Abstract
Several functional maps have been described in primary auditory cortex, including those related to frequency, tuning, latency, binaurality, and intensity. Many of these maps are arranged in a discontinuous or patchy manner. Similarly, thalamocortical projections arising from the ventral division of the medial geniculate body to the primary auditory cortex are also patchy. We used anterograde labeling and electrophysiological methods to examine the relationship between thalamocortical patches and auditory cortical maps. Biotinylated dextran–amine was deposited into physiologically characterized sites in the ventral division of the medial geniculate body of New Zealand white rabbits. Approximately 7 d later, the animal was again anesthetized and the ipsilateral auditory cortex was mapped with tungsten microelectrodes. Multi-unit physiological data were obtained for the following characteristics: best frequency (BF), binaurality, response type, latency, sharpness of tuning, and threshold. Immunocytochemical methods were used to reveal the injection site in the ventral division of the medial geniculate body as well as the anterogradely labeled thalamocortical afferents in the auditory cortex. In 86% of the cases (12 of 14), entry into a thalamocortical patch was associated with a marked change in physiological responses. A consistent BF and binaural class were usually observed within a patch. The patches appear to innervate distinct functional regions coding frequency and binaurality. A model is presented showing how patchy thalamocortical projections participate in the formation of tonotopic and binaural maps in primary auditory cortex.
Introduction
The topographic representation of peripheral sensory receptors in mammalian sensory systems results in a systematic representation or functional map in sensory cortex (Marshall et al., 1941; Hubel and Wiesel, 1962; Merzenich et al., 1973; Hubel and Wiesel, 1977). The first tonotopic auditory neocortical map was demonstrated by Woolsey and Walzl (1942) in the form of a cochleotopic organization in the primary auditory cortex (AI) of the cat. Other functional maps in AI include binaural interaction bands (Imig and Adrian, 1977; Middlebrooks et al., 1980), threshold/intensity (Tunturi, 1950; Schreiner et al., 1992), and sharpness of tuning (Schreiner and Mendelson, 1990). Interestingly, these maps are patchy or discontinuous in their distribution relative to the frequency map (Merzenich et al., 1973; Brugge and Imig, 1978; Middlebrooks et al., 1980; Reale and Imig, 1980; Redies et al., 1989; Schreiner, 1991, 1992;Schreiner et al., 1992, 2000; Mendelson et al., 1993, 1997; Fitzpatrick et al., 1998).
Ascending auditory signals reach AI via projections from the ventral division of the medial geniculate body (MGV) (Mesulam and Pandya, 1973; Sousa-Pinto, 1973; Jones and Burton, 1976; Winer et al., 1977; Imig and Morel, 1983; Middlebrooks and Zook, 1983; LeDoux et al., 1985). Anterograde studies of MGV projections have revealed the existence of a discontinuous or patchy projection of afferent axons from the MGV to layers III/IV of auditory cortex (McMullen and de Venecia, 1993; Romanski and LeDoux, 1993; de Venecia and McMullen, 1994; Cetas et al., 1999). Patchy thalamocortical (TC) afferents to the cortex have been described in a variety of species, including the rat, rabbit, ferret, cat, and macaque (Winer et al., 1977;Angelucci et al., 1993; Romanski and LeDoux, 1993; Hashikawa et al., 1995; Huang and Winer, 2000). Some insight into the nature of TC patches has come from studies involving the calcium-binding protein parvalbumin (PV) (Hendry et al., 1989; Morino-Wannier et al., 1992;McMullen et al., 1994; de Venecia et al., 1995, 1998; Jones et al., 1995; Molinari et al., 1995). TC patches coexist with PV-positive patches in AI (de Venecia et al., 1998). In addition, the MGV is intensely PV-positive in many species (Hashikawa et al., 1991; Vater and Braun, 1994; de Venecia et al., 1995; Molinari et al., 1995;Cruikshank et al., 2001), and PV-positive relay neurons in the MGV project to AI (de Venecia et al., 1998). Thus, at least some of the TC patches arising from the MGV may represent a chemically coded pathway to AI. Evidence that specific TC circuits contribute to patchy functional maps in AI was presented by Middlebrooks and Zook (1983), who demonstrated that excitatory/inhibitory (EE/EI) foci in AI receive input from segregated populations of neurons in the auditory thalamus. Surprisingly, the physiological responses of neurons within TC patches and their relationship to various acoustic maps existing in AI have not been addressed in any species. In the present study, this question was examined by mapping the auditory cortex in animals that received injections of anterograde tracer into the ventral division of the medial geniculate body. Portions of this work have been published previously in abstract form (Velenovsky et al., 2000, 2001).
Materials and Methods
Animals. The animals were housed, cared for, and used strictly in accordance with United States Department of Agriculture regulations and the Guide for the Care and Use of Laboratory Animals (National Institutes of Health publication 85-23). The research protocol was approved by the Institutional Animal Care and Use Committee of the University of Arizona College of Medicine. Experiments were performed on normal young adult New Zealand white (NZW) rabbits (1–3 kg) obtained from local suppliers. The experiments were performed in two parts. In part I, an anterograde tracer was injected into the ventral division of the MGB and the animal was allowed to recover. In part II, the ipsilateral auditory cortex was electrophysiologically mapped with microelectrodes 6–8 d later. All labeling and mapping procedures were performed in an IAC model 401A sound booth (Industrial Acoustics Company, Bronx, NY).
Part I: anterograde labeling of TC pathway. Animals were anesthetized with ketamine (44 mg/kg, i.m.) and xylazine (10 mg/kg, i.m.) and then placed in a Kopf stereotaxic device (David Kopf Instruments, Tujunga, CA). Surgery was performed under sterile conditions. Injection sites were referenced to bregma (lambda and bregma in the same horizontal plane) using stereotaxic coordinates (McMullen and de Venecia, 1993). The final coordinate ranges were as follows: anteroposterior, 6.5–7.2 mm; lateral, 5.3–5.6 mm; dorsoventral, 12.25–13.65 (referenced from skull surface). After small holes were drilled through the skull, tungsten electrodes (2–4 MΩ;World Precision Instruments, Sarasota, FL) were advanced stereotaxically into the auditory thalamus using a Kopf micromanipulator fitted with a motorized stage (model MC-3B-11; National Aperture Inc., Salem, NH). Custom-fabricated transducers coupled to custom-molded earpieces were used to deliver acoustic stimuli. Tucker–Davis Technologies (Gainesville, FL) system II hardware controlled by a Gateway (Poway, CA) personal computer using custom software were used to generate auditory stimuli and analyze multi-unit responses as the electrode was advanced in 100 μm steps. Multi-unit responses were amplified and filtered using a Grass P511 preamplifier (Grass Instruments, West Warwick, RI). After noise bursts (one per second; 100–200 msec duration) revealed an acoustically responsive area, tone bursts (one per second; 100–200 msec duration) were used to characterize best frequency (BF), latency, and response profile of the site. When short-latency-onset responses and sharp tuning curves in response to tone bursts were seen, the coordinates were noted and the electrode was slowly removed. A borosilicate glass electrode (outside tip diameter, 10–13 μm) filled with 10% biotinylated dextran–amine (BDA, molecular weight of 10,000; Molecular Probes, Eugene, OR) in 0.1 m PBS was returned to the MGB recording site. This was accomplished by placing the injection microelectrode at the bregma reference site under high magnification. The identical stereotaxic coordinates of the tungsten electrode were used to locate the injection electrode at the original recording site. The BDA was deposited using positive current pulses (0.9 Hz, 3 μA for 20 min) with a Transkinetics CS-3 current generator. After the electrode was removed, the incision was sutured, and chloromycetin (30 mg/kg, s.c.) was administered. The animal was returned to its cage after it recovered from anesthesia and was monitored daily for signs of infection or discomfort.
Part II: mapping of TC patches. After 6–8 d, the animal was returned to the recording room and to the Kopf stereotaxic device for cortical mapping. The animal was anesthetized using urethane (1.25 mg/kg, i.v.) and ketamine (13 mg/kg, i.m., every 50 min). Oval holes of ∼4 × 6 mm were drilled through the skull just dorsal to AI. Tangential penetrations were made through the auditory cortex (McMullen and Glaser, 1982) with tungsten microelectrodes (2–4 MΩ; World Precision Instruments). Multi-unit response properties were determined at 300 μm intervals. This recording interval was large enough to maximize cortical mapping but remained fine enough to permit functional/anatomical correlations. Broadband noise bursts were used to determine the overall responsiveness of an area to auditory stimuli. When a responsive area was located, the characteristic frequency, threshold, and binaurality were determined using tone bursts (100 msec duration). Binaurality was determined by presenting noise bursts at a level 20–40 dB above threshold. For binaural presentation, diotic stimuli were used. Responsiveness was judged by listening to multi-unit activity through a monitor speaker and viewing real-time spike rasters. Responses were classified as EE if diotic stimuli elicited the most robust response and EI if stimulating the contralateral ear elicited a more robust response. No preference for contralateral or binaural stimulation was classified as excitatory/occlusion (EO) (Imig and Adrian, 1977; Middlebrooks and Zook, 1983). Afterward, spike rasters, poststimulus time histograms (PSTHs) and tuning curves were obtained (Cetas et al., 2002a). The binaurality determined for noise bursts was used to set the mode of stimulus presentation (contra or binaural) when the automated tuning curve program was run. The BF from the tuning curve program was then evaluated for binaurality, using levels and procedure as for noise above (Cetas et al., 2001). Electrolytic lesions (10 μA for 10 sec) were placed at the end of each penetration and at the location of the initial acoustic response to assist in electrode track reconstructions. At completion of the mapping experiments, the animal was perfused with 4% paraformaldehyde in PBS and the brain was removed. The brain was dissected into cortical and thalamic blocks and postfixed overnight in 4% paraformaldehyde at 4°C. The blocks were cryoprotected in ascending sucrose solutions (to 30%) before sectioning.
Tissue processing. For the localization of injection sites, coronal thalamic sections were cut using a sledge-type microtome (75 μm thick) and incubated for 15 min in 1% H2O2 to suppress endogenous peroxidase activity. BDA was localized by avidin–biotin–horseradish peroxidase histochemistry (Vector Elite ABC Kit; Vector Laboratories, Burlingame, CA) using nickel–cobalt intensification of the diaminobenzidine (DAB) reaction product (Adams, 1981). Sections were mounted on gelatinized slides and counterstained with 1% aqueous methylene blue to confirm the location and extent of the MGV injections. The electrophysiologically mapped cortices were gently flattened between glass slides and fixed in 4% paraformaldehyde. Tangential frozen sections through the cortex were cut on a sledge-type microtome at a thickness of 50 μm. A sensitive immunoperoxidase method was used to visualize BDA-labeled axons in the cortex ipsilateral to MGV injections (McMullen and de Venecia, 1993; de Venecia and McMullen, 1994). Briefly, sections were incubated for 48 hr at 4°C in goat anti-biotin antibody (Vector Laboratories) diluted 1:10,000 in PBS containing 3% normal rabbit serum (NRS), followed by biotinylated rabbit anti-goat IgG (Vector Laboratories) diluted 1:200 in 3% NRS–PBS for 2 hr at room temperature. The labeled axons were visualized with a standard DAB histochemistry reaction with heavy metal intensification (Adams, 1981). Because PV has been shown to be an excellent marker for AI in a variety of species (Wallace et al., 1991; McMullen et al., 1994; Hashikawa et al., 1995; Kosaki et al., 1997; de Venecia et al., 1998; Budinger et al., 2000; Cruikshank et al., 2001), alternative cortical sections were processed for this calcium-binding protein. The monoclonal antibody against PV used in these experiments was Swiss Antibodies #235 (Swant, Bellinzona, Switzerland). All immunohistochemical procedures were performed on free-floating sections using a rocker table for gentle agitation. Dilutions and rinses were done with 0.1 m PBS, pH 7.4. Sections were first submerged in 1% H2O2 for 15 min to suppress endogenous peroxidase activity and then placed into 3% normal horse serum (NHS; Vector Laboratories) with 1% Triton X-100 for 60 min to block nonspecific labeling and to increase antibody penetration. The sections were incubated in primary mouse monoclonal antibody to PV (1:5000–1:15,000 dilution with 3% NHS) for 72 hr at 4°C, followed by biotinylated horse anti-mouse IgG (1:200 dilution with 3% NHS) for 2 hr, and avidin–biotin–horseradish peroxidase complex (Vector Laboratories Standard ABC kit) for 90 min at room temperature. PV immunoreactivity was visualized using the cobalt–nickel DAB intensification method of Adams (1981). No specific staining was observed in control experiments in which sections were incubated in primary antibody preadsorbed with HPLC-purified rat parvalbumin (Swiss antibodies). All sections were then mounted onto gelatinized slides and coverslipped with Permount. TC patches, electrode tracks, and electrolytic lesions were reconstructed from serial sections with the aid of a computer microscope (MicroBrightField Inc., Colchester, VT) or an Aus Jena Macro-Projector (AusJena, Jena, Germany). Tissue shrinkage was determined by measuring the distances between lesions after tissue processing and comparing those values with those measuredin situ. A shrinkage measurement of 30% was determined and applied to reconstruct the cortical electrode penetrations.
Results
All successful injections into the MGV resulted in labeled TC patches. AI was mapped in 12 animals, with a total of 35 tangential electrode penetrations. In seven animals, at least one TC patch was traversed by a mapping penetration. In six of the seven animals, the BF of the MGV injection site was determined. In three of the six animals, BF and binaurality of the injection site were represented in at least one TC patch. Reconstructions of frequency and binaural maps obtained from tangential electrode penetrations in three animals are shown in Figure 1. In all cases in which AI was mapped, a high-to-low dorsoventral frequency progression was seen. In 16 penetrations, an additional tonotopic field was located dorsal and often anterior to the primary field, with a low-to-high frequency progression that mirrored the progression in the primary field. This secondary field is shown for animals CM-4 and CM-13 in Figure 1(denoted by asterisks) and CM-15 in Figure 3. The distribution of binaural categories relative to the tonotopic maps is also shown in Figure 1. In general, neurons formed clusters of binaural categories that extended across isofrequency contours. EE and EO categories predominated and formed regions 0.5–2.0 mm wide. EI regions were seen less frequently.
A total of 14 BDA-labeled TC patches were mapped in seven animals. Typically, multiple TC arbors in AI resulted from a single BDA injection in the MGV (Fig. 2). In many cases, the TC patches in the tangential plane appeared oriented along the presumptive isofrequency contours in AI (shown in Fig. 1) of the rabbit (see Figs. 2, 3, 5, 7, 9). In all but one case, labeled patches arising from MGV tracer injections coincided with tonotopically organized areas in auditory cortex, whose functional characteristics (short latency, low threshold, dorsoventral high-to-low frequency organization) were consistent with AI of this species (McMullen and Glaser, 1982). In 86% (12 of 14 in seven animals) of the penetrations through labeled TC patches, entry and exit into anterograde-labeled terminal fields were characterized by abrupt changes in physiological responses (e.g., binaurality, latency, and frequency) to acoustic stimuli. In general (10 of 14 penetrations), TC patches defined cortical regions of uniform multi-unit response profiles (e.g., BF or binaurality). The patches were not associated with any one group of unvarying response properties (i.e., consistent frequency or binaurality was not always represented in every patch).
An example of anterograde labeled patches in AI resulting from a large BDA injection into the MGV of animal CM-15 is illustrated in Figure 2(left). In this case, the BDA injection labeled an elongated slab-like region whose orientation paralleled the cellular laminas in the rabbit MGV (Cetas et al., 2001, 2002b). The TC projections labeled by this injection consisted of four distinct patches shown in Figure 2(right). A comparison with Figure 1 indicates that the overall orientation of the patches parallels the isofrequency contours of this species (Fig. 2). This relationship was observed in several experiments (see below); it suggests a point-to-strip organization of TC projections in this species. A reconstruction of the mapping experiment for animal CM-15 is shown in Figure 3. A high-to-low frequency progression was seen during mapping experiments, as revealed by the graphs for penetrations 4 and 5 shown in Figure 3. A dorsal tonotopic field was also seen in this experiment, characterized by a steep low-to-high frequency progression that mirrored the frequency organization of AI (Fig. 3). In experiment CM-15, frequency was consistent throughout mapped portions of each of the TC patches. Binaurality, in the form of EE, was also consistent in each of the penetrations through the TC patches (Fig. 3).
Figure 4 illustrates a coronal section of the MGV from animal CM-27, which received a small BDA injection located at the lateral edge of the anterior MGV. A computer microscope reconstruction of the small TC terminal fields labeled by this injection, along with a reconstruction of one tangential electrode penetration, is shown in Figure 5. Typical for small patches labeled by injections of this size, BF (15 kHz) and binaurality (EE) remained consistent within the TC patch, whereas threshold and PSTH response type varied (Fig. 5). Note also the posterodorsal to anteroventral orientation of the two small patches shown in the reconstruction of penetration 3, an orientation that parallels the isofrequency contours of the rabbit AI (Fig. 1).
Figure 6 is a photomicrograph of a larger BDA injection in the high-frequency area of the MGV for experiment CM-13. Similar to CM-15, shown in Figure 2, the BDA injection site has a dorsomedial–ventrolateral orientation similar to that of cellular laminas and frequency slabs that have been described in the MGV (Cetas et al., 2001). A computer microscope reconstruction of TC terminal fields along with reconstructions of two tangential electrode penetrations in auditory cortex from experiment CM-13 are shown in Figure 7. Because of the large BDA injection in the MGV, the TC terminal fields were larger here relative to those from experiment CM-27 (Fig. 5). Similar to those of experiments CM-15 and CM-27 (Figs. 3, 5), the TC terminal fields were oriented in an anteroventral-to-posterodorsal direction. In each penetration, both BF and binaurality remained constant within the TC axonal field. In penetration 1, a change in binaurality occurred on entering and exiting the TC field. A consistent BF (16 kHz) and binaurality (EO) were observed within the patch. A consistent BF (23 kHz) and binaural response (EO) were also seen in the small patch mapped in penetration 3 (Fig. 7, right). Although frequency remained consistent in both TC fields, the BFs were not the same (16 and 23 kHz). It is interesting to note that 23 kHz is ∼0.7 octaves above 16 kHz, a frequency step size that has been described in the rabbit MGB (Cetas et al., 2001).
The BDA injection in the MGV for experiment CM-29 is shown in Figure8. Unlike the MGV injections in experiments CM-15 (Fig. 3) and CM-13 (Fig. 6), the injection focus extends vertically across the MGV laminas. Such an injection would be expected to cross multiple frequency slabs in this species (Cetas et al., 2002b).
A computer reconstruction of the large terminal TC field labeled by the BDA injection shown in Figure 8 (CM-29) is shown in Figure9. Note the anteroventral-to-posterodorsal orientation of the TC field, similar to that of CM-15 (Fig. 3) and CM-27 (Fig. 5). Multi-unit responses to acoustic stimulation were more robust within the terminal field than those outside the TC arbors (Fig. 9). The multi-unit response type (onset/sustained) is also consistent throughout the labeled terminal field. A stepwise frequency progression was observed within the TC patch. Binaurality was also consistent throughout the patch, with the majority being classified as EO.
Discussion
Auditory fields and TC patches
Although physiological (Colwell and Merzenich, 1975; Middlebrooks et al., 1980) and anatomical (Middlebrooks and Zook, 1983; Angelucci et al., 1993; McMullen and de Venecia, 1993; de Venecia and McMullen, 1994; Hashikawa et al., 1995; Cetas et al., 1999) evidence for the existence of multiple parallel pathways linking the auditory thalamus and AI has existed for years, there have been few attempts to correlate auditory physiological maps with TC circuits (Middlebrooks and Zook, 1983). In the present study, focal tracer injections in the MGV frequently resulted in a band of TC axons composed of multiple patches (McMullen and de Venecia, 1993). A consistent finding in the present study was that TC patches defined a cortical module with a particular BF. Electrophysiological mapping of several patches making up a band revealed a common BF within the band (experiment CM-15). In most cases, the TC axonal fields were aligned parallel to isofrequency contours in AI, an arrangement predicted by Tunturi (1950) more than 50 years ago. These results are consistent with anterograde and retrograde studies of auditory thalamic pathways that have shown that restricted areas of the MGV diverge to widespread areas along an isofrequency contour (Colwell and Merzenich, 1975; Merzenich et al., 1982; McMullen and de Venecia, 1993; Cetas et al., 1999). We conclude that functionally defined isofrequency contours in AI derive from the patchy divergent projections of auditory thalamic neurons.
Binaural interaction bands form an additional functional map in AI (Imig and Adrian, 1977; Middlebrooks et al., 1980). Neuronal groups projecting to either EE or EI bands are spatially segregated from one another within the MGV (Middlebrooks and Zook, 1983), suggesting the existence of several classes of MGV neurons with unique projections to AI. In the present study, clusters of binaural regions were found within AI composed of EE, EO, or EI response types, which crossed isofrequency contours. The distribution of binaural classes in the rabbit AI is similar to what has been described in AI of several other species, such as the cat (Imig and Adrian, 1977; Middlebrooks et al., 1980; Schreiner, 1991, 1995) and rat (Kelly and Sally, 1988), but has not been reported before in this species. TC patches were also associated with the clustered distribution of binaural classes in AI. In many cases, the patch boundaries defined the borders of binaural transitions (Fig. 7, EI–EO, EO–EE). Our results suggest that TC patches represent the anatomical substrate for frequency and binaural maps in AI. Several other discontinuous maps in the AI overlay the tonotopic and binaural maps and include sharpness of tuning (Schreiner, 1991; Recanzone et al., 1999), intensity tuning (Schreiner et al., 1992; Recanzone et al., 1999), latency (Recanzone et al., 1999), and temporal response properties (Schreiner, 1991; Schulze et al., 1997). How these maps relate to TC patches requires additional study.
In experiment CM-29, at least three distinct BFs were represented within a large TC field. In contrast, binaurality (as well as latency and response profile) remained consistent. We believe this finding is related to the number of frequency laminas encompassed by the MGV injection (Cetas et al., 2001). The frequency steps within the TC axonal field (0.7 octave) were identical to those observed in mapping penetrations across cell laminas in the MGV (Cetas et al., 2001). The constancy of binaural responses within the large patches is consistent with the distribution of binaural classes in the auditory thalamus. In the MGV of the rabbit (Cetas et al., 2001) and cat (Rodrigues-Dagaeff et al., 1989), binaural response classes are mapped independently of frequency.
Auditory cortical maps in the rabbit: comparison with other species
In our experiments, all TC patches but one were found in areas with a frequency organization that was typical of what has been reported in AI of the rabbit: a dorsoventral high-to-low frequency progression (McMullen and Glaser, 1982). This was expected, because our injections were made in the MGV, the source of the main lemniscal pathway to AI (Winer et al., 1977; Niimi and Matsuoka, 1979;Imig and Morel, 1983; McMullen and de Venecia, 1993). In AI of the rabbit, the tonotopic map and its representative isofrequency contours appear rotated 90° compared with that in cats and monkeys (Merzenich et al., 1973; Imig et al., 1977; Reale and Imig, 1980; Schreiner, 1991;Recanzone et al., 1999). This rotation is consistent with the relative orientation of cellular laminas in the MGV (Morest, 1965; Imig and Morel, 1984; Cetas et al., 2001). A tonotopic map with isofrequency contours similar to that of rabbits has been reported in an Australian marsupial (Aitkin et al., 1986) and in ferrets (Angelucci et al., 1993). In most mammalian species, the primary auditory field is surrounded by one or more tonotopically organized areas (Tunturi, 1950;Merzenich and Brugge, 1973; Imig et al., 1977; Reale and Imig, 1980;Redies et al., 1989; Hackett et al., 1998). In the rabbit, a secondary field with a tonotopic organization that mirrors AI lies dorsal to AI. Based on its frequency organization and its position relative to AI, this field appears to be the homolog to the anterior auditory field of the cat (Reale and Imig, 1980) and the dorsal caudal field of the guinea pig (Redies et al., 1989; Wallace et al., 2000).
Integrity of tracer-injected MGV
An important concern when performing combined anterograde labeling and mapping experiments is the possibility that the tracer used to label anatomical structures may damage or destroy cells at the injection site. In addition, uptake, transport, and distribution of the tracer could modify the transmission of information to axonal targets, thus altering the response profile of cortical sites coextensive with the labeled axons. The evidence that BDA injections into the MGV and its transport to AI did not result in alterations in the functional properties of AI include the following: (1) The cortical frequency maps obtained in our studies were very similar to those determined in previous mapping studies of NZW rabbits (McMullen and Glaser, 1982). (2) More importantly, experimental animals served as their own controls; adjacent cortical penetrations in which one electrode passed through a TC patch while the other did not were comparable in frequency progression, latency, sharpness of tuning, and response strength. (3) In some cases, the multi-unit responses within a TC patch were more exuberant than those outside the patch. One would expect the opposite effect if the BDA had eliminated excitatory input to cortical neurons. (4) In several cases, the BF of the injection site was represented within the area of a mapped TC patch. If neurons at the MGV injection site had been damaged or destroyed, we would not expect to see the BF of that area represented within a TC patch. In fact, we might expect to see areas of no response or frequency gaps during cortical mapping, but this was not the case. We conclude that the cortical response properties were not significantly affected by the thalamic injections of BDA.
A model of MGB–AI connections
One of the problems in understanding auditory TC relationships is the difficulty of reconciling continuously distributed functional maps (e.g., frequency) with those exhibiting a discontinuous (e.g., binaural) organization. A model incorporating both of these features of TC circuitry based on anatomical and physiological data (Cetas et al., 1999, 2001, 2002a,b) is shown in Figure10. In this model, TC axons originating from binaural-specific relay neurons located in frequency slabs in the MGV terminate in patches along a frequency strip in AI. Adjacent MGB neurons within the same frequency slab but coding for a different binaural class project to separate fields within the same frequency strip. This model explains how continuous and discontinuous maps in AI derive from patchy TC circuits.
Footnotes
This work was supported by National Institutes of Health (NIH)/National Institute of Neurological and Communicative Disorders and Stroke Grants DC05108 (D.S.V.) and DC02410 (N.T.M.) and a Deafness Research Foundation Award (D.S.V.). J.S.C. was the recipient of a Predoctoral Fellowship from NIH Training Grant NS07434. R.O.P. was supported by the Undergraduate Biology Research Program at the University of Arizona and the Howard Hughes Medical Institute. We thank Dr. Naomi Rance for useful comments on a previous version of this manuscript, Jeb Zirato for his help with the photomicroscopy, and Vanessa Lopez for assistance with generation of computer reconstructions of thalamocortical patches.
Correspondence should be addressed to Dr. D. S. Velenovsky, Department of Cell Biology and Anatomy, University of Arizona College of Medicine, P.O. Box 245044, 1501 North Campbell Avenue, Tucson, AZ 85724. E-mail: dsv{at}u.arizona.edu.