myelin-basic-protein and Deafness

myelin-basic-protein has been researched along with Deafness* in 2 studies

Other Studies

2 other study(ies) available for myelin-basic-protein and Deafness

Article	Year
Schwann cells revert to non-myelinating phenotypes in the deafened rat cochlea. The European journal of neuroscience, 2007, Volume: 26, Issue:7 Loss of sensory hair cells within the cochlea results in a permanent sensorineural hearing loss and initiates the gradual degeneration of spiral ganglion neurons (SGNs) - the primary afferent neurons of the cochlea. While these neurons are normally myelinated via Schwann cells, loss of myelin occurs as a precursor to neural degeneration. However, the relationship between demyelination and the status of Schwann cells in deafness is not well understood. We used a marker of peripheral myelin (myelin protein zero; P0) and a marker of Schwann cells (S100) to determine the temporal sequence of myelin and Schwann cell loss as a function of duration of deafness. Rat pups were systemically deafened for periods ranging from 2 weeks to greater than 6 months by co-administration of frusemide and gentamicin. Cochleae were cryosectioned and quantitative immunohistochemistry used to determine the extent of P0 and S100 labelling within the peripheral processes, SGN soma and their central processes within the modiolus. SGN density was also determined for each cochlear turn. P0 labelling decreased throughout the cochlea with increasing duration of deafness. The reduction in P0 labelling occurred at a faster rate than the SGN loss. In contrast, S100 labelling was not significantly reduced compared with age-matched controls in any cochlear region until 6 months post-deafening. These results suggest that Schwann cells may revert to non-myelinating phenotypes in response to deafness and exhibit greater survival traits than SGNs. The potential clinical significance of these findings for cochlear implants is discussed. Topics: Animals; Animals, Newborn; Cochlea; Deafness; Disease Models, Animal; Evoked Potentials, Auditory, Brain Stem; Furosemide; Gene Expression Regulation; Gentamicins; Glial Fibrillary Acidic Protein; Myelin Basic Protein; Myelin P0 Protein; Neurofilament Proteins; Neurons; Rats; Rats, Wistar; S100 Proteins; Schwann Cells; Spiral Ganglion; Time Factors	2007
Thyroid hormone deficiency before the onset of hearing causes irreversible damage to peripheral and central auditory systems. Journal of neurophysiology, 2000, Volume: 83, Issue:5 Both a genetic or acquired neonatal thyroid hormone (TH) deficiency may result in a profound mental disability that is often accompanied by deafness. The existence of various TH-sensitive periods during inner ear development and general success of delayed, corrective TH treatment was investigated by treating pregnant and lactating rats with the goitrogen methimazole (MMI). We observed that for the establishment of normal hearing ability, maternal TH, before fetal thyroid gland function on estrus days 17-18, is obviously not required. Within a crucial time between the onset of fetal thyroid gland function and the onset of hearing at postnatal day 12 (P12), any postponement in the rise of TH-plasma levels, as can be brought about by treating lactating mothers with MMI, leads to permanent hearing defects of the adult offspring. The severity of hearing defects that were measured in 3- to 9-mo-old offspring could be increased with each additional day of TH deficiency during this critical period. Unexpectedly, the active cochlear process, assayed by distortion product otoacoustic emissions (DPOAE) measurements, and speed of auditory brain stem responses, which both until now were not thought to be controlled by TH, proved to be TH-dependent processes that were damaged by a delay of TH supply within this critical time. In contrast, no significant differences in the gross morphology and innervation of the organ of Corti or myelin gene expression in the auditory system, detected as myelin basic protein (MBP) and proteolipid protein (PLP) mRNA using Northern blot approach, were observed when TH supply was delayed for few days. These classical TH-dependent processes, however, were damaged when TH supply was delayed for several weeks. These surprising results may suggest the existence of different TH-dependent processes in the auditory system: those that respond to corrective TH supply (e.g., innervation and morphogenesis of the organ of Corti) and those that do not, but require T3 activity during a very tight time window (e.g. , active cochlear process, central processes). Topics: Animals; Auditory Threshold; Cochlea; Deafness; Drug Administration Schedule; Evoked Potentials, Auditory, Brain Stem; Female; Fetus; Gene Expression; Hypothyroidism; Immunohistochemistry; Maternal-Fetal Exchange; Methimazole; Myelin Basic Protein; Myelin Proteolipid Protein; Organ of Corti; Otoacoustic Emissions, Spontaneous; Pregnancy; Rats; Rats, Wistar; Reaction Time; RNA, Messenger; Thyroid Hormones	2000

Article

Year

Schwann cells revert to non-myelinating phenotypes in the deafened rat cochlea.

The European journal of neuroscience, 2007, Volume: 26, Issue:7

Loss of sensory hair cells within the cochlea results in a permanent sensorineural hearing loss and initiates the gradual degeneration of spiral ganglion neurons (SGNs) - the primary afferent neurons of the cochlea. While these neurons are normally myelinated via Schwann cells, loss of myelin occurs as a precursor to neural degeneration. However, the relationship between demyelination and the status of Schwann cells in deafness is not well understood. We used a marker of peripheral myelin (myelin protein zero; P0) and a marker of Schwann cells (S100) to determine the temporal sequence of myelin and Schwann cell loss as a function of duration of deafness. Rat pups were systemically deafened for periods ranging from 2 weeks to greater than 6 months by co-administration of frusemide and gentamicin. Cochleae were cryosectioned and quantitative immunohistochemistry used to determine the extent of P0 and S100 labelling within the peripheral processes, SGN soma and their central processes within the modiolus. SGN density was also determined for each cochlear turn. P0 labelling decreased throughout the cochlea with increasing duration of deafness. The reduction in P0 labelling occurred at a faster rate than the SGN loss. In contrast, S100 labelling was not significantly reduced compared with age-matched controls in any cochlear region until 6 months post-deafening. These results suggest that Schwann cells may revert to non-myelinating phenotypes in response to deafness and exhibit greater survival traits than SGNs. The potential clinical significance of these findings for cochlear implants is discussed.

Topics: Animals; Animals, Newborn; Cochlea; Deafness; Disease Models, Animal; Evoked Potentials, Auditory, Brain Stem; Furosemide; Gene Expression Regulation; Gentamicins; Glial Fibrillary Acidic Protein; Myelin Basic Protein; Myelin P0 Protein; Neurofilament Proteins; Neurons; Rats; Rats, Wistar; S100 Proteins; Schwann Cells; Spiral Ganglion; Time Factors

2007

Thyroid hormone deficiency before the onset of hearing causes irreversible damage to peripheral and central auditory systems.

Journal of neurophysiology, 2000, Volume: 83, Issue:5

Both a genetic or acquired neonatal thyroid hormone (TH) deficiency may result in a profound mental disability that is often accompanied by deafness. The existence of various TH-sensitive periods during inner ear development and general success of delayed, corrective TH treatment was investigated by treating pregnant and lactating rats with the goitrogen methimazole (MMI). We observed that for the establishment of normal hearing ability, maternal TH, before fetal thyroid gland function on estrus days 17-18, is obviously not required. Within a crucial time between the onset of fetal thyroid gland function and the onset of hearing at postnatal day 12 (P12), any postponement in the rise of TH-plasma levels, as can be brought about by treating lactating mothers with MMI, leads to permanent hearing defects of the adult offspring. The severity of hearing defects that were measured in 3- to 9-mo-old offspring could be increased with each additional day of TH deficiency during this critical period. Unexpectedly, the active cochlear process, assayed by distortion product otoacoustic emissions (DPOAE) measurements, and speed of auditory brain stem responses, which both until now were not thought to be controlled by TH, proved to be TH-dependent processes that were damaged by a delay of TH supply within this critical time. In contrast, no significant differences in the gross morphology and innervation of the organ of Corti or myelin gene expression in the auditory system, detected as myelin basic protein (MBP) and proteolipid protein (PLP) mRNA using Northern blot approach, were observed when TH supply was delayed for few days. These classical TH-dependent processes, however, were damaged when TH supply was delayed for several weeks. These surprising results may suggest the existence of different TH-dependent processes in the auditory system: those that respond to corrective TH supply (e.g., innervation and morphogenesis of the organ of Corti) and those that do not, but require T3 activity during a very tight time window (e.g. , active cochlear process, central processes).

Topics: Animals; Auditory Threshold; Cochlea; Deafness; Drug Administration Schedule; Evoked Potentials, Auditory, Brain Stem; Female; Fetus; Gene Expression; Hypothyroidism; Immunohistochemistry; Maternal-Fetal Exchange; Methimazole; Myelin Basic Protein; Myelin Proteolipid Protein; Organ of Corti; Otoacoustic Emissions, Spontaneous; Pregnancy; Rats; Rats, Wistar; Reaction Time; RNA, Messenger; Thyroid Hormones

2000