toxic proteins is important. In these forms, the primacy of the deleterious role of amyloid peptides would be a matter of questioning and the initiating role of neuropathology would be primarily the fact of dysmyelination.

From Systemic Inflammation to Neuroinflammation: The Case of Neurolupus.

It took decades to arrive at the general consensus dismissing the notion that the immune system is independent of the central nervous system. In the case of uncontrolled systemic inflammation, the relationship between the two systems is thrown off balance and results in cognitive and emotional impairment. It is specifically true for autoimmune pathologies where the central nervous system is affected as a result of systemic inflammation. Along with boosting circulating cytokine levels, systemic inflammation can lead to aberrant brain-resident immune cell activation, leakage of the blood⁻brain barrier, and the production of circulating antibodies that cross-react with brain antigens. One of the most disabling autoimmune pathologies known to have an effect on the central nervous system secondary to the systemic disease is systemic lupus erythematosus. Its neuropsychiatric expression has been extensively studied in lupus-like disease murine models that develop an autoimmunity-associated behavioral syndrome. These models are very useful for studying how the peripheral immune system and systemic inflammation can influence brain functions. In this review, we summarize the experimental data reported on murine models developing autoimmune diseases and systemic inflammation, and we explore the underlying mechanisms explaining how systemic inflammation can result in behavioral deficits, with a special focus on in vivo neuroimaging techniques.

Assessing Autophagy in Sciatic Nerves of a Rat Model that Develops Inflammatory Autoimmune Peripheral Neuropathies.

The rat sciatic nerve has attracted widespread attention as an excellent model system for studying autophagy alterations in peripheral neuropathies. In our laboratory, we have developed an original rat model, which we used currently in routine novel drug screening and to evaluate treatment strategies for chronic inflammatory demyelinating polyneuropathy (CIDP) and other closely related diseases. Lewis rats injected with the S-palmitoylated P0(180-199) peptide develop a chronic, sometimes relapsing-remitting type of disease. Our model fulfills electrophysiological criteria of demyelination with axonal degeneration, confirmed by immunohistopathology and several typical features of CIDP. We have set up a series of techniques that led us to examine the failures of autophagy pathways in the sciatic nerve of these model rats and to follow the possible improvement of these defects after treatment. Based on these newly introduced methods, a novel area of investigation is now open and will allow us to more thoroughly examine important features of certain autophagy pathways occurring in sciatic nerves.

Autophagy in neuroinflammatory diseases.

Autophagy is a metabolically-central process that is crucial in diverse areas of cell physiology. It ensures a fair balance between life and death molecular and cellular flows, and any disruption in this vital intracellular pathway can have consequences leading to major diseases such as cancer, metabolic and neurodegenerative disorders, and cardiovascular and pulmonary diseases. Recent pharmacological studies have shown evidence that small molecules and peptides able to activate or inhibit autophagy might be valuable therapeutic agents by down- or up-regulating excessive or defective autophagy, or to modulate normal autophagy to allow other drugs to repair some cell alteration or destroy some cell subsets (e.g. in the case of cancer concurrent treatments). Here, we provide an overview of neuronal autophagy and of its potential implication in some inflammatory diseases of central and peripheral nervous systems. Based on our own studies centred on a peptide called P140 that targets autophagy, we highlight the validity of autophagy processes, and in particular of chaperone-mediated autophagy, as a particularly pertinent pathway for developing novel selective therapeutic approaches for treating some neuronal diseases. Our findings with the P140 peptide support a direct cross-talk between autophagy and certain central and peripheral neuronal diseases. They also illustrate the fact that autophagy alterations are not evenly distributed across all organs and tissues of the same individual, and can evolve in different stages along the disease course.

Autoimmunity, neuroinflammation, pathogen load: A decisive crosstalk in neuropsychiatric SLE.

Depicting the cellular and molecular bases of the continuous dialogue existing between the peripheral immune and the central nervous systems, as in neurolupus, is fundamental to improve, and better apprehend the role played by immune cells and mediators in the initiation and progression of neurological and psychiatric diseases, which nowadays remain a major public health issue. The relative frequency of neurological symptoms occurring in systemic autoimmunity is particularly worrying as, for example, two-thirds of patients with lupus will eventually experience the disabling effects of neuropsychiatric lupus. Neurolupus is a particularly severe form of lupus with wide-ranging symptoms, which contribute to increased mortality and morbidity in patients. In this context, infections, which suddenly trigger exacerbations of the otherwise mild lupus disease, may drive the progression of neuroinflammation and neurodegeneration via different mechanisms involving a network of effector molecules and cells. The complex interaction of neuroimmunology and neuroinfectiology represents a genuine challenge for basic scientists and clinicians to understand the mechanisms that are implicated, and identify possible biomarkers of severity that might predict the development of this devastating form of lupus. The ultimate goal is to design appropriate, personalised therapeutic strategies to improve the outcome of the disease.

Neuropsychiatric systemic lupus erythematosus and cognitive dysfunction: the MRL-lpr mouse strain as a model.

Mouse models of autoimmunity, such as (NZB×NZW)F1, MRL/MpJ-Fas(lpr) (MRL-lpr) and BXSB mice, spontaneously develop systemic lupus erythematosus (SLE)-like syndromes with heterogeneity and complexity that characterize human SLE. Despite their inherent limitations, such models have highly contributed to our current understanding of the pathogenesis of SLE as they provide powerful tools to approach the human disease at the genetic, cellular, molecular and environmental levels. They also allow novel treatment strategies to be evaluated in a complex integrated system, a favorable context knowing that very few murine models that adequately mimic human autoimmune diseases exist. As we move forward with more efficient medications to treat lupus patients, certain forms of the disease that requires to be better understood at the mechanistic level emerge. This is the case of neuropsychiatric (NP) events that affect 50-60% at SLE onset or within the first year after SLE diagnosis. Intense research performed at deciphering NP features in lupus mouse models has been undertaken. It is central to develop the first lead molecules aimed at specifically treating NPSLE. Here we discuss how mouse models, and most particularly MRL-lpr female mice, can be used for studying the pathogenesis of NPSLE in an animal setting, what are the NP symptoms that develop, and how they compare with human SLE, and, with a critical view, what are the neurobehavioral tests that are pertinent for evaluating the degree of altered functions and the progresses resulting from potentially active therapeutics.

Neuropsychiatric systemic lupus erythematosus: pathogenesis and biomarkers.

Systemic lupus erythematosus (SLE) is a complex clinical syndrome, elements of which remain poorly understood. Although recognized over 140 years ago when Kaposi recorded the systemic nature and manifestations of the disease, CNS involvement represents one of the least understood aspects of SLE. This knowledge gap remains despite the fact that up to 75% of adults and children with SLE will, at some point over the course of the disease and to different extents, experience the various disabling effects of neuropsychiatric SLE (NPSLE). Indeed, after decades of research, our understanding of the underlying pathophysiology of NPSLE, in particular, remains limited. Numerous factors contribute to the immune dysfunction that occurs in SLE, including genetic, environmental and hormonal influences, and the contributory or predisposing components that lead to neurological tropism of disease in some patients have not been clearly demonstrated. Features of NPSLE pathogenesis that might be directly linked to clinical manifestations have been identified; however, the complexity and variety of NPSLE symptoms and the clinical overlap with other psychiatric disorders continue to make accurate diagnosis difficult and time-consuming. Thus, efforts to define biomarkers of NPSLE are needed to improve prediction of disease outcomes and guide treatment. In this article, we review the manifestation and pathogenesis of NPSLE, focusing on the features that might aid identification of potential biomarkers.

The double-H maze test, a novel, simple, water-escape memory task: acquisition, recall of recent and remote memory, and effects of systemic muscarinic or NMDA receptor blockade during training.

To explore spatial cognition in rodents, research uses maze tasks, which differ in complexity, number of goals and pathways, behavioural flexibility, memory duration, but also in the experimenter's control over the strategy developed to reach a goal (e.g., allocentric vs. egocentric). This study aimed at validating a novel spatial memory test: the double-H maze test. The transparent device made of an alley with two opposite arms at each extremity and two in its centre is flooded. An escape platform is submerged in one arm. For experiments 1-3, rats were released in unpredictable sequences from one of both central arms to favour an allocentric approach of the task. Experiment 1 (3 trials/day over 6 days) demonstrated classical learning curves and evidence for recent and nondegraded remote memory performance. Experiment 2 (2 days, 3 trials/day) showed a dose-dependent alteration of task acquisition/consolidation by muscarinic or NMDA receptor blockade; these drug effects vanished with sustained training (experiment 3; 4 days, 3 trials/day). Experiment 4 oriented rats towards a procedural (egocentric) approach of the task. Memory was tested in a misleading probe trial. Most rats immediately switched from response learning-based to place learning-based behaviour, but only when their initial view on environmental cues markedly differed between training and probe trials. Because this simple task enables the formation of a relatively stable memory trace, it could be particularly adapted to study consolidation processes at a system level or/and the interplay between procedural and declarative-like memory systems.

Modulation of cholinergic functions by serotonin and possible implications in memory: general data and focus on 5-HT(1A) receptors of the medial septum.

Cholinergic systems were linked to cognitive processes like attention and memory. Other neurotransmitter systems having minor influence on cognitive functions - as shown by the weakness of the effects of their selective lesions - modulate cholinergic functions. The serotonergic system is such a system. Conjoined functional changes in cholinergic and serotonergic systems may have marked cognitive consequences [Cassel JC, Jeltsch H. Serotoninergic modulation of cholinergic function in the central nervous system: cognitive implications. Neuroscience 1995;69(1):1-41; Steckler T, Sahgal A. The role of serotoninergic-cholinergic interactions in the mediation of cognitive behaviour. Behav Brain Res 1995;67:165-99]. A crucial issue in that concern is the identification of the neuroanatomical and neuropharmacological substrates where functional effects of serotonergic/cholinergic interactions originate. Approaches relying on lesions and intracerebral cell grafting, on systemic drug-cocktail injections, or even on intracerebral drug infusions represent the main avenues on which our knowledge about the role of serotonergic/cholinergic interactions has progressed. The present review will visit some of these avenues and discuss their contribution to what is currently known on the potential or established implication(s) into memory functions of serotonergic/cholinergic interactions. It will then focus on a brain region and a neuropharmacological substrate that have been poorly studied as regards serotonergic modulation of memory functions, namely the medial septum and its 5-HT(1A) receptors. Based on recent findings of our laboratory, we suggest that these receptors, located on both cholinergic and GABAergic septal neurons, take part in a mechanism that controls encoding, to some extent consolidation, but not retrieval, of hippocampal-dependent memories. This control, however, does not occur by the way of an exclusive action of serotonin on cholinergic neurons.