Nitrogen-cycling bacteria and archaea in the carbonate sediment of a coral reef.

In the coarse-grained carbonate sediments of coral reefs, advective porewater flow and the respiration of organic matter establish redox zones that are the scene of microbially mediated transformations of N compounds. To investigate the geobiology of N cycling in reef sediments, the benthic microbiota of Checker Reef in Kaneohe Bay, Hawaii, were surveyed for candidate nitrate reducers, ammonifying nitrite reducers, aerobic and anaerobic ammonia oxidizers (anammox) by identifying phylotypes of their key metabolic genes (napA, narG, nrfA, amoA) and ribotypes (unique RNA sequences) of anammox-like 16S rRNA. Putative proteobacteria with the catalytic potential for nitrate reduction were identified in oxic, interfacial and anoxic habitats. The estimated richness of napA (≥202 in anoxic sediment) and narG (≥373 and ≥441 in oxic and interfacial sediment, respectively) indicates a diverse guild of nitrate reducers. The guild of nrfA hosts in interfacial reef sediment was dominated by Vibrio species. The identified members of the aerobic ammonium oxidizing guild (amoA hosts) were Crenarchaeota or close relatives of Nitrosomonadales. Putative anammox bacteria were detected in the RNA pool of Checker Reef sediment. More than half of these ribotypes show ≥90% identity with homologous sequences of Scalindua spp., while no evidence was found for members of the genera Brocadia or Kuenenia. In addition to exploring the diversity of these four nitrogen-cycling microbial guilds in coral reef sediments, the abundances of aerobic ammonium oxidizers (amoA), nitrite oxidizers (nxrAB), ammonifying nitrite reducers (nrfA) and denitrifiers (nosZ) were estimated using real-time PCR. Representatives of all targeted guilds were detected, suggesting that most processes of the biogeochemical N cycle can be catalyzed by the benthic microbiota of tropical coral reefs.

Suppression of the deafness and thyroid dysfunction in Thrb-null mice by an independent mutation in the Thra thyroid hormone receptor alpha gene.

Deletion of thyroid hormone receptor beta (TR beta), a ligand-dependent transcription factor encoded by the Thrb gene, causes deafness and thyroid hyperactivity in Thrb-null (Thrb(tm1/tm1)) mice and in a recessive form of the human syndrome of resistance to thyroid hormone. Here, we have determined that a targeted mutation (Thra(tm2)) in the related Thra gene, encoding thyroid hormone receptor alpha suppresses these phenotypes in mice. Thra encodes a TR alpha 1 receptor which is non-essential for hearing and a TR alpha 2 splice variant of unknown function that neither binds thyroid hormone nor transactivates. The Thra(tm2) mutation deletes TR alpha 2 and concomitantly causes overexpression of TR alpha 1 as a consequence of the exon structure of the gene. Thra(tm2/tm2) mice have normal auditory thresholds indicating that TR alpha 2 is dispensable for hearing, and have only marginally reduced thyroid activity. However, a potent function for the Thra(tm2) allele is revealed upon its introduction into Thrb(tm1/tm1) mice, where it suppresses the auditory and thyroid phenotypes caused by loss of TR beta. These findings reveal a novel modifying function for a Thra allele and suggest that increased expression of TR alpha 1 may substitute for the absence of TR beta. The TR isotypes generated by the distinct Thrb and Thra genes represent a small family of receptors that have diverged to mediate different physiological roles; however, the ability of changes in Thra expression to compensate for loss of Thrb indicates that many functions of these genes remain closely related.

Retardation of cochlear maturation and impaired hair cell function caused by deletion of all known thyroid hormone receptors.

The deafness caused by early onset hypothyroidism indicates that thyroid hormone is essential for the development of hearing. We investigated the underlying roles of the TRalpha1 and TRbeta thyroid hormone receptors in the auditory system using receptor-deficient mice. TRalpha1 and TRbeta, which act as hormone-activated transcription factors, are encoded by the Thra and Thrb genes, respectively, and both are expressed in the developing cochlea. TRbeta is required for hearing because TRbeta-deficient (Thrb(tm1/tm1)) mice have a defective auditory-evoked brainstem response and retarded expression of a potassium current (I(K,f)) in the cochlear inner hair cells. Here, we show that although TRalpha1 is individually dispensable, TRalpha1 and TRbeta synergistically control an extended array of functions in postnatal cochlear development. Compared with Thrb(tm1/tm1) mice, the deletion of all TRs in Thra(tm1/tm1)Thrb(tm1/tm1) mice produces exacerbated and novel phenotypes, including delayed differentiation of the sensory epithelium, malformation of the tectorial membrane, impairment of electromechanical transduction in outer hair cells, and a low endocochlear potential. The induction of I(K,f) in inner hair cells was not markedly more retarded than in Thrb(tm1/tm1) mice, suggesting that this feature of hair cell maturation is primarily TRbeta-dependent. These results indicate that distinct pathways mediated by TRbeta alone or by TRbeta and TRalpha1 together facilitate control over an extended range of functions during the maturation of the cochlea.

Mechano-electrical transduction in mice lacking the alpha-subunit of the epithelial sodium channel.

Sensory hair cells of the vertebrate inner ear use mechanically gated transducer channels (MET) to perceive mechanical stimuli. The molecular nature of the MET channel is not known but several findings suggested that the amiloride-sensitive epithelial Na+ channel, ENaC, might be a candidate gene for this function. In order to test this hypothesis, we examined knockout mice deficient in the alpha-subunit of ENaC, and therefore in ENaC function. First, neonatal alphaENaC(-/-) mice exhibited vestibular reflexes not different from wildtype littermates thus indicating normal vestibular function. We used organotypic cultures of cochlear outer hair cells from newborns to rescue the hair cells from the perinatal death of alphaENaC(-/-) mice. When hair bundles of cochlear outer hair cells of alphaENaC(-/-) mice were mechanically stimulated by a fluid jet in whole cell voltage clamp experiments, transducer currents were elicited that were not significantly different from those of alphaENaC(+/-) or (+/+) cochlear outer hair cells. These results suggest that the vertebrate mechano-electrical transducer apparatus does not include the alpha-subunit of the epithelial Na+ channel.

Thyroid hormone receptor beta-dependent expression of a potassium conductance in inner hair cells at the onset of hearing.

To elucidate the role of thyroid hormone receptors (TRs) alpha1 and beta in the development of hearing, cochlear functions have been investigated in mice lacking TRalpha1 or TRbeta. TRs are ligand-dependent transcription factors expressed in the developing organ of Corti, and loss of TRbeta is known to impair hearing in mice and in humans. Here, TRalpha1-deficient (TRalpha1(-/-)) mice are shown to display a normal auditory-evoked brainstem response, indicating that only TRbeta, and not TRalpha1, is essential for hearing. Because cochlear morphology was normal in TRbeta-/- mice, we postulated that TRbeta regulates functional rather than morphological development of the cochlea. At the onset of hearing, inner hair cells (IHCs) in wild-type mice express a fast-activating potassium conductance, IK,f, that transforms the immature IHC from a regenerative, spiking pacemaker to a high-frequency signal transmitter. Expression of IK,f was significantly retarded in TRbeta-/- mice, whereas the development of the endocochlear potential and other cochlear functions, including mechanoelectrical transduction in hair cells, progressed normally. TRalpha1(-/-) mice expressed IK,f normally, in accord with their normal auditory-evoked brainstem response. These results establish that the physiological differentiation of IHCs depends on a TRbeta-mediated pathway. When defective, this may contribute to deafness in congenital thyroid diseases.

Hair cells in mammalian utricles.

Two morphological classes of mechanosensory cells have been described in the vestibular organs of mammals, birds, and reptiles: type I and type II hair cells. Type II hair cells resemble hair cells in other organs in that they receive bouton terminals from primary afferent neurons. In contrast, type I hair cells are enveloped by large cuplike afferent terminals called calyces. Type I and II cells differ in other morphological respects: cell shape, hair bundle properties, and more subtle ultrastructural features. Understanding the functional significance of these strikingly different morphological features has proved to be a challenge. Experiments that correlated the response properties of primary vestibular afferents with the morphologies of their afferent terminals suggested that the synapse between the type I hair cell and calyx ending is lower gain than that between a type II hair cell and a bouton ending. Recently, patch-clamp experiments on isolated hair cells have revealed that type I hair cells from diverse species have a large potassium conductance that is activated at the resting potential. As a consequence, the voltage responses generated by the type I hair cells in response to injected currents are smaller than those generated by type II hair cells. This may contribute to the lower gain of type I inputs to primary afferent neurons. Studies of neonatal mouse utricles show that the type I-specific potassium conductance is not present at birth but emerges during the first postnatal week, a period of morphological differentiation of type I and type II hair cells.

Postnatal development of type I and type II hair cells in the mouse utricle: acquisition of voltage-gated conductances and differentiated morphology.

The type I and type II hair cells of mature amniote vestibular organs have been classified according to their afferent nerve terminals: calyx and bouton, respectively. Mature type I and type II cells also have different complements of voltage-gated channels. Type I cells alone express a delayed rectifier, gK,L, that is activated at resting potential. We report that in mouse utricles this electrophysiological differentiation occurs during the first postnatal week. Whole-cell currents were recorded from hair cells in denervated organotypic cultures and in acutely excised epithelia. From postnatal day 1 (P1) to P3, most hair cells expressed a delayed rectifier that activated positive to resting potential and a fast inward rectifier, gK1. Between P4 and P8, many cells acquired the type I-specific conductance gK,L and/or a slow inward rectifier, gh. By P8, the percentages of cells expressing gK,L and gh were at mature levels. To investigate whether the electrophysiological differentiation correlated with morphological changes, we fixed utricles at different times between P0 and P28. Ultrastructural criteria were developed to classify cells when calyces were not present, as in cultures and neonatal organs. The morphological and electrophysiological differentiation followed different time courses, converging by P28. At P0, when no hair cells expressed gK,L, 33% were classified as type I by ultrastructural criteria. By P28, approximately 60% of hair cells in acute preparations received calyx terminals and expressed gK,L. Data from the denervated cultures showed that neither electrophysiological nor morphological differentiation depended on ongoing innervation.

Expression of a potassium current in inner hair cells during development of hearing in mice.

Excitable cells use ion channels to tailor their biophysical properties to the functional demands made upon them. During development, these demands may alter considerably, often associated with a change in the cells' complement of ion channels. Here we present evidence for such a change in inner hair cells, the primary sensory receptors in the mammalian cochlea. In mice, responses to sound can first be recorded from the auditory nerve and observed behaviourally from 10-12 days after birth; these responses mature rapidly over the next 4 days. Before this time, mouse inner hair cells have slow voltage responses and fire spontaneous and evoked action potentials. During development of auditory responsiveness a large, fast potassium conductance is expressed, greatly speeding up the membrane time constant and preventing action potentials. This change in potassium channel expression turns the inner hair cell from a regenerative, spiking pacemaker into a high-frequency signal transducer.

Genetic analysis of vertebrate sensory hair cell mechanosensation: the zebrafish circler mutants.

The molecular basis of sensory hair cell mechanotransduction is largely unknown. In order to identify genes that are essential for mechanosensory hair cell function, we characterized a group of recently isolated zebrafish motility mutants. These mutants are defective in balance and swim in circles but have no obvious morphological defects. We examined the mutants using calcium imaging of acoustic-vibrational and tactile escape responses, high resolution microscopy of sensory neuroepithelia in live larvae, and recordings of extracellular hair cell potentials (microphonics). Based on the analyses, we have identified several classes of genes. Mutations in sputnik and mariner affect hair bundle integrity. Mutant astronaut and cosmonaut hair cells have relatively normal microphonics and thus appear to affect events downstream of mechanotransduction. Mutant orbiter, mercury, and gemini larvae have normal hair cell morphology and yet do not respond to acoustic-vibrational stimuli. The microphonics of lateral line hair cells of orbiter, mercury, and gemini larvae are absent or strongly reduced. Therefore, these genes may encode components of the transduction apparatus.

Mechanically and ATP-induced currents of mouse outer hair cells are independent and differentially blocked by d-tubocurarine.

Mechano-electrical transducer channels (MET) and ATP-gated ion channels (P2X receptors) of hair cells have several properties in common: they share the same location at the apex of the cell, both channels are non-selective for cations and blocked by aminoglycosides and pyrazinecarboxamides (amiloride-related compounds). In this study, we test the relationship and possible identity of these two channel types. Using whole-cell patch-clamp recordings of outer hair cells (OHCs) of the cultured neonatal mouse cochlea and a fluid jet to stimulate their hair bundles mechanically, we show that d-tubocurarine, a blocker of P2X2 receptors, blocks MET channels with a half-blocking concentration of 2.3 microM. In contrast, the KD for the P2X2 receptors was 90 microM and 84 microM measured in hair cells and Xenopus oocytes, respectively. When hair bundles of OHCs were simultaneously stimulated with saturating mechanical stimuli and superfused by 100-300 microM ATP, transducer currents and ATP-activated currents were elicited simultaneously. Their amplitudes were additive, however. We conclude that MET- and ATP-activated currents are mediated by two distinct channel populations in hair cells.

Developmental changes in the physiology of hair cells.

Mature hair cells express complements of ion channels which vary with hair cell type. Immature hair cells in the inner ears of neonatal mice and pre-hatch chicks share mechanosensitive and certain voltage-gated conductances: delayed rectifier and inwardly rectifying potassium conductances, voltage-gated calcium and sodium conductances. Over the course of several days the immature cells acquire other conductances that confer upon them the distinctive voltage-dependent properties of mature hair cells. In the mouse utricle, postnatal acquisition of additional delayed and inward rectifiers transforms the neonatal hair cells into two classes with the electrophysiological profiles of mature type I and type hair II cells. Electromotility, a highly differentiated, voltage-dependent property of mature outer hair cells from the mammalian cochlea, is also acquired after mechanosensitivity.

A delayed rectifier conductance in type I hair cells of the mouse utricle.

1. Membrane currents of hair cells in acutely excised or cultured mouse utricles were recorded with the whole cell voltage-clamp method at temperatures between 23 and 36 degrees C. 2. Type I and II hair cells both had delayed rectifier conductances that activated positive to -55 mV. 3. Type I, but not type II, hair cells had an additional delayed rectifier conductance (gK,L) with an activation range that was unusually negative and variable. At 23-25 degrees C, V(1/2) values ranged from -88 to -62 mV in 57 cells. 4. gK,L was very large. At 23-25 degrees C, the average maximum chord conductance was 75 +/- 65 nS (mean +/- SD, n = 57; measured at -54 mV), or approximately 21 nS/pF of cell capacitance. 5. gK,L was highly selective for K+ over Na+ (permeability ratio PNa+/PK+:0.006), but unlike other delayed rectifiers, gK,L was significantly permeable to Cs+ (PCs+/PK+:0.31). gK,L was independent of extracellular Ca2+. 6. At -64 mV, Ba2+ and 4-aminopyridine blocked gK,L with apparent dissociation constants of 2.0 mM and 43 microM, respectively. Extracellular Cs+ (5 mM) blocked gK,L by 50% at -124 mV. Apamin (100 nM) and dendrotoxin (10 nM) has no effect. 7. The kinetic data of gK,L are consistent with a sequential gating model with at least two closed states and one open state. The slow activation kinetics (principal time constants at 23-25 degrees C:600-200 ms) had a thermal Q10 of 2.1. Inactivation (Q10:2.7) was partial at all temperatures. Deactivation followed a double-exponential time course and had a Q10 of 2.0. 8. At 23-25 degrees C, gK,L was appreciably activated at the mean resting potential of type I hair cells (-77 +/- 3.1 mV, n = 62), so that input conductances were often more than an order of magnitude larger than those of type II cells. If these conditions hold in vivo, type I cells would produce unusually small receptor potentials. Warming the cells to 36 degrees C produced parallel shifts in gK,L's activation range (0.8 +/- 0.3 mV/degrees C, n = 8), and in the resting potential (0.6 +/- 0.3 mV/degrees C, n = 4). Thus the high input conductances were not an artifact of unphysiological temperatures but remained high near body temperature. It remains possible that in vivo gK,L's activation range is less negative and input conductances are lower; the large variance in the voltage range of activation suggests that it may be subject to modulation.

Injection locking of a diode-pumped Nd:YAG laser at 946 nm.

Injection locking in the quasi-three-level laser system Nd:YAG (4)F(3/2)-(4)I(9/2) at 946 nm is reported. The master and slave oscillators are pumped by laser diodes. The master oscillator is frequency stabilized to a high-finesse cavity, resulting in a laser linewidth of less than 10 Hz. Using intracavity frequency doubling of the slave oscillator, we achieve a single-mode output power of 60 mW at 473 nm. The laser radiation was frequency quadrupled, resulting in an UV power of 0.55 mW at 236.5 nm. The laser system was used to excite a strongly forbidden In(+) transition, proposed as a new optical frequency standard.

Block by amiloride and its derivatives of mechano-electrical transduction in outer hair cells of mouse cochlear cultures.

1. The effects of amiloride and amiloride derivatives on mechano-electrical transducer currents in outer hair cells of the cultured neonatal mouse cochlea were examined under whole-cell voltage clamp. 2. At -84 mV transducer currents were reversibly blocked by the extracellular application of the pyrazinecarboxamides amiloride, benzamil, dimethylamiloride, hexamethyleneiminoamiloride, phenamil and methoxynitroiodobenzamil with half-blocking concentrations of 53, 5.5, 40, 4.3, 12 and 1.8 microM, respectively. Hill coefficients were determined for all but the last of these compounds and were 1.7, 1.6, 1.0, 2.2 and 1.6, respectively, suggesting that two drug molecules co-operatively block the transducer channel. 3. Both the structure-activity sequence for amiloride and its derivatives and the mechanism of the block of the transducer channel appear to be different from those reported for the high-affinity amiloride-sensitive epithelial Na+ channels but similar to those of stretch-activated channels in Xenopus oocytes. 4. The block by all pyrazinecarboxamides was voltage dependent with positive membrane potentials releasing the block. The form of the voltage dependence is consistent with a voltage-independent binding of the drug to a site that is accessible at hyperpolarized but not at depolarized potentials, suggesting that the transducer channel undergoes a voltage-dependent conformational change. The channel was not blocked by 1 mM amiloride from the intracellular side at either negative or positive membrane potentials. 5. The kinetics of the block were studied using force steps or voltage jumps. The results suggest that the drug binding site is only accessible when the transducer channel is open (open-channel block) and that the channel cannot close when the drug molecules are bound. 6. The time dependence and voltage dependence of the block together reveal that the transducer channel has at least two open conformational states, the transition between which is voltage dependent.

Mechano-electrical transducer currents in hair cells of the cultured neonatal mouse cochlea.

The first step towards the generation of the receptor potential in hair cells is the gating of the transducer channels and subsequent flow of transducer current, induced by deflection of the stereocilia. We describe properties of the transducer current in outer hair cells of neonatal mice. Less extensive observations on inner hair cells suggest that their transducer currents have similar characteristics. The hair bundles were stimulated by force from a fluid jet. The transducer currents in outer hair cells are the largest found so far in any hair cell, with a chord conductance of up to 9.2 nS at -84 mV. The transfer function suggests that the channel has at least two closed states and one open state. The permeabilities for sodium, potassium and caesium are similar, consistent with the channel being a fairly non-selective cation channel. At negative potentials the currents adapt in most cells, although never as completely as in hair cells of lower vertebrates. If the unit conductance of the transducer channel is similar to that of the turtle's auditory hair cells (100 pS), then there are about 90 channels per hair bundle, or one channel between every pair of adjacent stereocilia in neighbouring rows.

Spontaneous and electrically induced movements of ampullary kinocilia and stereovilli.

In the transparent vestibular organ of young eels, isolated in toto, movements of individual kinocilia and hair bundles of the frontal ampulla were recorded by photodiodes and a video system. Flagella-like oscillations of kinocilia occurred spontaneously when preparations deteriorated and could be induced regularly in fresh preparations by pressing onto the tip of the cilium. Upon step-like electrical polarization of the epithelium hair bundles deflected in a tonic, pointer-like manner. When the apical membrane was hyperpolarized the hair bundles deflected towards the kinocilium (positive deflection) amounting to about 0.6 degrees when the polarization was made strong enough to cause saturating responses in the ampullary nerve. In response to sinusoidal voltage the amplitude of the hair bundle deflection declined by -4 dB/octave for frequencies above 1.3 Hz. When the kinocilium was disconnected from the bundle of stereovilli by transient reduction of divalent cations, voltage induced deflections occurred, of both the kinocilium and the stereovilli. Reducing the extracellular Ca-activity seemed to destabilize the electrically induced deflections; blocking the oxidative metabolism (CN-) had no effect. The induced deflections only disappeared upon chemical fixation by glutaraldehyde or treatment with triton X-100. Surface tension and electrostriction of the cell membrane are discussed as possible force generators.

Cupula displacement, hair bundle deflection, and physiological responses in the transparent semicircular canal of young eel.

The transparent labyrinth of young eels (Anguilla anguilla L.) was used in toto for studying the configuration of cupula displacement, deflection of the hair bundle, and correlated changes in transepithelial voltage (delta TEV) and nerve activity (delta NA) in the semicircular canal. Microcapillaries were introduced into the canal through holes produced by a microthermocauter. Mechanical stimulation was applied either by injection of fluid into the ampulla or by electromagnetically displacing ferrofluid as a piston within the canal. Motion of individual kinocilia, stained cupulae or the ferrofluid piston was analysed by double-exposed microphotographs, photodiodes, or a video-system. The three-dimensional cupula displacement configuration was found to be piston- to diaphragm-like. Hair bundles at different sites on the crista exhibit differences in amplitude and time course of deflection. The transfer factor between shifts of the canal fluid and the tips of the kinocilia is 0.4-0.6. Displacements in opposite directions induce delta TEV and delta NA of opposite sign. Various tests confirmed delta TEV to reflect receptor potential responses. Nerve activity adapts to a tonic response with a time constant of 6.4 s. No similar adaptation occurred in delta TEV. Stimulus-response curves of TEV- and NA-responses are similar and sigmoid in shape with saturation at ciliary deflections of roughly +6 degrees and -3 degrees.

Passive and active deflections of ampullary kinocilia correlated with changes in transepithelial voltage.

Deflections of individual ampullary kinocilia were optically recorded in the undissected vestibular system of young eels. At mechanical stimulation, transepithelial receptor potentials and nerve activity were recorded. Saturating responses occurred at ciliary deflections of +6 degrees and -3 degrees. Kinocilia occasionally oscillate spontaneously in a snaking or pointer-like mode as the preparation deteriorates. In nearly all kinocilia of fresh preparations exogenous transepithelial voltage change induces active pointer-like deflection in a graded and tonic manner. A voltage change of a given sign induces a deflection that counteracts mechanical stimuli producing a voltage change of the same sign.