Coding interaural time differences at low best frequencies in the barn owl.

In birds and mammals, precisely timed spikes encode the timing of acoustic stimuli, and interaural acoustic disparities propagate to binaural processing centers. The Jeffress model proposes that these projections act as delay lines to innervate an array of coincidence detectors, every element of which has a different relative delay between its ipsilateral and contralateral excitatory inputs. Thus, interaural time difference (ITD) is encoded into the position of the coincidence detector whose delay lines best cancel out the acoustic ITD. Neurons of the avian nucleus laminaris and mammalian MSO phase-lock to both monaural and binaural stimuli but respond maximally when phase-locked spikes from each side arrive simultaneously, i.e. when the difference in the conduction delays compensates for the ITD. McAlpine et al. [Nat. Neurosci. 4 (2001) 396] identified an apparent difference between avian and mammalian ITD coding. In the barn owl, the maximum firing rate appears to encode ITD. This may not be the case for the guinea pig, where the steepest region of the function relating discharge rate to interaural time delay (ITD) is close to midline for all neurons, irrespective of best frequency (BF). These data suggest that low BF ITD sensitivity in the guinea pig is mediated by detection of a change in slope of the ITD function, and not by maximum rate. We review coding of low best frequency ITDs in barn owls and mammals and discuss whether there may be differences in the code used to signal ITD in mammals and birds.     

System-specific distribution of zinc in the chick brain

Summary The brain of young domestic chicks was investigated using a Timm sulfide silver method. Serial Vibratome sections were analyzed under the light microscope, and the localization of zinc-positive structures in selected areas was determined at the ultrastructural level. Both strong and differential staining was visible in the avian telencephalon whereas most subtelencephalic structures showed a pale reaction. The highest staining intensity was found in the nonprimary sensory regions of the telencephalon such as the hyperstriatum dorsale, hyperstriatum ventrale, hippocampus, palaeostriatum augmentatum, lobus parolfactorius and caudal parts of neostriatum. There was an overall gradient of staining intensity in neostriatal areas from rostral to caudal with the heaviest zinc deposits in the caudal neostriatum. Primary sensory projection areas, such as the ectostriatum (visual), hyperstriatum intercalatum superius (visual), nucleus basalis (beak representation), the input layer L₂ of the auditory field L and the somatosensory area rostral to field L were selectively left unstained. Fiber tracts throughout the brain were free of zinc deposits except for glial cells. In electron micrographs of stained regions, silver grains were localized in some presynaptic boutons of asymmetric synapses (Gray type I), within the cytoplasm of neuronal somata and sporadically in the nucleus. The possible involvement of zinc in synaptic transmission and other processes is discussed.Abbreviations for Anatomical Structures used in the Text and Figures Ac Nucleus accumbens - Ad Archistriatum dorsale - Ai Archistriatum intermedium - Am Archistriatum mediale - Ap Archistriatum posterior - APH Area parahippocampalis - BAS Nucleus basalis - BO Bulbus olfactorius - Cb Cerebellum; - CbI Nucleus cerebellaris internus - CbM Nucleus cerebellaris intermedius - CDL Area corticoidea dorsolateralis - CPi Cortex piriformis - CT Commissura tectalis - DMP Nucleus dorsomedialis posterior thalami - E Ectostriatum - H Hyperstriatum - HA Hyperstriatum accessorium - HD Hyperstriatum dorsale - HIS Hyperstriatum intercalatum superius - Hp Hippocampus - HV Hyperstriatum ventrale - ICo Nucleus intercollicularis - Ipc Nucleus isthmi, pars parvocellularis - L Lingula - L _{1, 2, 3} Field L - La Nucleus laminaris - LFM Lamina frontalis suprema - LFS Lamina frontalis superior - LH Lamina hyperstriatica - LMD Lamina medullaris dorsalis - LNH Rostrolateral neostriatum/Hyperstriatum ventrale - LPO Lobus parolfactorius - M Medulla - MLd Nucleus mesencephalicus lateralis, pars dorsalis - MNH Rostromedial neostriatum/Hyperstriatum ventrale - N Neostriatum - NC Neostriatum caudale - NEB Nucleus of ectostriatal belt - NHA Nucleus of HA - PA Palaeostriatum augmentatum - Pap Nucleus papillioformis - PL Nucleus pontis lateralis - PP Palaeostriatum primitivum - RP Nucleus reticularis pontis caudalis - Rt Nucleus rotundus - S Nucleus septalis - SS Somatosensory area - TeO Tectum opticum - Tn Nucleus taeniae - TPO Area temporoparieto-occipitalis - V Ventricle - Va Vallecula     

Commissural connections mediate inhibition for the computation of interaural level difference in the barn owl

Summary In the barn owl (Tyto alba), the posterior nucleus of the ventral lateral lemniscus (VLVp) is the first site of binaural convergence in the pathway that processes interaural level difference (ILD), an important sound-localization cue. The neurons of VLVp are sensitive to ILD because of an excitatory input from the contralateral ear and an inhibitory input from the ipsilateral ear. A previously described projection from the contralateral cochlear nucleus, can account for the excitation. The present study addresses the source of the inhibitory input.We demonstrate with standard axonal transport methods that the left and right VLVps are interconnected via fibers of the commissure of Probst. We further show that the anesthetization of one VLVp renders ineffective the inhibition that is normally evoked by stimulation of the ipsilateral ear. Thus, one cochlear nucleus (driven by the ipsilateral ear) appears to provide inhibition to the ipsilateral VLVp by exciting commissurally-projecting inhibitory neurons in the contralateral VLVp.Abbreviations ABL average binaural level - CP commissure of Probst - DNLL dorsal nucleus of the lateral lemniscus - IC inferior colliculus - ILD interaural level difference - IPc nucleus isthmi, pars parvocellularis - ITD interaural time difference - LSO lateral superior olive - MNTB medial nucleus of the trapezoid body - NA nucleus angularis - SL nucleus semilunaris - VLVa nucleus ventralis lemnisci lateralis, pars anterior - VLVp nucleus ventralis lemnisci lateralis, pars posterior     

Postnatal development of central auditory frequency maps

Summary In the early postnatal period of many mammals and in the perihatching period of chicks the auditory ranges are restricted to the species-specific low- and mid-frequency ranges. During subsequent development, the high frequency hearing expands (depending on the species) by 1–4 octaves. Adult-like audition is established between the 4th and the 7th week. It is still discussed controversially, how the extension of the auditory ranges relates to the maturation of orderly frequency representation in the cochleae of the respective species. The present review summarizes investigations of the development of tonotopy in nuclei of the central auditory system, and discusses how the centrally acquired data might contribute to the understanding of the maturation of cochlear stimulus transduction and to the development of frequency maps.Abbreviations ANF auditory nerve fibers - BF best frequency - CN cochlear nucleus - DAB days after birth - DCN dorsal cochlear nucleus - IC inferior colliculus - IHC inner hair cells - HS Hipposideros speoris - LSO lateral superior olive - MGB medial geniculate body (auditory thalamus) - NL Nucleus laminaris - NM Nucleus magnocellularis - OHC outer hair cells - RR Rhinolophus rouxi - SOC superior olivary complex - 2-DG 2-deoxyglucose     

Connectivity of the auditory forebrain nuclei in the Guinea Fowl (Numida meleagris)

Summary Injection of tritiated leucine and proline into the nucleus ovoidalis of the Guinea Fowl (Numida meleagris) produces terminal labeling in the palaeostriatum and in three adjacent zones (field L₁–L₃) of the auditory neostriatum (AN). L₂, situated between L₁ and L₃, receives the main input and corresponds to the former field L of Rose. These neuroanatomically defined zones of the auditory neostriatum are also characterized by differing properties of their neurons. Injection of radioactive material into the auditory neostriatum produces labeling of (i) a palaeostriatal, (ii) a ventral hyperstriatal, and (iii) an additional neostriatal area (Nd). Injection into the hyperstriatum ventrale reveals connections (i) to field L₂, (ii) to the palaeostriatum, (iii) to Nd, and (iv) to the archistriatum. After injection into the palaeostriatum, labeling can be observed (i) in the neostriatum dorsale, (ii) in the hyperstriatum ventrale, (iii) in the archistriatum, (iv) in the diencephalic nuclei, nucleus ansae lenticularis and nucleus spiriformis lateralis, and (v) in the mesencephalic nuclei, nucleus tegmenti pedunculo-pontinus and nucleus intercollicularis. These results show that a widespread connectivity exists among primary and presumably higher order auditory areas in the forebrain of birds. Connections also exist between these auditory areas and presumed vocal-motor areas (neostriatum dorsale, archistriatum, nucleus intercollicularis).Abbreviations A Archistriatum - AL Ansa lenticularis - AN Auditory neostriatum - Bas Nucleus basalis - CA Commissura anterior - Cb Cerebellum - CP Commissura posterior - DLP Nucleus dorsolateralis posterior thalami - DTh Dorsal thalamus - E Ectostriatum - EM Nucleus ectomamillaris - FA Tractus fronto-archistriatalis - FPL Fasciculus prosencephali lateralis - GLv Nucleus geniculatus lateralis, pars ventralis - HA Hyperstriatum accessorium - HD Hyperstriatum dorsale - HIS Hyperstriatum intercalatum superius - HV Hyperstriatum ventrale - HVc Hyperstriatum ventrale, pars caudale - I Injection site - ICo Nucleus intercollicularis - ICT Nucleus intercalatus thalami - Imc Nucleus isthmi, pars magnocellularis - Ipc Nucleus isthmi, pars parvocellularis - l₁, L₂, L₃ Auditory neostriatum: zones L₁, L₂, L₃ - LAD Lamina archistriatalis dorsalis - LH Lamina hyperstriatica - LMD Lamina medullaris dorsalis - LPO Lobus parolfactorius - M Mesencephalon - MLd Nucleus mesencephalicus lateralis, pars dorsalis - N Neostriatum - nAL Nucleus ansae lenticularis - Nc Neostriatum caudale - Nd Neostriatum dorsale - OM Tractus occipito-mesencephalicus - OMv Nucleus nervi oculomotorii, pars ventralis - Ov Nucleus ovoidalis - PA Palaeostriatum augmentatum - PP Palaeostriatum primitivum - PT Nucleus praetectalis - PVM Nucleus periventricularis magno-cellularis - RSd Nucleus reticularis superior, pars dorsalis - RSv Nucleus reticularis superior, pars ventralis - Rt Nucleus rotundus - SMe Stria medullaris - SpL Nucleus spiriformis lateralis - SpM Nucleus spiriformis medialis - SRt Nucleus subrotundus - TeO Tectum opticum - TOv Tractus ovoidalis - TPc Nucleus tegmenti pedunculo-pontinus - TrO Tractus opticus - TSM Tractus septo-mesencephalicus - Ve Ventricle The authors are indebted to Mrs. I. Röder and Mrs. M. Hansel for their aid in the preparation of the histological material and the illustrationsThis work was supported by the Deutsche Forschungsgemeinschaft, Sche 132/4     

Asymmetric Excitatory Synaptic Dynamics Underlie Interaural Time Difference Processing in the Auditory System

Low-frequency sound localization depends on the neural computation of interaural time differences (ITD) and relies on neurons in the auditory brain stem that integrate synaptic inputs delivered by the ipsi- and contralateral auditory pathways that start at the two ears. The first auditory neurons that respond selectively to ITD are found in the medial superior olivary nucleus (MSO). We identified a new mechanism for ITD coding using a brain slice preparation that preserves the binaural inputs to the MSO. There was an internal latency difference for the two excitatory pathways that would, if left uncompensated, position the ITD response function too far outside the physiological range to be useful for estimating ITD. We demonstrate, and support using a biophysically based computational model, that a bilateral asymmetry in excitatory post-synaptic potential (EPSP) slopes provides a robust compensatory delay mechanism due to differential activation of low threshold potassium conductance on these inputs and permits MSO neurons to encode physiological ITDs. We suggest, more generally, that the dependence of spike probability on rate of depolarization, as in these auditory neurons, provides a mechanism for temporal order discrimination between EPSPs.     

Delay Line Models of Sound Localization in the Barn Owl

SYNOPSIS. The detection of interaural time differences underliesazimuthal sound localization in the barn owl. Sensitivity tothese time differences arises in the brainstem nucleus laminaris.Auditory information reaches the nucleus laminaris via bilateralprojections from the cochlear nucleus magnocellularis. The magnocellularinputs to the nucleus laminaris act as delay lines to createmaps of interaural time differences. These delay lines are tappedby postsynaptic coincidence detectors that encode interauraltime differences. The entire circuit, from the auditory nerveto the nucleus magnocellularis to the nucleus laminaris, isspecialized for the encoding and preservation of temporal information.A mathematical model of this circuit (Grun et al., 1990) providesuseful predictions.     

Sensory basis for sound intensity discrimination in the bushcricket Requena verticalis (Tettigoniidae, Orthoptera)

The ability of the female bushcricket, Requena verticalis, to discriminate between two conspecific sound signals that differed in sound pressure level (SPL) was tested in a two-choice paradigm. Significant discrimination was achieved with a 2-dB difference. The property of each pair of receptors to establish binaural discharge differences was investigated in electrophysiological experiments. The threshold to the conspecific signal varies for each fibre from about 40 to 90 dB SPL, allowing for a range fractionation of the hearing organ. Each pair of receptors establishes significant binaural discharge differences only within a restricted intensity range about 10 dB above threshold. Based on a model of the intensity response function of a receptor the total discharge of the 22 receptors in both ears was calculated with monaural and binaural stimulation. The profile of receptors exhibiting significant discharge differences changes with increasing SPL, from the most sensitive fibres with a characteristic frequency between 12 kHz and 35 kHz at low SPLs to the least sensitive fibres at very low and high characteristic frequencies at medium to high SPLs. The discharge difference with an intensity difference of 2 dB is rather small (4% of the total receptor activity) and limited only to a few pairs of receptors. Accepted: 8 November 1997     

Afferent connections of the optic tectum in channel catfish Ictalurus punctatus

Summary Horseradish peroxidase was injected unilaterally into the optic tectum of the channel catfish, Ictalurus punctatus. The sources of tectal afferents were thereby revealed by retrogradely labeled neurons in various brain centers. Retrogradely labeled cells were seen in both the ipsilateral and contralateral telencephalon. The superficial pretectal area was labeled on both sides of the brain. Ipsilateral projections were also observed coming from the entopeduncular nucleus. Both the anterior thalamic nucleus and the ventro-medial thalamic nucleus projected to the ipsilateral optic tectum. Cells in the ipsilateral nucleus of the posterior commissure were seen to project to the tectum. Labeled fibers were visualized in the lateral geniculate nucleus ipsilateral to the injected tectum, however, no labeled cell bodies were observed. Therefore, tectal cells project to the lateral geniculate nucleus, but this projection is not reciprocal. No labeled cells were found in the cerebellum. Labeled cells occurred in both the ipsilateral and contralateral medial reticular formation; they were also observed in the ipsilateral nucleus isthmi. A projection was seen coming from the dorsal funicular nucleus. Furthermore, labeled cells were shown in the inferior raphe nucleus.Abbreviations AP Area pretectalis - C Cerebellum - DPTN Dorsal posterior tegmental nucleus - H Habenula - IRF Inferior reticular formation - LI Inferior lobe - LGN Lateral geniculate nucleus - LR Lateral recess - MB Mammillary body - MRF Medial reticular formation - MZ Medial zone of the telencephalon - NC Nucleus corticalis - NDL-M Nucleus opticus dorsolateralis/pars medialis - NI Nucleus isthmi - NPC Nucleus of the posterior commissure - OPT Optic tectum - OT Optic tract - PC Posterior commissure - PN Pineal organ - PrOP Preoptic nucleus - PT Pretectum - TBt Tectobulbar tract - TEL Telencephalon - TL Torus longitudinalis - TS Torus semicircularis - VC Valvula cerebelli - VLTN Ventrolateral thalamic nucleus - VMTN Ventromedial thalamic nucleus     

Bilateral matching of frequency tuning in neural cross-correlators of the owl

Sound localization requires comparison between the inputs to the left and right ears. One important aspect of this comparison is the differences in arrival time to each side, also called interaural time difference (ITD). A prevalent model of ITD detection, consisting of delay lines and coincidence-detector neurons, was proposed by Jeffress (J Comp Physiol Psychol 41:35–39, 1948). As an extension of the Jeffress model, the process of detecting and encoding ITD has been compared to an effective cross-correlation between the input signals to the two ears. Because the cochlea performs a spectrotemporal decomposition of the input signal, this cross-correlation takes place over narrow frequency bands. Since the cochlear tonotopy is arranged in series, sounds of different frequencies will trigger neural activity with different temporal delays. Thus, the matching of the frequency tuning of the left and right inputs to the cross-correlator units becomes a ‘timing’ issue. These properties of auditory transduction gave theoretical support to an alternative model of ITD-detection based on a bilateral mismatch in frequency tuning, called the ‘stereausis’ model. Here we first review the current literature on the owl’s nucleus laminaris, the equivalent to the medial superior olive of mammals, which is the site where ITD is detected. Subsequently, we use reverse correlation analysis and stimulation with uncorrelated sounds to extract the effective monaural inputs to the cross-correlator neurons. We show that when the left and right inputs to the cross-correlators are defined in this manner, the computation performed by coincidence-detector neurons satisfies conditions of cross-correlation theory. We also show that the spectra of left and right inputs are matched, which is consistent with predictions made by the classic model put forth by Jeffress. This article is part of a special issue on Neuronal Dynamics of Sensory Coding.     

The functional role of GABA and glycine in monaural and binaural processing in the inferior colliculus of horseshoe bats

Summary The functional role of GABA and glycine in monaural and binaural signal analysis was studied in single unit recordings from the central nucleus of the inferior colliculus (IC) of horseshoe bats (Rhinolophus rouxi) employing microiontophoresis of the putative neurotransmitters and their antagonists bicuculline and strychnine.Most neurons were inhibited by GABA (98%; N=107) and glycine (92%; N=118). Both neurotransmitters appear involved in several functional contexts, but to different degrees.Bicuculline-induced increases of discharge activity (99% of cells; N=191) were accompanied by changes of temporal response patterns in 35% of neurons distributed throughout the IC. Strychnine enhanced activity in only 53% of neurons (N=147); cells exhibiting response pattern changes were rare (9%) and confined to greater recording depths. In individual cells, the effects of both antagonists could markedly differ, suggesting a differential supply by GABAergic and glycinergic networks.Bicuculline changed the shape of the excitatory tuning curve by antagonizing lateral inhibition at neighboring frequencies and/or inhibition at high stimulation levels. Such effects were rarely observed with strychnine.Binaural response properties of single units were influenced either by antagonization of inhibition mediated by ipsilateral stimulation (bicuculline) or by changing the strength of the main excitatory input (bicuculline and strychnine).Abbreviations BF best frequency - Bic bicuculline - C control - CF constant frequency - CN cochlear nucleus - DNLL dorsal nucleus of the lateral lemniscus - FM frequency modulation - GABA gamma amino butyric acid - IC inferior colliculus - LSO lateral superior olive - Str strychnine     

An auditory fovea in the barn owl cochlea

The distribution of frequencies along the basilar papilla of the barn owl (Tyto alba) was studied by labelling small groups of primary auditory neurones of defined frequency response and tracing them to their peripheral innervation sites. The exact location of marked neurones was determined in cochlear wholemounts with the aid of a special surface preparation technique. The average basilar papilla length (in fixed, embedded specimens) was 10.74 mm.The resulting frequency map shows the basic vertebrate pattern with the lowest frequencies represented apically and increasingly higher frequencies mapped at progressively more basal locations. However, the length of basilar papilla devoted to different frequency ranges, i.e. the space per octave, varies dramatically in the barn owl. The lower frequencies (up to 2 kHz) show values between about 0.35 and 1 mm/octave, which are roughly equivalent to values reported for other birds. Above that, the space increases enormously, the highest octave (5–10 kHz) covering about 6 mm, or more than half of the length of the basilar papilla.Such an overrepresentation of a narrow, behaviourally very important frequency band is also seen in some bats, where it has been termed an acoustic or auditory fovea.Abbreviations CF characteristic frequency - HRP horseradish peroxidase - NA Nucleus angularis - NM Nucleus magnocellularis     

Embryonic origins of auditory brain-stem nuclei in the chick hindbrain

The auditory nuclei of the chick brain stem have distinct morphologies and highly specific synaptic connectivity. Nucleus magnocellularis (NM) and nucleus angularis receive tonotopically ordered cochlear input. NM in turn projects tonotopically to nucleus laminaris (NL), maintaining binaural specificity with projections to either dorsal or ventral NL dendrites. NM and NL arise from a common anlage, which differentiates as the cells migrate and acquire their mature morphologies. NM and NL cells are closely associated during embryogenesis and synapse formation. However, the morphologies of the nuclei and of the cells within the nuclei differ greatly between NM and NL. While later maturation of these nuclei has been described in considerable detail, relatively little is known about the early embryonic events that lead to the formation of these nuclei. We examined the embryonic origins of cells in brain-stem auditory nuclei with particular emphasis on NM and NL. Lipophilic dyes were injected into small regions of the embryonic hindbrain prior to the birth and migration of cells that contribute to these nuclei. We found that NM arises from rhombomeres r5, r6, and r7, and NL arises mostly from r5 with a few cells arising from r6. NM and NL thus have partially overlapping rhombomeres of origin. However, we found that the precursors for NM and NL are found in distinct regions within rhombomere 5, with NM precursors in medial regions and NL precursors in lateral regions. Our results do not support a lineage relationship between NM and NL cells and they suggest that NM and NL are specified prior to migration of precursors to the auditory anlage.     

On the ability of neurons in the barn owl's inferior colliculus to sense brief appearances of interaural time difference

Summary This paper investigates the ability of neurons in the barn owl's (Tyto alba) inferior colliculus to sense brief appearances of interaural time difference (ITD), the main cue for azimuthal sound localization in this species. In the experiments, ITD-tuning was measured during presentation of a mask-probe-mask sequence. The probe consisted of a noise having a constant ITD, while the mask consisted of binaurally uncorrelated noise. Collicular neurons discriminated between the probe and masking noise by showing rapid changes from untuned to tuned and back to untuned responses.The curve describing the relation between probe duration and the degree of ITD-tuning resembled a leaky-integration process with a time constant of about 2 ms. Many neurons were ITD-tuned when probe duration was below 1 ms. These extremely short effective probe durations are interpreted as evidence for neuronal convergence within the pathway computing ITD. The minimal probe duration necessary for ITD-tuning was independent of the bandwidth of the neurons' frequency tuning and also of the best frequency of a neuron. Many narrowly tuned neurons having different best frequencies converge to form a broad-band neuron. To yield the short effective probe durations the convergence must occur in strong temporal synchronism.Abbreviations ICc central nucleus of the inferior colliculus; - ICx external nucleus of the inferior colliculus; - ITD interaural time difference - LP Likelihood parameter     

Das visuelle System von Zonotrichia leucophrys gambelii

Zusammenfassung Der Verlauf der Sehbahn und die Lokalisation der optischen Zentren wurden bei Zonotrichia leucophrys gambelii (nordamerikanischer Ammernfink) nach einseitiger Augenexstirpation mit den Techniken von Nauta-Fink-Heimer, Bodian und Bielschowsky erforscht. Die Untersuchungen erstreckten sich über einen Zeitraum von 3 bis zu 120 Tagen nach der Operation. Zonotrichia leucophrys gambelii besitzt ein für Vögel typisches visuelles System. Die Hauptmasse der Optikusfasern endet im Stratum griseum et fibrosum superficiale des Tectum opticum. Weitere zentrale Endgebiete sind: Nucleus geniculatus lateralis, Nucleus lateralis anterior, Nucleus superficialis synencephali, Nucleus externus, tectales Grau und Nucleus ectomamillaris als Kern der basalen optischen Wurzel. Alle Fasern werden im Chiasma opticum total gekreuzt, auch der Tractus isthmo-opticus, ein efferentes Bündel, dessen Ursprung im Nucleus isthmo-opticus zu finden ist. Dieses efferente Fasersystem läßt sich im Stumpf des durchtrennten N. opticus noch 120 Tage nach der Operation gut versilbern. Eine direkte Verbindung von Retina und Hypothalamus war lichtmikroskopisch nicht nachweisbar. Neurosekretorisch aktive Zellen des Hypothalamus können zwar einen engen räumlichen Kontakt mit den optischen Fasern haben, Synapsen sind aber an diesen Stellen nicht zu erkennen. Es werden passagere Opticusfasern beschrieben, die auf dem Weg zum Nucleus lateralis anterior und Nucleus superficialis synencephali den Hypothalamus durchsetzen.

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Neurohistological and experimental studies of the visual system in Zonotrichia leucophrys gambelii

Summary The course of the optic pathways and the positions of the optic centers have been investigated with unilaterally enucleated white-crowned sparrows, Zonotrichia leucophrys gambelii, using the techniques of Nauta-Fink-Heimer, Bodian, and Bielachowsky. The investigation involved birds examined 3–120 days after enucleation. The white-crowned sparrow has a typically avian visual system. The major bundles of optic fibers terminate in the stratum griseum et fibrosum superficiale of the tectum opticum. Further terminal areas are the nucleus geniculatus lateralis, nucleus lateralis anterior, nucleus superficialis synencephali, nucleus externus, the tectal gray, and the nucleus ectomamillaris of the basal optic root. There is a complete crossing of all fibers in the chiasma, including those of the tractus isthmo-opticus, an efferent bundle with its origin in the nucleus isthmo-opticus. This efferent fiber system can be well impregnated in the stump of the sectioned optic nerve up to 120 days after the operation. No direct connection between the retina and hypothalamus could be demonstrated by light microscopy. Hypothalamic neurosecretory cells can occur in close contact with optic fibers but no synapses have been recognized. Some optic fibers pass through the hypothalamus enroute to the nucleus lateralis anterior and the nucleus superficialis synencephali.

Mit Unterstützung durch die Deutsche Forschungsgemeinschaft. Herrn Prof. Dr. D.S. Farner, Department of Zoology, University of Washington, Seattle, Wash., danke ich für die Förderung dieser Studien (National Institutes of Health Research Grant No. 5 ROI NB 06187 to Professor D. S. Farner).     

Catecholamine im Gehirn der Eidechse (Lacerta viridis und Lacerta muralis)

Zusammenfassung Mit Hilfe der Methode zur fluoreszenzmikroskopischen Lokalisation von Catechol- und Tryptaminen wurde die Verteilung von Catecholaminen im Zentralnervensystem von Lacerta viridis und muralis untersucht. Die meisten Kerngebiete des Mittel-, Zwischen- und Vorderhirns werden von Endaufsplitterungen catecholaminhaltiger Neurone erreicht, deren Verteilungsmuster für jedes Kerngebiet charakteristisch ist; die Ursprungsgebiete dieser Fasersysteme liegen im Tegmentum (Nucleus reticularis mesencephali) und im Hypothalamus (Nucleus diffusus tuberis). Außer diesen Ursprungskernen findet sich im Hypothalamus ein paraventrikulär gelegenes, catecholaminhaltiges Kerngebiet (Nucleus ependymalis hypothalami), dessen kurze, transmitterreiche Neurone die Hauptkerngebiete des Hypothalamus (Nucleus ventromedialis tuberis; Area praeoptica) und wahrscheinlich auch die Commissurenkerne innervieren.Spektrographische und histochemische Befunde legen die Vermutung nahe, daß die fluoreszierende Substanz im Palaeostriatum von Lacerta hauptsächlich Noradrenalin ist und daß die Neurone des Nucleus ependymalis hypothalami neben Adrenalin primäre Catecholamine enthalten. Es wird die Möglichkeit diskutiert, daß die im ZNS von Lacerta nachgewiesenen Catecholamine als Transmitterstoffe wirken.

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Summary The distribution of catecholamines in the central nervous system of Lacerta viridis and muralis was investigated by means of the method for fluorescence-microscopical detection of catechol- and tryptamines. Most nuclear areas of the mes-, di- and telencephalon receive terminal ramifications of catecholamine-containing neurones, the distribution pattern of which is typical for each nucleus; these neurones originate in the tegmentum (nucleus reticularis mesencephali) and in the hypothalamus (nucleus diffusus tuberis). Apart from these nuclei another paraventricular nucleus (nucleus ependymalis hypothalami) was found to contain catecholamines. The short neurones of this nucleus mainly innervate the nucleus ventromedialis tuberis and the area praeoptica. It is assumed that these neurones also supply the nuclei commissurales of the telencephalon.According to the results of spectrographical and histochemical tests it is assumed that the fluorescent substance in the palaeostriatum of Lacerta is mainly noradrenaline and that the neurones of the nucleus ependymalis hypothalami besides little adrenaline contain huge amounts of primary catecholamines. The possibility of the fluorescent substances acting as transmitters is discussed.

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Mit dankenswerter Unterstützung durch die Deutsche Forschungsgemeinschaft und die Joachim Jungius-Gesellschaft zur Förderung der Wissenschaften, Hamburg.     

Astrocyte-secreted factors modulate a gradient of primary dendritic arbors in nucleus laminaris of the avian auditory brainstem

Neurons in nucleus laminaris (NL) receive binaural, tonotopically matched input from nucleus magnocelluaris (NM) onto bitufted dendrites that display a gradient of dendritic arbor size. These features improve computation of interaural time differences, which are used to determine the locations of sound sources. The dendritic gradient emerges following a period of significant reorganization at embryonic day 15 (E15), which coincides with the emergence of astrocytes that express glial fibrillary acidic protein (GFAP) in the auditory brainstem. The major changes include a loss of total dendritic length, a systematic loss of primary dendrites along the tonotopic axis, and lengthening of primary dendrites on caudolateral NL neurons. Here we have tested whether astrocyte-derived molecules contribute to these changes in dendritic morphology. We used an organotypic brainstem slice preparation to perform repeated imaging of individual dye-filled NL neurons to determine the effects of astrocyte-conditioned medium (ACM) on dendritic morphology. We found that treatment with ACM induced a decrease in the number of primary dendrites in a tonotopically graded manner similar to that observed during normal development. Our data introduce a new interaction between astrocytes and neurons in the auditory brainstem and suggest that these astrocytes influence multiple aspects of auditory brainstem maturation.     

Response properties of the prothoracic AN2 auditory interneurone to model calling songs in the cricket Gryllus bimaculatus

Sound processing properties for calling song (CS) models, as described for the prothoracic L3 auditory neurone in Acheta domesticus, are investigated for the homologous auditory neurone 2 (AN2) in female Gryllus bimaculatus De Geer. AN2 of G. bimaculatus responds selectively to the syllable period (SP) of models of a male CS. The selectiveness of this response parallels the selectivity of phonotaxis females perform in response to the same SPs. Both, the responses of AN2 and female behaviour show clear interindividual variability. The SP‐selective responses of AN2 result from an SP‐dependent reduction in the spiking to subsequent syllables of the model CSs, measured as the percentage decrement. This SP‐dependent response does not primarily result from inbuilt properties of the AN2 membrane. Rather, it is dependent on inhibitory input to the AN2. However, clear inhibitory postsynaptic potentials in dendritic recordings of the AN2 are not encountered. This immediate response of AN2 to CSs is followed by an increased rate of tonic firing between stimulus CSs, which is termed the prolonged response, and is dependent on the carrier frequencies that make up the male CSs. With stimulation on the contralateral side of the soma of AN2s, more than 50% of AN2s exhibit a prolonged response. However, with stimulation from the ipsilateral side of the soma, most AN2s exhibit a prolonged response. The prolonged response of AN2 at 5 kHz may be even more sensitive than the immediate response. Thus, the AN2 neurone could provide a basis for phonotaxis that is selective for both the SPs and the carrier frequencies of potentially attractive calling songs.     

Functional delay of myelination of auditory delay lines in the nucleus laminaris of the barn owl

In the barn owl, maps of interaural time difference (ITD) are created in the nucleus laminaris (NL) by interdigitating axons that act as delay lines. Adult delay line axons are myelinated, and this myelination is timely, coinciding with the attainment of adult head size, and stable ITD cues. The proximal portions of the axons become myelinated in late embryonic life, but the delay line portions of the axon in NL remain unmyelinated until the first postnatal week. Myelination of the delay lines peaks at the third week posthatch, and myelinating oligodendrocyte density approaches adult levels by one month, when the head reaches its adult width. Migration of oligodendrocyte progenitors into NL and the subsequent onset of myelination may be restricted by a glial barrier in late embryonic stages and the first posthatch week, since the loss of tenascin-C immunoreactivity in NL is correlated with oligodendrocyte progenitor migration into NL.     

Resonance phenomena in the cochlea of the mustache bat and their contribution to neuronal response characteristics in the cochlear nucleus

Summary The cochlea of the mustache bat, Pteronotus parnellii, is very sensitive and sharply tuned to the frequency range of the dominant second harmonic of the echolocation call around 61 kHz. About 900 Hz above this frequency the cochlear microphonic potential (CM) reaches its maximum amplitude and lowest threshold. At exactly the same frequency, pronounced evoked otoacoustic emissions (OAE) can be measured in the outer ear canal, indicating mechanical resonance. The CM amplitude maximum and the OAE are most severely masked by simultaneous exposure to tones within the range from about 61–62 kHz up to about 70 kHz. The data suggest that the mechanism of mechanical resonance involves cochlear loci basal to the 61 kHz position.The resonance contributes to auditory sensitivity and sharp tuning: At the frequency of the OAE, single unit responses in the cochlear nucleus have the lowest thresholds. Maximum tuning sharpness occurs at frequencies about 300 Hz below the OAE-frequency, where the threshold is about 10 dB less sensitive than at the OAE-frequency. In addition, in the frequency range around the OAE-frequency several specialized neuronal response features can be related to mechanical resonance: Long lasting excitation after the end of the stimulus, asymmetrical tuning curves with a shallow high frequency slope and phasic on-off neuronal response patterns. In particular the latter phenomenon indicates the occurrence of local mechanical cancellations in the cochlea.Abbreviations CF constant frequency component of echolocation calls - CM cochlear microphonic potential - FM frequency modulated component of echolocation calls - N1 compound action potential of the auditory nerve - OAE octoacoustic emission - SEOAE synchronous evoked OAE