Xenobiotic metabolizing enzymes in the central nervous system: Contribution of cytochrome P450 enzymes in normal and pathological human brain

The metabolism of xenobiotics in human brain constitutes a field of recent intensive research in relation to the potential implications in the pharmacological effect of drugs acting on the central nervous system. Cytochrome P450 enzymes (CYPs) play a crucial role in these metabolic pathways and the existence of functional CYP monooxygenases in brain is now well established. These enzymes are preferentially localized in the neuronal cells within the microsomal fraction and the inner membrane of mitochondria. Although low, the metabolism in situ could influence individual response to xenobiotics or produce reactive, toxic metabolites causing irreversible damage in the neuronal cells. The abundant presence of CYPs in selective cell populations within different regions of the brain has also suggested a role for these enzymes in brain physiology thus not restricted to xenobiotic-induced neurotoxicity. For instance, CYPs participate in the regulation of neurotransmitters and steroids and brain maintenance of cholesterol homeostasis. Recent advances support an additional role for these enzymes in the pathogenesis of psychiatric and neurodegenerative disorders such as depression, schizophrenia, and Alzheimer's and Parkinson's diseases. The characterization of brain CYP isoforms and their localization, the identification of their substrates and metabolic end-products will allow better understanding of the role of these enzymes in brain physiology, development and diseases.     

乳铁蛋白对铁代谢的影响及其在神经退行性疾病中的应用

乳铁蛋白是一种具有多种生理功能的铁结合性糖蛋白,是铁在机体内代谢及转运关键载体。目前,有关乳铁蛋白对神经退行性疾病的防治作用及应用研究已成为该领域的新热点。本文主要介绍了铁在机体内的代谢;铁转运蛋白-乳铁蛋白转运系统：铁转运主要是由转铁蛋白受体和乳铁蛋白受体介导的,铁转运入脑的途径主要是转铁蛋白-转铁蛋白受体途径,还有乳铁蛋白-乳铁蛋白受体途径及其他途径;铁对脑损伤的作用机制,其中铁参与的氧化应激反应以及铁代谢和铁转运相关基因的突变或缺失可能都是引起脑损伤的原因;最后简述乳铁蛋白在防治神经退行性疾病中最新的进展,乳铁蛋白修饰的纳米粒子可能是目前最有效治疗神经退行性疾病的方法之一。     

A new experimental animal for the study of age-related changes in serotonergic neuronal activity in the brain cortex

Calcium uptake by the cortical synaptosomes in a rodent (Fischer rat) and an insectivore shrew (Suncus murinus) was detected as a parameter reflecting molecular dysfunction of the aging brain. The change in calcium uptake by the cortical synaptosomes in both species was concomitant which showed less than half the capacity at 24 months old animals compared with those at 8 months old. On the other hand, 5-hydroxytryptamine binding and imipramine binding to the membrane fraction of aging rat brain cortex was not altered in terms of binding capacity along with aging, while, in Suncus, the binding of both serotonergic ligands declined with aging. In order to elucidate decreased serotonergic activity in human demented aged brain, together with declining activity in neurotransmitting systems detectable as a function of calcium uptake by the cortical synaptosomes, Suncus may be an appropriate animal model for studying physiological aging processes in the mammalian brain cortex.Special Issue Dedicated to Dr. Abel Lajtha.     

Presenilin-2 in the cynomolgus monkey brain: investigation of age-related changes

Localization of presenilin-2 (PS-2), a transmembrane protein implicated in early onset familial Alzheimers disease, was examined in the brains of 30 cynomolgus monkeys aged 4 to 36 years. Anti-PS-2 antibody N20, which recognizes PS-2 amino acid residues 2–20, and anti-PS-2 antibody C20, which recognizes PS-2 amino acid residues 535–554, stained mainly the cytoplasm of large pyramidal neurons and large neurites. This finding was also confirmed by double immunohistochemical investigations using N20 or C20 and anti-NeuN antibody. In the brain of the oldest monkey, swollen neurites containing senile plaques were immunostained with C20, but not with N20. Western blot analyses of microsomal fractions isolated from the brains of three adult monkeys revealed that much less PS-2 was present compared to presenilin-1 (PS-1). Age-related assessment of PS-2 in brain homogenates from young and adult monkeys showed that PS-2 levels and PS-2 subcellular localization were unchanged with increasing age. Because PS-2 expression was much less robust than that of PS-1, we conclude that PS-2 mainly localizes to large neurons and does not show so drastic age-related changes as PS-1.     

A comprehensive experimental study on material properties of human brain tissue

A comprehensive study on the biomechanical response of human brain tissue is necessary to investigate traumatic brain injury mechanisms. Published brain material property studies have been mostly performed under a specific type of loading, which is insufficient to develop accurate brain tissue constitutive equations. In addition, inconsistent or contradictory data in the literature made it impossible for computational model developers to create a single brain material model that can fit most, if not all, experimental results.     

Cerebral creatine kinase deficiency influences metabolite levels and morphology in the mouse brain: a quantitative in vivo 1H and 31P magnetic resonance study

Creatine kinase (CK)-catalysed ATP-phosphocreatine (PCr) exchange is considered to play a key role in energy homeostasis of the brain. This study assessed the metabolic and anatomical consequences of partial or complete depletion of this system in transgenic mice without cytosolic B-CK (B-CK-/-), mitochondrial ubiquitous CK (UbCKmit-/-), or both isoenzymes (CK -/-), using non-invasive quantitative magnetic resonance (MR) imaging and spectroscopy. MR imaging revealed an increase in ventricle size in a subset of B-CK-/- mice, but not in animals with UbCKmit or compound CK mutations. Mice lacking single CK isoenzymes had normal levels of high-energy metabolites and tissue pH. In the brains of CK double knockouts pH and ATP and Pi levels were also normal, even though PCr had become completely undetectable. Moreover, a 20-30% decrease was observed in the level of total creatine and a similar increase in the level of neuronal N-acetyl-aspartate compounds. Although CKs themselves are not evenly distributed throughout the CNS, these alterations were uniform and concordant across different brain regions. Changes in myo-inositol and glutamate peaks did appear to be mutation type and brain area specific. Our results challenge current models for the biological significance of the PCr-CK energy system and suggest a multifaceted role for creatine in the brain.     

Trace elements in human milk: Correlation with blood levels, inter-element correlations and changes in concentration during the first month of lactation

Using inductively coupled plasma mass spectrometry (ICP-MS) based analytical procedures, the concentration of several trace elements (Mn, As, Pb, Co, Ni, Cu, Zn and Se) was determined in human milk samples collected from a group of healthy lactating Portuguese women (n=44), both on the 2nd day postpartum (i.e., colostrum; n=34) and at 1 month postpartum (i.e., mature milk; n=19). Blood samples (n=44), collected on the 2nd day after parturition, were also analyzed for the same trace elements. No major correlations were observed between the levels of the analyzed trace elements in blood and colostrum samples. All the studied elements, except for Co, Pb and Ni, showed a significant trend for a decrease in concentration in milk during the first month of lactation. This trend was more pronounced for Zn and Se, whose levels decreased to approximately 23% and 44% of their initial mean concentration, respectively. With the exception of Co (r=0.607) and Zn (r=0.487), no significant correlations were observed when comparing the levels of each trace element between samples of colostrum and mature milk. Several inter-element correlations were found within each type of milk sample. The most significant were: (i) Se vs Cu (r=0.828) and Se vs Co (r=0.605) in colostrum samples and (ii) Ni vs Pb (r=0.756), Ni vs Mn (r=0.743) and Se vs Co (r=0.714) in mature milk samples. An inverse correlation between Zn and Se was also found in both types of milk sample; however, it only reached statistical significance for mature milk (r=-0.624).     

Brain banks: benefits,limitations and cautions concerning the use of post-mortem brain tissue for molecular studies

Brain banks are facilities providing an interface between generous donation of nervous tissues and research laboratories devoted to increase our understanding of the diseases of the nervous system, discover new diagnostic targets, and develop new strategies. Considering this crucial role, it is important to learn about the suitabilities, limitations and proper handling of individual brain samples for particular studies. Several factors may interfere with preservation of DNA, RNA, proteins and lipids, and, therefore, special care must be taken first to detect sub-optimally preserved tissues and second to provide adequate material for each specific purpose. Basic aspects related with DNA, RNA and protein preservation include agonal state, post-mortem delay, temperature of storage and procedures of tissue preservation. Examination of DNA and RNA preservation is best done by using bioanalyzer technologies instead of less sensitive methods such as agarose gels. Adequate RNA preservation is mandatory in RNA microarray studies and adequate controls are necessary for proper PCR validation. Like for RNA, the preservation of proteins is not homogeneous since some molecules are more vulnerable than others. This aspect is crucial in the study of proteins including expression levels and possible post-translational modifications. Similarly, the reliability of functional and enzymatic studies in human post-mortem brain largely depends on protein preservation. Much less is known about other aspects, such as the effects of putative deleterious factors on epigenetic events such as methylation of CpGs in gene promoters, nucleosome preservation, histone modifications, and conservation of microRNA species. Most brains are appropriate for morphological approaches but not all brains are useful for certain biochemical and molecular studies.     

Levels of amino acids in 52 discrete areas of postmortem brain of adult and aged humans

Summary In a series of studies we have analyzed the regional distribution of the free amino acid pool in 52 discrete areas of postmortem brain of adult and aged humans. Here we show the distribution of eleven amino acids: alanine, methionine, valine, leucine, isoleucine, glutamine, asparagine, lysine, arginine, ornithine, and histidine. As found previously for other amino acids, the distribution of these amino acids was seen to be heterogeneous, the level of the area of highest level being 3.4 to 10.7 times that of the area of the lowest level. On average we found a five- or six-fold difference in concentration between the highest and lowest level areas in the brain samples from adult and old respectively. The distribution patterns were found to be different for each amino acid; they were not similar even in the same class (amides, branched chain, basic amino acids), and they were different from those recently found in rat brain. Only a few changes, mostly increases, were found in the aged brain, such as increases in alanine and valine levels in cortical areas. In studies of changes in cerebral amino acid levels, the great regional heterogeneity of distribution has to be taken into account since changes in whole brain values may not reflect regional changes. The functional significance and the control of this regional heterogeneity are under investigation.     

Role of transferrin in iron uptake by the brain: a comparative study

Summary The role of specific transferrin (Tf) and Tf receptor interaction on brain capillary endothelial cells in iron transport from the plasma to the brain was investigated by using Tf from several species of animals labeled with ⁵⁹Fe and ¹²⁵I, and 15-day and adult rats. The rate of iron transfer was much greater in the 15-day rats. It was greatest with Tf from the mammals, rat, rabbit and human, but much lower with chicken ovotransferrin and quokka (a marsupial), toad, lizard, crocodile, and fish Tf. The uptake of Tf by the brain showed a similar pattern, except for a very high uptake of ovotransferrin (ovo Tf). Iron uptake by the femurs (a source of bone marrow) was also high with Tf from the mammalian species and low with the other types of Tf, but showed little change with aging of the animals. It is concluded that iron transport into the brain is dependent on the function of Tf receptors, probably on capillary endothelial cells, and that these receptors show the same type of species specificity as the receptors on immature erythroid cells. Also, the decrease in iron uptake by the brain as rats age from 15 days to adulthood is specific for the brain and is not a general effect of the aging process.Abbreviations Tf transferrin - ovo Tf ovotransferrin     

Biochemical Evidence of Selective Nerve Cell Changes in the Normal Ageing Human and Rat Brain

Abstract: Atrophy with ageing of human whole brain, entire temporal lobe, and caudate nucleus was assessed in autopsy specimens, by biochemical techniques. Only the caudate nucleus showed changes. Markers for several neurotransmitter systems were also examined for changes with age. In neocortex and temporal lobe of human brain, small decreases were detected in markers of cholinergic nerve terminals, whereas a large decrease (79%) occurred in the caudate nucleus. Findings were similar in striatum from 3–33-month-old rats. No change occurred in binding of [³H]quinuclidinyl benzilate by human samples. Markers of serotonergic terminals were also unchanged in human and rat brain. By contrast, binding of [³H]lysergic acid diethylamide and [³H]serotonin was decreased (32–81%) in human neocortex and temporal lobe, but not in caudate nucleus. A 43% loss of a marker of γ-aminobutyrate terminals occurred in human neocortex, while [³H]muscimol binding increased (179%). No changes were detected in markers of catecholamine synapses in temporal lobe or rat striatum. Hence, with human ageing there appears to be a loss of markers of γ-aminobutyrate neurones intrinsic to neocortex and acetylcholine cells intrinsic to the caudate nucleus, as well as a change in postsynaptic serotonin receptors in neocortex. These losses are accompanied by relative preservation of markers of ascending projections from basal forebrain and brain stem.     

The chemical characterization of melanin contained in substantia nigra of human brain

The pigment of substantia nigra human brain has been extracted by a mild procedure consisting of washes with phosphate buffer, methanol and incubation with SDS-proteinase. Pyrolisis gas chromatography mass spectrometry infrared spectrometry, termogravimetric analysis and elemental analysis were the techniques used for the chemical characterization. An indole moiety bound to a sulfur containing amino acid and to palmitic acid were the main aspects found in the structure. The presence of a 7% inorganic component was observed. This probably contains Fe, Cu, Zn and Cr which are also relevant, for the formation and the role of melanin in substantia nigra neurons. The fatty acid moiety is chemically bound to the indole structure as it was not eliminated by repeated methanol washing. The same situation occurs for the sulfur containing gropu. Considering these data and the most abundant molecules present in substantia nigra the precursor of neuromelanin seems to be a cysteinyl-cethecol, to which is then bound a palmityl group.     

A study of the polymorphism and ethnic distribution differences of human serum paraoxonase

The enzyme serum paraoxonase shows a polymorphism in Europeans which is governed by two alleles. The first allele has a gene frequency p_low of 0.716–0.777, and is manifested as a low activity group in homozygotes. More than 50% of all European test subjects can be included in this group. A second allele with a gene frequency q_high of 0.223–0.284 was found in typical European distributions and is manifested in both the form of a second heterozygotic and a third homozygotic group with high activities. The Hardy-Weinberg rule for a two-allele model is valid for the distribution. The gene frequency p_low of the first allele decreases as one moves from Europe in the direction of Africa and Asia. In typical Mongoloid and Negroid collectives, less than 10% of the population can be included in the low-activity group, a group which is not even demonstrable in the Aborigines of Australia. The serum paraoxonase of the Aborigine population shows unimodal distribution. The validity of the Hardy-Weinberg rule for a three-allele model must be rejected in all examined collectives. Human serum paraoxonase shows neither age-related changes in activity nor sex-dependent activity differences.     

Immunolocalization of tight junction proteins in the adult and developing human brain

The formation of endothelial tight junctions (TJs) is crucial in blood-brain barrier (BBB) differentiation, and the expression and targeting of TJ-associated proteins mark the beginning of BBB functions. Using confocal microscopy, this study analyzed endothelial TJs in adult human cerebral cortex and the fetal telencephalon and leptomeninges in order to compare the localization of two TJ-associated transmembrane proteins, occludin and claudin-5. In the arterioles and microvessels of adult brain, occludin and claudin-5 form continuous bands of endothelial immunoreactivity. During fetal development, occludin and claudin-5 immunoreactivity is first detected as a diffuse labeling of endothelial cytoplasm. Later, at 14 weeks, the immunosignal for both proteins shifts from the cytoplasm to the interface of adjacent endothelial cells, forming a linear, widely discontinuous pattern of immunoreactivity that achieves an adult-like appearance within a few weeks. These results demonstrate that occludin and claudin-5 expression is an early event in human brain development, followed shortly by assembly of both proteins at the junctional areas. This incremental process suggests more rapid establishment of the human BBB, consistent with its specific function of creating a suitable environment for neuron differentiation and neurite outgrowth during neocortical histogenesis.Electronic Supplementary Material Supplementary material is available in the online version of this article at http://dx.doi.org/10.1007/s00418-004-0665-1Daniela Virgintino and Mariella Errede contributed equally to this work     

Enkephalin dipeptidyl carboxypeptidase (enkephalinase) activity: selective radioassay, properties, and regional distribution in human brain

Abstract: The compound [³H-Tyr¹,D-Ala²,Lcu-OH⁵]enkephalin has been synthesised as a potentially selective substrate for enkephalin dipeptidyl carboxypcptidase ( enkephalinase ) activity in brain. lncubations in the presence of homogenates and particulate fractions from rodent and human brain result in the formation of [³H]Tyr-D-Ala-Gly, which can be conveniently isolated by polystyrene bead column chromatography. The enzyme activity responsible for the hydrolysis of the Gly³-Phe⁴ amide bond of this substrate displays close resemblance to that hydrolysing the natural enkephalins at the same level. In addition, enkephalinase activity characterised in postmortem human brain is closely similar to that in rodent brain, with regard to optimal pH and apparent affinities of various substrates and inhibitors, including the potent compound thiorphan. Enkephalinase activity is distributed in a highly heterogeneous fashion among regions of human brain, the highest levels being found in globus pallidus and pars reticulata of the substantia nigra. This distribution is poorly correlated with that of opiate receptor binding sites but displays some resemblance to that of reported Met5-enkephalin levels.     

Effects of chelators on iron uptake and release by the brain in the rat

The iron chelators desferrioxamine (DFO), pyridoxal isonicotinoyl hydrazone (PIH), 2,2-bipyridine, diethylenetriamine penta-acetic acid (DTPA) and 1,2 dimethyl-3-hydroxy pyrid-4-one (CP20) were analysed for their ability to change⁵⁹Fe uptake and release from the brain of 15- and 63-day rats either during or after intravenous injection of⁵⁹Fe-¹²⁵I-transferrin. DTPA was the only chelator unable to significantly reduce iron uptake into the brain of 15-day rats. This indicates that iron is not released from transferrin at the luminal surface of brain capillary endothelial cells. CP20 was able to reduce iron uptake in the brain by 85% compared to 28% with DFO. Only CP20 was able to significantly reduce brain iron uptake in 63 day rats. Once⁵⁹Fe had entered the brain no chelator used was able to mediate its release. All of the chelators except CP20 had similar effects on femur iron uptake as they did on brain uptake, suggesting similar iron uptake mechanisms. It is concluded that during the passage of transferrin-bound iron into the brain the iron is released from transferrin within endothelial cells after endocytosis of transferrin.     

Serotonin receptor of type 6 (5-HT6) in human prefrontal cortex and hippocampus post-mortem: An immunohistochemical and immunofluorescence study

Given the paucity of data on the distribution of serotonin (5-HT) receptors of type 6 (5-HT₆) in the human brain, the aim of this study was to investigate their distribution in postmortem human prefrontal cortex, striatum and hippocampus by either immunohistochemical or immunofluorescence techniques.