Kv4.2-Positive Domains on Dendrites in the Mouse Medial Geniculate Body Receive Ascending Excitatory and Inhibitory Inputs Preferentially From the Inferior Colliculus.

The medial geniculate body (MGB) is the thalamic center of the auditory lemniscal pathway. The ventral division of MGB (MGV) receives excitatory and inhibitory inputs from the inferior colliculus (IC). MGV is involved in auditory attention by processing descending excitatory and inhibitory inputs from the auditory cortex (AC) and reticular thalamic nucleus (RTN), respectively. However, detailed mechanisms of the integration of different inputs in a single MGV neuron remain unclear. Kv4.2 is one of the isoforms of the Shal-related subfamily of potassium voltage-gated channels that are expressed in MGB. Since potassium channel is important for shaping synaptic current and spike waveforms, subcellular distribution of Kv4.2 is likely important for integration of various inputs. Here, we aimed to examine the detailed distribution of Kv4.2, in MGV neurons to understand its specific role in auditory attention. We found that Kv4.2 mRNA was expressed in most MGV neurons. At the protein level, Kv4.2-immunopositive patches were sparsely distributed in both the dendrites and the soma of neurons. The postsynaptic distribution of Kv4.2 protein was confirmed using electron microscopy (EM). The frequency of contact with Kv4.2-immunopositive puncta was higher in vesicular glutamate transporter 2 (VGluT2)-positive excitatory axon terminals, which are supposed to be extending from the IC, than in VGluT1-immunopositive terminals, which are expected to be originating from the AC. VGluT2-immunopositive terminals were significantly larger than VGluT1-immunopositive terminals. Furthermore, EM showed that the terminals forming asymmetric synapses with Kv4.2-immunopositive MGV dendritic domains were significantly larger than those forming synapses with Kv4.2-negative MGV dendritic domains. In inhibitory axons either from the IC or from the RTN, the frequency of terminals that were in contact with Kv4.2-positive puncta was higher in IC than in RTN. In summary, our study demonstrated that the Kv4.2-immunopositive domains of the MGV dendrites received excitatory and inhibitory ascending auditory inputs preferentially from the IC, and not from the RTN or cortex. Our findings imply that time course of synaptic current and spike waveforms elicited by IC inputs is modified in the Kv4.2 domains.

Double superior venae cavae with absence of the coronary sinus and anomalies of the azygos venous system.

The superior vena cava is formed during the fetal period by the development of anastomoses between the right and left anterior cardinal veins, and the regression of the central part of the left anterior cardinal vein. The persistence of this part of the left anterior cardinal vein causes the formation of a left superior vena cava, which is a rare anomaly in cadaver dissection. We report the case of a persistent left superior vena cava with a normal right superior vena cava in a 95-year-old male cadaver, which was discovered during anatomical dissection for medical students at Kawasaki Medical School in 2016. The left superior vena cava was formed by the confluence of the left internal jugular and left subclavian veins and terminated in the right atrium via what would normally be the coronary sinus. The right and left superior venae cavae received intercostal veins via a right and left azygos vein, respectively. However, the right azygos vein was shorter than the normal azygos vein and received only the second to fifth intercostal veins, whereas the left azygos vein received the fifth to eleventh left intercostal veins and the sixth to eleventh right intercostal veins. We consider that the anomalies of the azygos venous system were the result of regression of right supracardinal vein and the persistence of the left supracardinal vein during development. An awareness of such variations of major thoracic veins is important for the interpretation of unusual CT images.

Examination of morphological and synaptic features of calbindin-immunoreactive neurons in deep layers of the rat olfactory bulb with correlative laser and volume electron microscopy.

The olfactory bulb (OB) contains various interneuron types that play key roles in processing olfactory information via synaptic contacts. Many previous studies have reported synaptic connections of heterogeneous interneurons in superficial OB layers. In contrast, few studies have examined synaptic connections in deep layers because of the lack of a selective marker for intrinsic neurons located in the deeper layers, including the mitral cell layer, internal plexiform layer (IPL) and granule cell layer. However, neural circuits in the deep layers are likely to have a strong effect on the output of the OB because of the cellular composition of these regions. Here, we analyzed the calbindin-immunoreactive neurons in the IPL, one of the clearly neurochemically defined interneuron types in the deep layers, using multiple immunolabeling and confocal laser scanning microscopy combined with electron microscopic three-dimensional serial-section reconstruction, enabling correlated laser and volume electron microscopy (EM). Despite a resemblance to the morphological features of deep short axon cells, IPL calbindin-immunoreactive (IPL-CB-ir) neurons lacked axons. Furthermore, multiple immunolabeling for plural neurochemicals indicated that IPL-CB-ir neurons differed from any interneuron types reported previously. We identified symmetrical synapses formed by IPL-CB-ir neurons on granule cells (GCs) using correlated laser and volume EM. These synapses might inhibit GCs and thus disinhibit mitral and tufted cells. Our present findings indicate, for the first time, that IPL-CB-ir neurons are involved in regulating the activities of projection neurons, further suggesting their involvement in synaptic circuitry for output from the deeper layers of the OB, which has not previously been clarified.

[A histological study and three-dimensional reconstruction of F4/80-positive reticular cells and macrophages at the onset of murine bone marrow hematopoiesis].

Adult bone marrow consists of two different compartments, a vascular compartment of sinusoid and a hematopoietic compartment consisting of stromal cells and hematopoietic cells. In the hematopoietic compartment, stromal cells play an important role in the formation of the microenvironment for hematopoiesis. To clarify the relationship between hematopoietic cells and stromal cells, particularly reticular cells and macrophages, we examined the femur bone marrow of ICR mouse fetuses and neonates using F4/80 immunostaining and three-dimensional reconstruction under light and electron microscopy. In the fetal femurs, the marrow cavity formed early from 15 days of gestation, and it showed a marked increase in volume thereafter. On the basis of the appearance of hematopoietic cells, marrow development could be classified into two stages, a pre-hematopoietic stage from 15 days of gestation to two days of age, and a beginning stage of hematopoiesis thereafter. The pre-hematopoietic bone marrow contains not only stromal reticular cells but also macrophages, and both types of stromal cells were strongly positive to F4/80 monoclonal antibody. These F4/80-positive reticular cells had a triangular cell profile with long and slender cytoplasmic processes. Reticular cells often contained large lysosomes of not only dying neutrophils but also erythroblast nuclei. A few erythroblasts accumulated around the processes, and the number of erythroblasts around reticular cells increased with bone marrow development. On the other hand, macrophages were located either close to sinusoids or in sinusoid lumen, and a close relationship to hematopoietic cells was hardly noticeable. At the beginning stage of hematopoiesis, F4/80-positive reticular cells extended their long and slender cytoplasmic processes, and the number and length of the processes appeared markedly increased. The three-dimensional cell surface of the F4/80-positive reticular cells became very complex. Numerous erythroblasts accumulated around the processes, and erythroblastic islands could gradually be recognized after four days of age. In the erythroblastic islands, central reticular cells were F4/80-positive and contained numerous large phagosomes originating from the expelled nuclei of erythroblasts. Although macrophages contained large phagosomes, the relationship between macrophages and hematopoietic cells could not clearly be elucidated even at the beginning stage of hematopoiesis. At the onset of bone marrow hematopoiesis, the hematopoietic compartment contained two kinds of F4/80-positive phagocytes, i.e., reticular cells and macrophages. In marrow erythroblastic islands, not macrophages but F4/80-positive reticular cells were located at the center of each island.

An ultrastructural and biochemical study of foot structure in "catch" smooth muscle cells of a clam.

The foot structure of molluscan (clam) catch muscle cells was studied from the structural and biochemical standpoints. In vertebrate cross striated muscle cells, foot structures are situated in the interspaces between T-tubules and sarcoplasmic reticula (SRs). By contrast, T-tubules were not observed in clam catch muscle cells, but foot structures were ultrastructurally identified in the interspaces between the SRs and cell membranes. We isolated the SR fraction from muscle cells which contained vesicles with SRs and cell membranes. Foot structures were also observed in the SR fraction by thin sectioning. The size and shape of the foot structure in both intact muscle cells and the SR fractions appeared to be slightly smaller than those of vertebrates. However, the molecular weight of the foot structures (foot proteins) as determined by SDS-PAGE (450 kD) was similar to ryanodine receptors (RyRs) which were reported previously in cross striated muscle cells from pecten and vertebrates. The protein showing the 450 kD band reacted to an anti-ryanodine receptor by Western blotting. These findings are discussed in comparison with previous studies of foot structures and RyRs of vertebrates and invertebrates.