Wolfgang Knabe scite author profile

Epibranchial placodes and rhombencephalic neural crest provide precursor cells for the geniculate, petrosal, and nodose ganglia. In chick embryos and in Tupaia belangeri, apoptosis in rhombomeres 3 and 5 helps to select premigratory precursor cells and to segregate crest cell streams derived from the even-numbered rhombomeres. Much less is known about the patterns and functions of apoptosis in epibranchial placodes. We found that, in Tupaia belangeri, combined anlagen of the otic placode and epibranchial placode 1 transiently share a primordial low grade thickening with post-otic epibranchial placodes. Three-dimensional reconstructions reveal complementary, spatially, and temporally regulated apoptotic and proliferative events that demarcate the otic placode and epibranchial placode 1, and help to individualize three pairs of epibranchial placodes in a rostrocaudal sequence. Later, rostrocaudal waves of proliferation and apoptosis extend from dorsal to ventral parts of the placodes, paralleled by the dorsoventral progression of precursor cell delamination. These findings suggest a role for apoptosis during the process of neuroblast generation in the epibranchial placodes. Finally, apoptosis eliminates remnants of the placodes in the presence of late invading macrophages.

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Expression patterns of erythropoietin and its receptor in the developing midbrain

Knabe

Knerlich

Washausen

et al. 2004

Anatomy and Embryology

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The expression patterns of erythropoietin (EPO) and its receptor (EPOR) were investigated in the midbrain and in adjacent parts of the synencephalon and hindbrain of embryonic C57Bl mice. On embryonic (E) day 8 (E8), virtually all neuroepithelial cells expressed EPOR. After neural tube closure, subsets of these cells downregulated EPOR. In contrast, radial glial cells were EPOR-immunolabeled from E11 onwards. Simultaneously, subpopulations of early developing neurons upregulated EPO and expressed HIF-1, known to transcriptionally activate EPO. Three-dimensional reconstructions revealed subpopulations of EPO-expressing neurons: (1) in the trigeminal mesencephalic nucleus (TMN), (2) at the rostral transition of the midbrain and synencephalon, (3) in the basal plate of the midbrain, (4) in the trigeminal motor nucleus, and (5) in the trigeminal principal sensory nucleus. In the rostral midbrain and synencephalon, EPO-immunoreactive neurons were attached to EPOR-expressing radial glial cells. The identity of radial glial cells was proven by their immunoreactivity for antibodies against astrocyte-specific glutamate transporter, brain lipid-binding protein, and nestin. From E12.5 onwards EPOR was downregulated in radial glial cells. Viable neurons of the TMN continued to express EPO and upregulated EPOR. Our findings provide new evidence that components of the EPO system are present in distinct locations of the embryonic brain and, by interactions between neurons and radial glial cells as well as among clustered TMN neurons, may contribute to its morphogenesis. Whether the observed expression patterns of EPO and EPOR may reflect EPO-mediated trophic and/or antiapoptotic effects on neurons is discussed.

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“Lens Mitochondria” in the Retinal Cones of the Tree-shrew Tupaia belangeri

Knabe

Skatchkov²,

Kuhn³

1997

Vision Research

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In all mammals, the mitochondria of the cones of the retina are concentrated in the inner segment. Uniquely in tree-shrews (Tupaia, Scandentia, Mammalia), a "megamitochondrion" exhibiting highly specialized systems of densely packed cristae and a very electron dense matrix, is located apically in the inner segment. The ellipsoid is a solid body containing several megamitochondria and, towards its base, a large number of smaller mitochondria. The refractive index of isolated, but not oriented, inner segments of Tupaia belangeri is higher (XA = 1.405) than in any other mammal studied so far. The consistent geometrical pattern of the multilamellar crista-matrix systems, oriented longitudinally towards the outer segment, suggests an additional optical function of the megamitochondria.

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Hypoxia and hypoxia-inducible factor modulated gene expression in brain: involvement in neuroprotection and cell death

Kietzmann¹,

Knabe

Schmidt‐Kastner

2001

European Archives of Psychiatry and Clinical Neuroscience

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Hypoxia, due to impaired cerebral blood flow, has hazardous effects on brain structure and function. Therefore, mechanisms should exist to meet the needs for hypoxic adaptation via regulation of gene expression. Signaling between the O2 sensor and the regulator(s) of transcription is only partially characterized and requires regulatory transcription factors. Among these regulatory proteins, hypoxia-inducible factor-1 (HIF-1) appears to have a key role. HIF-1 modulates gene activity in response to low O2 tensions in the developing and in the adult brain. Moderate hypoxia may elicit autoprotective mechanisms or hypoxia-induced regulators can contribute to mechanisms leading to cell death. Moreover, reactivation of embryonic gene expression may occur after injury-induced hypoxia. Thus, analyses of embryonic and pathogenic models should help to understand how hypoxia-mediated proliferative/cell death processes are involved in brain development and in the pathogenesis of acute or chronic neurodegenerative brain diseases.

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Apoptosis contributes to placode morphogenesis in the posterior placodal area of mice

Washausen

Knabe

2012

Brain Struct Funct

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In the embryonic head of vertebrates, neurogenic and non-neurogenic ectodermal placodes arise from the panplacodal primordium. Whether and how growth processes of the ectodermal layer, changes in the transcriptional precursor cell profile, or positional changes among precursor cells contribute to interplacodal boundary formation is subject to intense investigation. We demonstrate that large scale apoptosis in the multiplacodal posterior placodal area (PPA) of C57BL/6 mice assists in the segregation of otic and epibranchial placodes. Complex patterns of interplacodal apoptosis precede and parallel the structural individualization of high-grade thickened placodes, with the fundamental separation between otic and epibranchial precursor cells being seemingly prevalent. Interplacodal apoptosis between the emerging epibranchial placodes, which express Neurogenin2 prior to their complete structural individualization, comes out most strongly between the epibranchial placodes 1 and 2. Apoptosis then moves from interplacodal to intraplacodal positions in dorsal and, with a delay, ventral parts of the epibranchial placodes. Intraplacodal apoptosis appears to exert corrective actions among premigratory neuroblasts, and helps to eliminate the epibranchial placodes. The present findings confirm and extend earlier observations in Tupaia belangeri (Washausen et al. in Dev Biol 278:86-102, 2005), regarded as an intermediate between primates and other eutherian orders. Having now available maps of apoptosis in the PPA of embryonic mice, further investigations into the functions of inter- and intraplacodal apoptosis can be carried out in an experimentally and genetically more accessible mammalian model organism.

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Wolfgang Knabe

Apoptosis and proliferation in developing, mature, and regressing epibranchial placodes

Expression patterns of erythropoietin and its receptor in the developing midbrain

“Lens Mitochondria” in the Retinal Cones of the Tree-shrew Tupaia belangeri

Hypoxia and hypoxia-inducible factor modulated gene expression in brain: involvement in neuroprotection and cell death

Apoptosis contributes to placode morphogenesis in the posterior placodal area of mice

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