Ralf Peter Meyer scite author profile

BackgroundEssentially all knowledge about adult hippocampal neurogenesis in humans still comes from one seminal study by Eriksson et al. in 1998, although several others have provided suggestive findings. But only little information has been available in how far the situation in animal models would reflect the conditions in the adult and aging human brain. We therefore here mapped numerous features associated with adult neurogenesis in rodents in samples from human hippocampus across the entire lifespan. Such data would not offer proof of adult neurogenesis in humans, because it is based on the assumption that humans and rodents share marker expression patterns in adult neurogenesis. Nevertheless, together the data provide valuable information at least about the presence of markers, for which a link to adult neurogenesis might more reasonably be assumed than for others, in the adult human brain and their change with increasing age.Methods and FindingsIn rodents, doublecortin (DCX) is transiently expressed during adult neurogenesis and within the neurogenic niche of the dentate gyrus can serve as a valuable marker. We validated DCX as marker of granule cell development in fetal human tissue and used DCX expression as seed to examine the dentate gyrus for additional neurogenesis-associated features across the lifespan. We studied 54 individuals and detected DCX expression between birth and 100 years of age. Caveats for post-mortem analyses of human tissues apply but all samples were free of signs of ischemia and activated caspase-3. Fourteen markers related to adult hippocampal neurogenesis in rodents were assessed in DCX-positive cells. Total numbers of DCX expressing cells declined exponentially with increasing age, and co-expression of DCX with the other markers decreased. This argued against a non-specific re-appearance of immature markers in specimen from old brains. Early postnatally all 14 markers were co-expressed in DCX-positive cells. Until 30 to 40 years of age, for example, an overlap of DCX with Ki67, Mcm2, Sox2, Nestin, Prox1, PSA-NCAM, Calretinin, NeuN, and others was detected, and some key markers (Nestin, Sox2, Prox1) remained co-expressed into oldest age.ConclusionsOur data suggest that in the adult human hippocampus neurogenesis-associated features that have been identified in rodents show patterns, as well as qualitative and quantitative age-related changes, that are similar to the course of adult hippocampal neurogenesis in rodents. Consequently, although further validation as well as the application of independent methodology (e.g. electron microscopy and cell culture work) is desirable, our data will help to devise the framework for specific research on cellular plasticity in the aging human hippocampus.

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Defining the actual sensitivity and specificity of the neurosphere assay in stem cell biology

Singeç

et al. 2006

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For more than a decade the 'neurosphere assay' has been used to define and measure neural stem cell (NSC) behavior, with similar assays now used in other organ systems and in cancer. We asked whether neurospheres are clonal structures whose diameter, number and composition accurately reflect the proliferation, self-renewal and multipotency of a single founding NSC. Using time-lapse video microscopy, coculture experiments with genetically labeled cells, and analysis of the volume of spheres, we observed that neurospheres are highly motile structures prone to fuse even under ostensibly 'clonal' culture conditions. Chimeric neurospheres were prevalent independent of ages, species and neural structures. Thus, the intrinsic dynamic of neurospheres, as conventionally assayed, introduces confounders. More accurate conditions (for example, plating a single cell per miniwell) will be crucial for assessing clonality, number and fate of stem cells. These cautions probably have implications for the use of 'cytospheres' as an assay in other organ systems and with other cell types, both normal and neoplastic.

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Expression and Function of Cytochrome P450 in Brain Drug Metabolism

Meyer¹,

Gehlhaus²,

Knoth³

et al. 2007

CDM

130

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Cytochrome P450 (CYP, P450) is the collective term for a superfamily of heme-containing membrane proteins responsible for the metabolism of approximately 70 - 80 % of clinically used drugs. Besides the liver and other peripheral organs, P450 isoforms are expressed in glial cells and neurons of the brain. To enlighten their function and significance is a topic of high interest, as most of the neuroactive drugs used in therapy today are not only substrates, but also inducers of brain P450s with far reaching consequences. First of all, brain P450s are regulated differentially from those in liver. The availability of the prosthetic heme group appears to be essential for correct membrane insertion and enzymatic functionality of brain P450s. Furthermore, although not contributing to body's overall drug metabolism, brain P450s fulfil particular functions within specific cell types of the brain. In astrocytes of brain's border lines P450 isoforms are expressed at very high level. They form a metabolic barrier regulating drugs' influx, modulate blood-flow regulation, and act as signalling enzymes in inflammation. In neurons, however, P450s apparently have different function. In specified brain regions such as hypothalamus, hippocampus and striatum they provide signalling molecules like steroids and fatty acids necessary for neuronal outgrowth and maintenance. Induction of these P450s by neuroactive drugs can alter steroid hormone signalling directly in drug target cells, which may cause clinically relevant side effects like reproductive disorders and sexual or mental dysfunction. The understanding of brain P450 function appears to be of major interest in long-term drug mediated therapy of neurological diseases.

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Cytochrome P450 CYP1A1 Accumulates in the Cytosol of Kidney and Brain and Is Activated by Heme

2002

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Anti‐epileptic drug phenytoin enhances androgen metabolism and androgen receptor expression in murine hippocampus

Meyer

Hagemeyer

Knoth

et al. 2005

Journal of Neurochemistry

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Epilepsy is very often related to strong impairment of neuronal networks, particularly in the hippocampus. Previous studies of brain tissue have demonstrated that long-term administration of the anti-epileptic drug (AED) phenytoin leads to enhanced metabolism of testosterone mediated by cytochrome P450 (CYP) isoforms. Thus, we speculate that AEDs affect androgen signalling in the hippocampus. In the present study, we investigated how the AED phenytoin influences the levels of testosterone, 17b-oestradiol, and androgen receptor (AR) in the hippocampus of male C57Bl/6J mice. Phenytoin administration led to a 61.24% decreased hippocampal testosterone level as compared with controls, while serum levels were slightly enhanced. 17b-Oestradiol serum level was elevated 2.6-fold. Concomitantly, the testosterone metabolizing CYP isoforms CYP3A11 and CYP19 (aromatase) have been found to be induced 2.4-and 4.2-fold, respectively. CYP3A-mediated depletion of testosterone-forming 2b-, and 6b-hydroxytestosterone was significantly enhanced. Additionally, AR expression was increased 2-fold (mRNA) and 1.8-fold (protein), predominantly in the CA1 region. AR was shown to concentrate in nuclei of CA1 pyramidal neurons. We conclude that phenytoin affects testosterone metabolism via induction of CYP isoforms. The increased metabolism of testosterone leading to augmented androgen metabolite formation most likely led to enhanced expression of CYP19 and AR in hippocampus. Phenytoin obviously modulates the androgen signalling in the hippocampus.

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Ralf Peter Meyer

Murine Features of Neurogenesis in the Human Hippocampus across the Lifespan from 0 to 100 Years

Defining the actual sensitivity and specificity of the neurosphere assay in stem cell biology

Expression and Function of Cytochrome P450 in Brain Drug Metabolism

Cytochrome P450 CYP1A1 Accumulates in the Cytosol of Kidney and Brain and Is Activated by Heme

Anti‐epileptic drug phenytoin enhances androgen metabolism and androgen receptor expression in murine hippocampus

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