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Home , Basilar membrane, Cochlea, Cochlear amplifier, Cochlear duct, Inner ear, Organ of Corti

Cochlear , function and pathology I

Professor Dave Furness Keele University [email protected] Aims and objectives of these lectures • Introduction to gross anatomy of the • Focus (1) on the sensory : – Hair cells and the – The mechanism of mechanoelectrical transduction Aims and objectives of these lectures • Focus (2) on the biophysics of the cochlea, the dual roles of hair cells and their innervation: – Cochlear frequency selectivity – The – Neurotransmission and innervation of the hair cells – and the structure of the auditory nerve Aims and objectives of these lectures • Focus (3) on the cochlear lateral wall and Reissner’s membrane: – The – The stria vascularis – The endolymphatic potential and recycling – Reissner’s membrane Aims and objectives of these lectures • Focus (4) on cochlear pathology: – Presbyacusis – – Noise trauma – Genetic loss – Molecular mechanisms of cell loss – Regeneration and repair Inner

From Bear, Connors and Paradiso, Neuroscience: exploring the (Lippincott Williams and Wilkins) Cochlea • The main functions of the cochlea are to analyse and convert the vibrations caused by sound into a pattern of electrical signals that can be conveyed along the auditory nerve fibres to the brain • This process involves three main steps: – sensory transduction – processing of the signal – neurotransmission The bony and membraneous labyrinths

From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 scala vestibuli

scala media

scala tympani Cross sections of the

3 week old mouse 8 week old guinea pig

Left: Mahendrasingam et al., 2011, JARO; Right Hackney and Furness, Noise and its Pathophysiology (eds Luxon and Prasher, 2007, Wiley) Fluid segregation

• The three chambers contain different fluids • , high in potassium, in scala media • , high in sodium, in scala vestibuli and scala tympani The cochlea is a frequency analyser Increasing mass Low frequencies

Basilar membrane and organ of Corti

High frequencies

Increasing stiffness Frequency mapping on the • Discovered by Georg von Békésy who was awarded the Nobel Prize for Physiology or Medicine, 1961 • Used human cadavers and played sounds to them, whilst observing the motion of the basilar membrane • Measured the travelling wave and noted peaks of tuning • However, the peaks were not sharp enough to account for human frequency selectivity • Active physiological mechanisms are also required Frequency analysis in the cochlea • Sound sets up a travelling wave along the basilar membrane • The peak of motion determines the frequency selectivity (tuning) of the cochlea at that point • The peak moves further along as frequency gets lower Basilar membrane animation

YouTube video Copyright: Howard Hughes Institute (under license)

Cross sections of the cochlear duct

From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 Organ of Corti • Organ of Corti consists of a sensory epithelium with hair cells and supporting cells Stria vascularis

Nerve fibres From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 The reticular lamina by scanning electron microscopy

OHC IHC The reticular lamina by scanning electron microscopy

OHC IHC

Supporting cells: inner pillar, outer pillar, Deiter’s cell 1, Deiter’s cell 2, Deiters cell 3. Supporting cells are rich in and tubulin (cytoskeletal proteins) to provide mechanical support to the organ of Corti

From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 Supporting cells are rich in actin and tubulin (cytoskeletal proteins) to provide mechanical support to the organ of Corti

From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 Immunogold shows sorting of different actin isoforms in different organ of Corti cell types

From Furness et al Hear Res. 2005 Sep;207(1-2):22-34 Hair cells • Auditory stimuli are received in the form of mechanical energy • Hair cells are mechanosensory receptors of the and are found in the cochlear and vestibular epithelia • They share common characteristics which underlie their sensitivity to mechanical stimuli Hair cells in auditory epithelium Cochlea + Inner hair Outer hair organ of Corti cells cells Comparing the inner and outer hair cells

IHCs flask shaped; mitochondria dispersed; nucleus central OHCs cylindrical; mitochondria mostly lateral, nucleus basal Hair cells in the organ of Corti

• Two types, structurally and functionally distinct • A number of similarities and differences • Bundle structure – similar rows of but different shapes • Both can perform mechanoelectrical transduction • Innervation differs between the two

Overview of bundle structure

• Stereocilia form precise rows • They are coupled by various extracellular filaments

From Hackney and Furness J Cell Sci 2013; 126(Pt 8):1721-1731 The hair bundle is the ’s transducing element • Composed of stereocilia linked together by extracellular filaments • Contains many different proteins • The core of the stereocilium is actin • It also contains and a variety of scaffolding and calcium modulating proteins • Extracellular filaments composed of other proteins Other important proteins required for transduction

• Transducer elements • Structural and regulatory – TMC1 (transmembrane components channel 1) – Harmonin – TMC2 (transmembrane – Sans channel 2) – Whirlin – LHFPL5 (TMHS) – Usherin (tetraspan membrane – Stereocilin protein of hair cell stereocilia) – EPS8, EPS8L2 – Protocadherin 15 – PTPRQ – 23 – VLGR1 – TMIE (transmembrane – Calmodulin inner ear protein) – PMCA2A (calcium ATPase) Links

• The composition of links is becoming better understood • Their distributions tend to follow a particular pattern Hair bundles are the site of mechanoelectrical transduction • Hair cells are sensitive to deflections of the hair bundle plus (excitation) along the axis of sensitivity

0 0

minus (inhibition) Transduction occurs when the stereocilia are deflected positive negative

+

- -

+ Hair cell responses

Moving stereocilia

Cell electrical response The tip-links

• Excitatory deflections of stereocilia open transduction channels by means of a gating spring • The spring is represented by the A model of mechanosensitivity A single tip link Tip links and transduction channels

TMHS

From Hackney and Furness J Cell Sci 2013; 126(Pt 8):1721-1731 Immunolocalization of TMHS/LHFPL5

Actin (green), TMHS (red) Hair-cell transduction and neurotransmission

+80 mV

-70 mV

response Glutamate transporters around IHCs but not OHCs confirm glutamatergic transmission

OHC area Inner phalangeal Fibrocytes cells around IHCs Summary

• In this lecture we have looked at the gross structural anatomy of the cochlea • We have examined the organisation and function of the organ of Corti • We have described and explained mechanoelectrical transduction – how the hair cells detect mechanical stimulation