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Journal of the Association for Research in Otolaryngology

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01.12.2010

Divergent Aging Characteristics in CBA/J and CBA/CaJ Mouse Cochleae

verfasst von: Kevin K. Ohlemiller, Ashley R. Dahl, Patricia M. Gagnon

Erschienen in: Journal of the Association for Research in Otolaryngology | Ausgabe 4/2010

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Abstract

Two inbred mouse strains, CBA/J and CBA/CaJ, have been used nearly interchangeably as ‘good hearing’ standards for research in hearing and deafness. We recently reported, however, that these two strains diverge after 1 year of age, such that CBA/CaJ mice show more rapid elevation of compound action potential (CAP) thresholds at high frequencies (Ohlemiller, Brain Res. 1277: 70–83, 2009). One contributor is progressive decline in endocochlear potential (EP) that appears only in CBA/CaJ. Here, we explore the cellular bases of threshold and EP disparities in old CBA/J and CBA/CaJ mice. Among the major findings, both strains exhibit a characteristic age (∼18 months in CBA/J and 24 months in CBA/CaJ) when females overtake males in sensitivity decline. Strain differences in progression of hearing loss are not due to greater hair cell loss in CBA/CaJ, but instead appear to reflect greater neuronal loss, plus more pronounced changes in the lateral wall, leading to EP decline. While both male and female CBA/CaJ show these pathologies, they are more pronounced in females. A novel feature that differed sharply by strain was moderate loss of outer sulcus cells (or ‘root’ cells) in spiral ligament of the upper basal turn in old CBA/CaJ mice, giving rise to deep indentations and void spaces in the ligament. We conclude that CBA/CaJ mice differ both quantitatively and qualitatively from CBA/J in age-related cochlear pathology, and model different types of presbycusis.

Adams JC, Schulte BA (1997) Histopathologic observations of the aging gerbil cochlea. Hear Res 104:101–111CrossRefPubMed

Bohne BA, Gruner MM, Harding GW (1990) Morphological correlates of aging in the chinchilla cochlea. Hear Res 48:79–91CrossRefPubMed

Bult CJ, Eppig JT, Kadin JA, Richardson JE, Blake JA (2008) The mouse genome database (MGD): mouse biology and model systems. Nucleic Acids Res 36:D724–D728CrossRefPubMed

Charitidi K, Meltser I, Tahera Y, Canlon B (2009) Functional responses of estrogen receptors in the male and female auditory system. Hear Res 252:71–78CrossRefPubMed

Cohen GM, Park JC, Grasso JS (1990) Comparison of demyelination and neural degeneration in spiral and Scarpa's ganglion of C57BL/6 mice. J Electron Microsc Tech 15:165–172CrossRefPubMed

Covell WP, Rogers JB (1957) Pathologic changes in the inner ear of senile guinea pigs. Laryngoscope 67:118–129CrossRefPubMed

Di Girolamo S, Quaranta N, Picciotti P, Torsello A, Wolf F (2001) Age-related histopathological changes of the stria vascularis: an experimental model. Audiology 40:322–326CrossRefPubMed

Diaz RC, Vazquez AE, Dou H, Wei D, Cardell EL, Lingrel J, Shull GE, Doyle KJ, Yamoah EN (2007) Conservation of hearing by simultaneous mutation of Na, K-ATPase and NKCCl. J Assoc Res Otolaryngol 8:422–434CrossRefPubMed

Duvall AJ (1969) The ultrastructure of the external sulcus in the guinea pig cochlear duct. Laryngoscope 79:1–29CrossRefPubMed

El-Badry MM, McFadden SL (2009) Evaluation of inner hair cell and nerve fiber loss as sufficient pathologies underlying auditory neuropathy. Hear Res 255:84–90CrossRefPubMed

Erway Lc, Willott JF, Archer JR, Harrison DE (1993) Genetics of age-related hearing loss in mice: I. Inbred and F1 hybrid strains. Hear Res 65:125–132CrossRefPubMed

Felder E, Schrott-Fischer A (1995) Quantitative evaluation of myelinated nerve fibers in cochlea of humans with age-related high-tone hearing loss. Hear Res 91:19–32CrossRefPubMed

Fernandez EA, Ohlemiller KK, Gagnon PM, Clark WW (2010) Protection against noise-induced hearing loss in young CBA/J mice by low-dose kanamycin. J Assoc Res Otolaryngol 11:235–244CrossRefPubMed

Fox RR, Witham BA, Neleski LA, (Eds.) 1997. Handbook of genetically standardized JAX mice. The Jackson Laboratory, Bar Harbor ME.

Frisina RD (2009) Age-related hearing loss: ear and brain mechanisms. Ann NY Acad Sci 1170:708–717CrossRefPubMed

Gates GA, Mills JH (2005) Presbycusis. Lancet 366:1111–1120CrossRefPubMed

Gates GA, Couropmitree NN, Myers RH (1999) Genetic associations in age-related hearing thresholds. Arch Otolaryngol Head Neck Surg 125:654–659PubMed

Gratton MA, Schulte BA (1995) Alterations in microvasculature are associated with atrophy of the stria vascularis in quiet-aged gerbils. Hear Res 82:44–52CrossRefPubMed

Gratton MA, Schmiedt RA, Schulte BA (1996) Age-related decreases in endocochlear potential are associated with vascular abnormalities in the stria vascularis. Hear Res 102:181–190CrossRefPubMed

Gratton MA, Smyth BJ, Lam CF, Boettcher FA, Schmiedt RA (1997) Decline in the endocochlear potential corresponds to decreased Na, K-ATPase activity in the lateral wall of quiet-aged gerbils. Hear Res 108:9–16CrossRefPubMed

Hederstierna C, Hultcrantz M, Collins A, Rosenhall U (2007) Hearing in women at menopause: prevalence of hearing loss, audiometric configuration and relation to hormone replacement therapy. Acta Otolaryngol 27:149–155CrossRef

Henry KR (1983) Ageing and audition. In: Willott JF (ed) The auditory psychobiology of the mouse. Thomas, Springfield, pp 470–494

Henry KR (2004) Males lose hearing earlier in mouse models of late-onset age-related hearing loss; females lose hearing earlier in mouse models of early-onset hearing loss. Hear Res 190:141–148CrossRefPubMed

Henry KR, McGinn MD (1992) The mouse as a model for human audition. A review of literature. Audiology 31:181–189CrossRefPubMed

Hequembourg S, Liberman MC (2001) Spiral ligament pathology: a major aspect of age-related cochlear degeneration in C57BL/6 mice. J Assoc Res Otolaryngol 2:118–129PubMed

Hirose K, Liberman MC (2003) Lateral wall histopathology and endocochlear potential in the noise-damaged mouse cochlea. J Assoc Res Otolaryngol 4:339–352CrossRefPubMed

Ishiyama G, Tokita J, Lopez I, Tang Y, Ishiyama A (2007) Unbiased stereological estimation of the spiral ligament and stria vascularis volumes in aging and Meniere's disease using archival human temporal bones. J Assoc Res Otolaryngol 8:8–17CrossRefPubMed

Jagger DJ, Nevill G, Forge A (2010) The membrane properties of cochlear root cells are consistent with roles in potassium recirculation and spatial buffering. JARO 11:435–448.

Jerger J, Chmiel R, Stach B, Spretnjak M (1993) Gender affects audiometric shape in presbycusis. J Am Acad Audiol 4:42–49PubMed

Johnsson L-G, Hawkins JE (1972) Vascular changes in the human ear associated with aging. Ann Otol 81:364–376

Konig O, Ruttiger L, Muller M, Zimmermann U, Erdmann B, Kalbacher H, Gross M, Knipper M (2008) Estrogen and the inner ear: megalin knockout mice suffer progressive hearing loss. FASEB J 22:410–417CrossRefPubMed

Kujawa SG, Liberman MC (2009) Adding insult to injury: cochlear nerve degeneration after 'temporary' noise-induced hearing loss. J Neurosci 29:14077–14085CrossRefPubMed

Kusunoki T, Cureoglu S, Schachern PA, Baba K, Karyia S, Paparella MM (2004) Age-related histopathologic changes in the human cochlea: a temporal bone study. Arch Otolaryngol Head Neck Surg 131:897–903CrossRef

Lang H, Schulte BA, Schmiedt RA (2002) Endocochlear potentials and compound action potential recovery: functions in the C57BL/6J mouse. Hear Res 172:118–126CrossRefPubMed

Lang H, Schulte BA, Schmiedt RA (2003) Effects of chronic furosemide treatment and age on cell division in the adult gerbil inner ear. J Assoc Res Otolaryngol 4:164–175CrossRefPubMed

Lee JH, Marcus DC (2001) Estrogen acutely inhibits ion transport by stria vascularis. Hear Res 158:123–130CrossRefPubMed

Li H-S (1992) Genetic influences on susceptibility of the auditory system to aging and environmental factors. Scand Audiol Suppl 36:1–39PubMed

Li H-S, Hultcrantz M (1994) Age-related degeneration of the organ of corti in two genotypes of mice. Oto Rhino Laryngol 56:61–67

Marcus DC, Chiba T (1999) K⁺ and Na⁺ absorption by outer sulcus epithelial cells. Hear Res 134:48–56CrossRefPubMed

Minowa O, Ikeda K, Sugitani Y, Oshima T, Nakai S, Katori Y, Suzuki M, Furukawa M, Kawase T, Zheng Y, Ogura M, Asada Y, Watanabe K, Yamanaka H, Gotoh S, Nishi-Takeshima M, Sugimoto T, Kikuchi T, Takasaka T, Noda T (1999) Altered cochlear fibrocytes in a mouse model of DFN3 nonsyndromic deafnesss. Science 285:1408–1411CrossRefPubMed

Motohashi R, Takumida M, Shimizu A, Konomi U, Fujita K, Hirakawa K, Suzuki M, Anniko A (2010) Effects of age and sex on the expression of estrogen receptor α and β in the mouise inner ear. Acta Otolaryngol 130:204–214CrossRefPubMed

Muller M, von Hunerbein K, Hoidis S, Smolders JWT (2005) A physiological place-frequency map of the cochlea in the CBA/J mouse. Hear Res 202:63–73CrossRefPubMed

Nelson EG, Hinojosa R (2006) Presbycusis: a human temporal bone study of individuals with downward sloping audiometric patterns of hearing loss and review of the literature. Laryngoscope 116(suppl 112):1–12CrossRefPubMed

Ohlemiller KK (2006) Contributions of mouse models to understanding of age- and noise-related hearing loss. Brain Res 1091:89–102CrossRefPubMed

Ohlemiller KK (2009) Mechanisms and genes in human strial presbycusis from animal models. Brain Res 1277:70–83CrossRefPubMed

Ohlemiller KK, Gagnon PM (2004a) Cellular correlates of progressive hearing loss in 129 S6/SvEv mice. J Comp Neurol 469:377–390CrossRefPubMed

Ohlemiller KK, Gagnon PM (2004b) Apical-to-basal gradients in age-related cochlear degeneration and their relationship to 'primary' loss of cochlear neurons. J Comp Neurol 479:103–116CrossRefPubMed

Ohlemiller KK, Gagnon PM (2007) Genetic dependence of cochlear cells and structures injured by noise. Hear Res 224:34–50CrossRefPubMed

Ohlemiller KK, Frisina RD (2008) Age-related hearing loss and its cellular and molecular bases. In: Schacht J, Popper AN, Fay RR (eds) Auditory trauma, protection, and repair. Springer, New York, pp 145–194CrossRef

Ohlemiller KK, Lett JM, Gagnon PM (2006) Cellular correlates of age-related endocochlear potential reduction in a mouse model. Hear Res 220:10–26CrossRefPubMed

Ohlemiller KK, Rybak Rice ME, Gagnon PM (2008) Strial microvascular pathology and age-associated endocochlear potential decline in NOD congenic mice. Hear Res 244:85–97CrossRefPubMed

Ohlemiller KK, Rice MR, Lett JM, Gagnon PM (2009) Absence of strial melanin coincides with age associated marginal cell loss and endocochlear potential decline. Hear Res 249:1–14CrossRefPubMed

Pauler M, Schuknecht HF, White JA (1988) Atrophy of the stria vascularis as a cause of sensorineural hearing loss. Laryngoscope 98:754–759CrossRefPubMed

Schacht J, Hawkins JE (2005) Sketches of otohistory. Part 9: presby[a]cusis. Audiol Neuro-Otol 10:243–247CrossRef

Schmiedt RA (2010) Chapter 2: The physiology of cochlear presbycusis. In: Gordon-Salant, S., Frisina, R.D., Popper, A.N., Fay, R.R., (Eds.), Springer handbook of auditory research. The Aging Auditory System, Vol. 34. Springer, New York. pp. 9–38.

Schuknecht HF (1974) Pathology of the ear, 1st edn. Harvard University Press, Cambridge

Schuknecht HF (1993) Pathology of the ear, 2nd edn. Lea and Febiger, Philadelphia

Schuknecht HF, Gacek MR (1993) Cochlear pathology in presbycusis. Ann Otol Rhinol Laryngol 102:1–16PubMed

Schuknecht HF, Watanuki K, Takahashi T, Belal AA, Kimura RS, Jones DD (1974) Atrophy of the stria vascularis, a common cause for hearing loss. Laryngoscope 84:1777–1821CrossRefPubMed

Schulte BA, Schmiedt RA (1992) Lateral wall Na, K-ATPase and endodochlear potentials decline with age in quiet-reared gerbils. Hear Res 61:35–46CrossRefPubMed

Sha S-H, Kanicki A, Dootz GA, Talaska AE, Halsey K, Dolan DF, Altschuler RA (2008) Age-related auditory pathology in the CBA/J mouse. Hear Res 243:87–94CrossRefPubMed

Silver LM (1995) Mouse genetics. Oxford, Oxford, UK

Spicer SS, Schulte BA (2002) Spiral ligament pathology in quiet-aged gerbils. Hear Res 172:172–185CrossRefPubMed

Spicer SS, Schulte BA (2005a) Pathologic changes of presbycusis begin in secondary processes and spread to primary processes of strial marginal cells. Hear Res 205:225–240CrossRefPubMed

Spicer SS, Schulte BA (2005b) Novel structures in marginal and intermediate cells presumably relate to functions of basal versus apical strata. Hear Res 200:87–101CrossRefPubMed

Spicer SS, Samuel S, Schulte BA (1996) The fine structure of spiral ligament cells relates to ion return to the stria and varies with place-frequency. Hear Res 100:80–100CrossRefPubMed

Spongr VP, Flood DG, Frisina RD, Salvi RJ (1997) Quantitative measures of hair cell loss in CBA and C57BL/6 mice throughout their life span. J Acoust Soc Am 101:3546–3553CrossRefPubMed

Suzuki T, Nomoto Y, Nakagawa T, Kuwahata N, Ogawa H, Suzuki Y, Ito J, Omori K (2006) Age-dependent degeneration of the stria vascularis in human cochleae. Laryngoscope 116:1846–1850CrossRefPubMed

Tarnowski BI, Schmiedt RA, Hellstrom LI, Lee FS, Adams JC (1991) Age-related changes in cochleas of Mongolian gerbils. Hear Res 54:123–134CrossRefPubMed

Thomopoulos GN, Spicer SS, Gratton MA, Schulte BA (1997) Age-related thickening of basement membrane in stria vascularis capillaries. Hear Res 111:31–41CrossRefPubMed

Vina J, Borras C, Gambini J, Sastre J, Pallardo FV (2005) Why females live longer than males? Importance of the upregulation of longevity-associated genes by oestrogenic compounds. FEBS Lett 579:2541–2545CrossRefPubMed

Willott JF (1991) Aging and the auditory system: anatomy, physiology, and psychophysics. Singular, San Diego

Willott JF (2001) Modulation of presbcusis: current status and future directions. Audiol Neuro-Otol 6:231–249CrossRef

Willott JF (2009) Effects of sex, gonadal hormones, and augmented acoustic environments on sensorineural hearing loss and the central auditory system: insights from research on C57BL/6J mice. Hear Res 252:89–99CrossRefPubMed

Willott JF, Turner JG, Carlson S, Ding D, Bross LS, Falls WA (1998) The BALB/c mouse as an animal model for progressive sensorineural hearing loss. Hear Res 115:162–174CrossRefPubMed

Wright CG, Schuknecht HF (1972) Atrophy of the spiral ligament. Arch Otolaryngol 96:16–21PubMed

Wu T, Marcus DC (2003) Age-related changes in cochlear endolymphatic potassium and potential in CD-1 and CBA/CaJ mice. J Assoc Res Otolaryngol 4:353–362CrossRefPubMed

Titel: Divergent Aging Characteristics in CBA/J and CBA/CaJ Mouse Cochleae
verfasst von: Kevin K. Ohlemiller
Ashley R. Dahl
Patricia M. Gagnon
Publikationsdatum: 01.12.2010
Verlag: Springer-Verlag
Erschienen in: Journal of the Association for Research in Otolaryngology / Ausgabe 4/2010
Print ISSN: 1525-3961
Elektronische ISSN: 1438-7573
DOI: https://doi.org/10.1007/s10162-010-0228-1

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Divergent Aging Characteristics in CBA/J and CBA/CaJ Mouse Cochleae

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