Hiroaki Tsukano

Transcranial photo-inactivation of neural activities in the mouse auditory cortex.

Flavoprotein fluorescence in the brain is intimately coupled with neuronal aerobic energy metabolism. If flavoproteins are photobleached, neural activities may be affected owing to dysfunction in aerobic energy metabolism in mitochondria. We tested this possibility in cortical slices from mice, and found that exposure to blue light (lambda = 475 nm) derived from a 20 mW diode laser for 50 min suppresses trans-synaptic components of field potentials. This finding formed the basis of a transcranial photo-inactivation technique, that was used to investigate auditory signal transmission between the anterior auditory field (AAF) and the primary auditory cortex (AI) in anesthetized mice. Cortical responses in AAF and AI, elicited by 5 kHz tonal stimuli, were visualized using transcranial flavoprotein fluorescence imaging. After determining responsive areas in AAF and AI, the auditory cortex was exposed to the blue diode laser via the intact skull, while either AAF or AI was protected with a piece of carbon paper. Although the photo-inactivation of AI had no significant effect on the fluorescence responses in AAF, the photo-inactivation of AAF significantly reduced the fluorescence responses in AI, indicating the presence of auditory signal transmission from AAF to AI.

Visual Map Shifts based on Whisker-Guided Cues in the Young Mouse Visual Cortex

Mice navigate nearby space using their vision and whiskers, and young mice learn to integrate these heterogeneous inputs in perceptual space. We found that cortical responses were depressed in the primary visual cortex of young mice after wearing a monocular prism. This depression was uniformly observed in the primary visual cortex and was eliminated by whisker trimming or lesions in the posterior parietal cortex. Compensatory visual map shifts of responses elicited via the eye that had worn the prism were also observed. As a result, cortical responses elicited via each eye were clearly separated when a visual stimulus was placed in front of the mice. A comparison of response areas before and after prism wearing indicated that the map shifts were produced by depression with spatial eccentricity. Visual map shifts based on whisker-guided cues may serve as a model for investigating the cellular and molecular mechanisms underlying higher sensory integration in the mammalian brain.

Auditory cortical areas activated by slow frequency-modulated sounds in mice

Species-specific vocalizations in mice have frequency-modulated (FM) components slower than the lower limit of FM direction selectivity in the core region of the mouse auditory cortex. To identify cortical areas selective to slow frequency modulation, we investigated tonal responses in the mouse auditory cortex using transcranial flavoprotein fluorescence imaging. For differentiating responses to frequency modulation from those to stimuli at constant frequencies, we focused on transient fluorescence changes after direction reversal of temporally repeated and superimposed FM sweeps. We found that the ultrasonic field (UF) in the belt cortical region selectively responded to the direction reversal. The dorsoposterior field (DP) also responded weakly to the reversal. Regarding the responses in UF, no apparent tonotopic map was found, and the right UF responses were significantly larger in amplitude than the left UF responses. The half-max latency in responses to FM sweeps was shorter in UF compared with that in the primary auditory cortex (A1) or anterior auditory field (AAF). Tracer injection experiments in the functionally identified UF and DP confirmed that these two areas receive afferent inputs from the dorsal part of the medial geniculate nucleus (MG). Calcium imaging of UF neurons stained with fura-2 were performed using a two-photon microscope, and the presence of UF neurons that were selective to both direction and direction reversal of slow frequency modulation was demonstrated. These results strongly suggest a role for UF, and possibly DP, as cortical areas specialized for processing slow frequency modulation in mice.

Dual compartments of the ventral division of the medial geniculate body projecting to the core region of the auditory cortex in C57BL/6 mice

We investigated precise projection patterns from the ventral division of the medial geniculate body (MGv) projecting to the core region of the auditory cortex in C57BL/6 mice. The core region in mice comprises two different tonotopically organized areas, the anterior auditory field (AAF) and the primary auditory cortex (AI). In the present study, AAF and AI were functionally identified using flavoprotein fluorescence imaging. Biotinylated dextran amine (BDA) was injected iontophoretically into the tonotopic bands to 5kHz and 20kHz in AAF, and those to 5kHz, 10kHz, and 20kHz in AI for staining MGv neurons projecting to the injected sites. MGv neurons projecting to AAF were found in the medial part of MGv, while MGv neurons projecting to AI were found in the lateral part. In the medial part of MGv, areas projecting to 5-20kHz bands in AAF were aligned along the medio lateral axis. In the lateral part of MGv, areas projecting to 5-20kHz bands in AI were aligned along the dorso ventral axis. These results indicate that AAF and AI receive auditory information via two different MGv compartments with independent tonotopic axes, respectively.

Quantitative map of multiple auditory cortical regions with a stereotaxic fine-scale atlas of the mouse brain

Optical imaging studies have recently revealed the presence of multiple auditory cortical regions in the mouse brain. We have previously demonstrated, using flavoprotein fluorescence imaging, at least six regions in the mouse auditory cortex, including the anterior auditory field (AAF), primary auditory cortex (AI), the secondary auditory field (AII), dorsoanterior field (DA), dorsomedial field (DM), and dorsoposterior field (DP). While multiple regions in the visual cortex and somatosensory cortex have been annotated and consolidated in recent brain atlases, the multiple auditory cortical regions have not yet been presented from a coronal view. In the current study, we obtained regional coordinates of the six auditory cortical regions of the C57BL/6 mouse brain and illustrated these regions on template coronal brain slices. These results should reinforce the existing mouse brain atlases and support future studies in the auditory cortex.

Cortical depression in the mouse auditory cortex after sound discrimination learning

Cortical responses after sound discrimination learning were investigated using transcranial flavoprotein fluorescence imaging in mice. Water-deprived mice were trained to discriminate between rewarded (S+) and unrewarded (S-) sound stimuli. After the learning, they were anesthetized, and cortical responses to S+ and S- were recorded in the right auditory cortex. When a pure tone (PT) at 10 kHz and a 10 kHz amplitude-modulated (AM) sound were used as S+ and S-, the cortical responses to S- using AM were significantly depressed but those to S- using PT were not. The cortical responses to S+ showed no significant change. Upward frequency-modulated sounds from 5 kHz to 40 kHz (FM upward arrow) and downward frequency-modulated sounds from 40 kHz to 5 kHz (FM downward arrow) were also used as S+ and S-. Cortical responses to S- using FM[upward arrow] and FM[downward arrow] were significantly depressed after learning, while those to S+ were unchanged. No significant change of cortical responses to S- using FMs was observed in the left auditory cortex after learning. The learning-induced depression of S- using FMs was most clearly observed in the medial part of the tonotopic band to 40 kHz in the right primary auditory cortex, which might be involved in processing FM sounds.

Impaired clustered protocadherin-α leads to aggregated retinogeniculate terminals and impaired visual acuity in mice.

Clustered protocadherins (cPcdhs) comprising cPcdh‐α, ‐β, and ‐γ, encode a large family of cadherin‐like cell‐adhesion molecules specific to neurons. Impairment of cPcdh‐α results in abnormal neuronal projection patterns in specific brain areas. To elucidate the role of cPcdh‐α in retinogeniculate projections, we investigated the morphological patterns of retinogeniculate terminals in the lateral geniculate (LG) nucleus of mice with impaired cPcdh‐α. We found huge aggregated retinogeniculate terminals in the dorsal LG nucleus, whereas no such aggregated terminals derived from the retina were observed in the olivary pretectal nucleus and the ventral LG nucleus. These aggregated terminals appeared between P10 and P14, just before eye opening and at the beginning of the refinement stage of the retinogeniculate projections. Reduced visual acuity was observed in adult mice with impaired cPcdh‐α, whereas the orientation selectivity and direction selectivity of neurons in the primary visual cortex were apparently normal. These findings suggest that cPcdh‐α is required for adequate spacing of retinogeniculate projections, which may be essential for normal development of visual acuity.

Chondroitin Sulfate Is Required for Onset and Offset of Critical Period Plasticity in Visual Cortex

Ocular dominance plasticity is easily observed during the critical period in early postnatal life. Chondroitin sulfate (CS) is the most abundant component in extracellular structures called perineuronal nets (PNNs), which surround parvalbumin-expressing interneurons (PV-cells). CS accumulates in PNNs at the critical period, but its function in earlier life is unclear. Here, we show that initiation of ocular dominance plasticity was impaired with reduced CS, using mice lacking a key CS-synthesizing enzyme, CSGalNAcT1. Two-photon in vivo imaging showed a weaker visual response of PV-cells with reduced CS compared to wild-type mice. Plasticity onset was restored by a homeoprotein Otx2, which binds the major CS-proteoglycan aggrecan and promotes its further expression. Continuous CS accumulation together with Otx2 contributed bidirectionally to both onset and offset of plasticity, and was substituted by diazepam, which enhances GABA function. Therefore, CS and Otx2 may act as common inducers of both onset and offset of the critical period by promoting PV-cell function throughout the lifetime.

Specific distribution of non-phosphorylated neurofilaments characterizing each subfield in the mouse auditory cortex.

Recent imaging studies revealed the presence of functional subfields in the mouse auditory cortex. However, little is known regarding the morphological basis underlying the functional differentiation. Distribution of particular molecules is the key information that may be applicable for identifying auditory subfields in the post-mortem brain. Immunoreactive patterns using SMI-32 monoclonal antibody against non-phosphorylated neurofilament (NNF) have already been used to identify or parcellate various brain regions in various animals. In the present study, we investigated whether distribution of NNF is a reliable marker for identifying functional subfields in the mouse auditory cortex, and found that each auditory subfield has region-specific cellular and laminar patterns of immunoreactivity for NNF.

Age-related deterioration of cortical responses to slow FM sounds in the auditory belt region of adult C57BL/6 mice

To compare age-related deterioration of neural responses in each subfield of the auditory cortex in C57BL/6 mice, we evaluated amplitudes of tonal responses in young (5-11 weeks old) and adult (16-23 weeks old) groups using transcranial flavoprotein fluorescence imaging. Cortical responses to 20-kHz amplitude-modulated (AM) sounds, which were mainly found in the anterior auditory field (AAF) and the primary auditory cortex (AI) of the core region, were not markedly different between the two groups. In contrast, cortical responses to direction reversal of slow frequency-modulated (FM) sounds, which were mainly found in the ultrasonic field (UF), were significantly disrupted in the adult group compared with those in the young group. To investigate the mechanisms underlying such age-related deterioration, biotinylated dextran amine (BDA) was injected into UF. The number of retrograde labeled neurons in the dorsal division of the medial geniculate body (MGd) was markedly reduced in the adult group compared with that in the young group. These results strongly suggest that cortical responses to FM direction reversal in UF of adult C57BL/6 mice are mainly deteriorated by loss of non-lemniscal thalamic inputs from MGd to UF due to aging.