Faculty Opinions recommendation of The nuclear DNA base 5-hydroxymethylcytosine is present in Purkinje neurons and the brain.

Sampling of large-sized brains (eg, dog, primate) for microscopic examination is frequently inadequate to detect localized neurotoxic injury. Furthermore, the examination of H&E-stained sections alone will often be insufficient for the detection of subtle neuropathogic alteration. It is imperative for any pathologist evaluating brain sections to have knowledge of microscopic neuroanatomy and to also have some understanding of basic neurochemistry. When a focus of degeneration is detected within the brain, the pathologist needs to ascertain not only the specific anatomic location of this focus but also the neuroanatomic regions that project to and receive output from the injured focus. Because of the complexity of brain circuitry and the fact that the brain contains many distinctive neuron populations, many more brain sections are required for adequate microscopic evaluation than for any other body organ. Deciding which and how many areas should be examined, microscopically, from a large size brain is often problematic. Although any sampling protocol will be influenced by what is known about the test chemical, it has been well established that certain regions of the brain (eg, hippocampus and other components of the limbic system, basal ganglia, Purkinje neurons) are more susceptible than others to a variety of physical, metabolic, and chemical insults. Knowledge of these regional sensitivities will assist in guiding the pathologist in the development of an adequate sampling protocol.

Download Full-text

LOW LEVEL INCORPORATION OF TRITIATED THYMIDINE INTO THE NUCLEAR DNA OF PURKINJE NEURONS OF ADULT MICE

Cell Proliferation ◽

10.1111/j.1365-2184.1979.tb00167.x ◽

1979 ◽

Vol 12 (4) ◽

pp. 445-451

Author(s):

I. L. Cameron ◽

Mary R. H. Pool ◽

T. R. Hoage

Keyword(s):

Nuclear Dna ◽

Tritiated Thymidine ◽

Purkinje Neurons ◽

Low Level ◽

Adult Mice

Download Full-text

Mitochondrial DNA: a blind spot in neuroepigenetics

BioMolecular Concepts ◽

10.1515/bmc-2011-0058 ◽

2012 ◽

Vol 3 (2) ◽

pp. 107-115 ◽

Cited By ~ 30

Author(s):

Hari Manev ◽

Svetlana Dzitoyeva ◽

Hu Chen

Keyword(s):

Mitochondrial Dna ◽

Nuclear Dna ◽

Blind Spot ◽

Dna Methyltransferases ◽

Molecular Neuroscience ◽

Dna Modifications ◽

System Physiology ◽

Near Future ◽

First Time ◽

The Brain

AbstractNeuroepigenetics, which includes nuclear DNA modifications, such as 5-methylcytosine and 5-hydroxymethylcytosine and modifications of nuclear proteins, such as histones, is emerging as the leading field in molecular neuroscience. Historically, a functional role for epigenetic mechanisms, including in neuroepigenetics, has been sought in the area of the regulation of nuclear transcription. However, one important compartment of mammalian cell DNA, different from nuclear DNA but equally important for physiological and pathological processes (including in the brain), mitochondrial DNA has for the most part not had a systematic epigenetic characterization. The importance of mitochondria and mitochondrial DNA (particularly its mutations) in central nervous system physiology and pathology has long been recognized. Only recently have the mechanisms of mitochondrial DNA methylation and hydroxymethylation, including the discovery of mitochondrial DNA-methyltransferases and the presence and functionality of 5-methylcytosine and 5-hydroxymethylcytosine in mitochondrial DNA (e.g., in modifying the transcription of mitochondrial genome), been unequivocally recognized as a part of mammalian mitochondrial physiology. Here, we summarize for the first time evidence supporting the existence of these mechanisms and propose the term ‘mitochondrial epigenetics’ to be used when referring to them. Currently, neuroepigenetics does not include mitochondrial epigenetics – a gap that we expect to close in the near future.

Download Full-text

Adult Bone Marrow-Derived Cell Fusion with Cardiomyocytes and Purkinje Neurons in Response to Irradiation but Not in Steady State.

Blood ◽

10.1182/blood.v104.11.3604.3604 ◽

2004 ◽

Vol 104 (11) ◽

pp. 3604-3604

Author(s):

Jens M. Nygren ◽

Simon Stott ◽

Karina Liuba ◽

Martin Breitbach ◽

Willhelm Röll ◽

...

Keyword(s):

Bone Marrow ◽

Steady State ◽

Cell Fusion ◽

Hematopoietic Cell ◽

Purkinje Neurons ◽

Therapeutic Modality ◽

Whole Body ◽

Cell Lineages ◽

The Brain

Abstract Several recent studies have suggested that bone marrow (BM) cells can contribute to non-hematopoietic cell lineages through cell fusion rather than transdiffentiation. As this phenomenon has been observed in multiple organs, including the brain and heart, without prior infliction of organ-specific insults, it has been proposed that BM cells might contribute to replacement of non-hematopoietic cell lineages during steady state, and that BM transplantation might be developed as a therapeutic modality in diseases of these organs. However, as all observations of BM-derived cell fusion in vivo have been made in lethally irradiated mice reconstituted with genetically marked BM cells, we addressed to what degree cell fusion occurs normally and/or in response to whole body irradiation. To be able to distinguish between these possibilities we used c-kit deficient (w41/w41) mice, which unlike wild type mice do not require irradiation-induced myeloablation to facilitate reconstitution of transplanted BM cells. Noteworthy, no BM-derived cell fusion events were observed in the brain (purkinje neurons) or heart (cardiomyocytes) when unconditioned w41/w41 mice were reconstituted with beta actin GFP transgenic BM cells. In striking contrast, following whole body irradiation (875 rad), BM-derived cell fusion was observed in recipient cardiomyocytes and purkinje neurons of all BM transplanted mice. Thus, spontaneous adult BM-derived cell fusion does not occur in steady state but is potently facilitated by irradiation-induced injuries to the organs in which cell fusion occurs.

Download Full-text

Depletion of Intracellular Zinc from Neurons by Use of an Extracellular Chelator In Vivo and In Vitro

Journal of Histochemistry & Cytochemistry ◽

10.1177/002215540205001210 ◽

2002 ◽

Vol 50 (12) ◽

pp. 1659-1662 ◽

Cited By ~ 58

Author(s):

Christopher J. Frederickson ◽

Sang W. Suh ◽

Jae-Young Koh ◽

Yoo K. Cha ◽

Richard B. Thompson ◽

...

Keyword(s):

General Result ◽

Cortical Neurons ◽

Zinc Ion ◽

Purkinje Neurons ◽

Intracellular Zinc ◽

Ion Efflux ◽

Intracellular Compartments ◽

The Brain

The membrane-impermeable chelator CaEDTA was introduced extracellularly among neurons in vivo and in vitro for the purpose of chelating extracellular Zn2+. Unexpectedly, this treatment caused histochemically reactive Zn2+ in intracellular compartments to drop rapidly. The same general result was seen with intravesicular Zn2+, which fell after CaEDTA infusion into the lateral ventricle of the brain, with perikaryal Zn2+ in Purkinje neurons (in vivo) and with cortical neurons (in vitro). These findings suggest either that the volume of zinc ion efflux and reuptake is higher than previously suspected or that EDTA can enter cells and vesicles. Caution is therefore warranted in attempting to manipulate extracellular or intracellular Zn2+ selectively.

Download Full-text

Age-dependent dormant resident progenitors are stimulated by injury to regenerate Purkinje neurons

eLife ◽

10.7554/elife.39879 ◽

2018 ◽

Vol 7 ◽

Cited By ~ 3

Author(s):

N Sumru Bayin ◽

Alexandre Wojcinski ◽

Aurelien Mourton ◽

Hiromitsu Saito ◽

Noboru Suzuki ◽

...

Keyword(s):

Purkinje Neurons ◽

New Paradigm ◽

Perinatal Brain Injury ◽

Cerebellar Function ◽

Efficient Regeneration ◽

Age Dependent ◽

Cerebellum Development ◽

And Function ◽

The Brain ◽

Normal Cerebellum

Outside of the neurogenic niches of the brain, postmitotic neurons have not been found to undergo efficient regeneration. We demonstrate that mouse Purkinje cells (PCs), which are born at midgestation and are crucial for development and function of cerebellar circuits, are rapidly and fully regenerated following their ablation at birth. New PCs are produced from immature FOXP2+ Purkinje cell precursors (iPCs) that are able to enter the cell cycle and support normal cerebellum development. The number of iPCs and their regenerative capacity, however, diminish soon after birth and consequently PCs are poorly replenished when ablated at postnatal day five. Nevertheless, the PC-depleted cerebella reach a normal size by increasing cell size, but scaling of neuron types is disrupted and cerebellar function is impaired. Our findings provide a new paradigm in the field of neuron regeneration by identifying a population of immature neurons that buffers against perinatal brain injury in a stage-dependent process.

Download Full-text