Hiroaki Oniki

Immunocytochemical studies of aquaporin 4 in the skeletal muscle of mdx mouse

Immunostainability of anti aquaporin 4 antiserum was investigated in the muscles of dystrophin deficient mdx mice. Western blot analysis showed that the rabbit antiserum against aquaporin 4 reacted with a 28 kDa protein in extracts of normal mouse quadriceps femoris muscles but did not react with the protein in extracts of quadriceps femoris muscles of mdx mice. Immunoperoxidase staining of the muscles from normal and mdx mice revealed the positive immunoreaction at the myofiber surface of normal mice and the negative, or the faint and discontinuous immunostaining at the surface of mdx myofibers. Immunogold electron microscopy disclosed the localization of aquaporin 4 molecules at the myofiber plasma membranes of normal mice and the localization was consistent with that of orthogonal array particles in the protoplasmic face of normal muscle plasma membrane seen in freeze fracture replicas. This study demonstrated that the density of aquaporin 4 molecules was decreased in the muscle plasma membranes of mdx mice, resulting in the faulty function of mdx myofibers.

Ultrastructural localization of α1-syntrophin and neuronal nitric oxide synthase in normal skeletal myofiber, and their relation to each other and to dystrophin

Abstract We investigated the ultrastructural localization of α1-syntrophin and neuronal nitric oxide synthase (nNOS) in normal human skeletal myofibers and analyzed their relation to each other and to dystrophin using single and double immunogold-labeling electron microscopy. Single immunolabeling showed antibodies to α1-syntrophin and nNOS on the inner surface of the muscle plasma membrane, the sarcoplasmic side of plasma membrane invaginations, and the sarcoplasm near mitochondria of subsarcolemmal areas. The epitopes of α1-syntrophin and nNOS tended to be present in clusters. Double immunolabeling revealed that epitope combinations of α1-syntrophin-dystrophin, α1-syntrophin-nNOS, and nNOS-dystrophin occurred more frequently in doublet form than did other epitope combinations, such as α1-syntrophin-β-spectrin and nNOS-β-spectrin. These increased frequencies were noted both at the muscle plasma membrane undercoat and near mitochondria of subsarcolemmal areas. A significantly higher percentage of doublets comprised antibodies against α1-syntrophin and dystrophin (28.5 ± 1.5%, group mean ± SE) than those against α1-syntrophin and β-spectrin (9.2 ± 0.8%, P < 0.01). Furthermore, nNOS formed doublets significantly more frequently with dystrophin (25.2 ± 3.3%) and α1-syntrophin (26.0 ± 4.1%) than with β-spectrin (13.9 ± 2.3%; P < 0.05). These data support the association of dystrophin, α1-syntrophin, and nNOS at the inner surface of the muscle plasma membrane and near mitochondria of subsarcolemmal areas of normal human skeletal myofibers.

Expression of aquaporin 3 and its localization in normal skeletal myofibres

The question whether aquaporin 3 (AQP3) is expressed in normal human skeletal muscle at mRNA and protein levels has been examined, since AQP3 has been reported to be coexpressed with AQP4 in various kinds of tissues other than skeletal muscle. The gel electrophoresis of the reverse transcription polymerase chain reaction (RT-PCR) product of total RNA samples extracted from normal human muscle specimens by using the oligonucleotide primers for AQP3 contained a band of 629 base pairs which corresponded to the base pair length between two primers of AQP3. The nucleotide sequence of this RT-PCR product coincided with that of AQP3. At the protein level, immunoblot, immunohistochemical and immunoelectron microscopical studies were done by using rabbit antibody against the synthetic peptide of the cytoplasmic domain of the human AQP3 molecule. Immunoblot analysis showed that rabbit antibody against the human AQP3 reacted with a protein of approximately 30 kDa molecular weight in extracts of normal human skeletal muscles. The immunoreaction for the anti-AQP3 antibody with normal human muscle was noted at the myofibre surface. Immunogold labelling electron microscopy revealed that the gold particles indicating the presence of AQP3 molecules were located mainly at the inside surface of muscle plasma membrane.

Size and localization of dystrophin molecule: immunoelectron microscopic and freeze etching studies of muscle plasma membranes of murine skeletal myofibers.

The ultrastructure and mode of existence of the dystrophin molecule and its relations to actin filaments were examined in murine skeletal myofibers. Electron microscopy of freeze-etched replicas of goldlabelled dystrophin molecules in quick-freeze, deepetch, rotary-shadow preparations revealed rod-like structures 108.2±16.3 nm long and 3.1±1.5 nm thick. Some dystrophin molecules appeared to link their ends to form anastomosing networks; others were separate from each other. The dystrophin molecules were parallel or nearly parallel to the inner surface of the muscle plasma membrane. Double immuno-labelling transmission electron microscopy using N- and C-terminal dystrophin antibodies showed that the group mean distances of the N- and C-terminal signals from the muscle plasma membrane were 52.7±8.1 nm and 45.9±11.3 nm, respectively, which were not significantly different. Histograms of the distribution of the N- and C-terminal distances from the muscle plasma membrane had similar patterns with peaks 10∼20 nm from the membrane. This was consistent with the findings of the mode of existence of dystrophin molecules seen in freeze-etched replicas. Finally, the dystrophin molecules were linked with the most peripheral sarcoplasmic actin like filaments, end to side as well as end to end.

Immunocytochemical Studies of Aquaporin 4, Kir4.1, and α1-syntrophin in the Astrocyte Endfeet of Mouse Brain Capillaries

One of the most important physiological roles of brain astrocytes is the maintenance of extracellular K+ concentration by adjusting the K+ influx and K+ efflux. The inwardly rectifying K+ channel Kir4.1 has been identified as an important member of K+ channels and is highly concentrated in glial endfeet membranes. Aquaporin (AQP) 4 is another abundantly expressed molecule in astrocyte endfeet membranes. We examined the ultrastructural localization of Kir4.1, AQP4, α1-syntrophin, and β-spectrin molecules to understand the functional role(s) of Kir4.1 and AQP4. Immunogold electron microscopy of these molecules showed that the signals of these molecules were present along the plasma membranes of astrocyte endfeet. Double immunogold electron microscopy showed frequent co-localization in the combination of molecules of Kir4.1 and AQP4, Kir4.1 and α1-syntrophin, and AQP4 and α1-syntrophin, but not those of AQP4 and β-spectrin. Our results support biochemical evidence that both Kir4.1 and AQP4 are associated with α1-syntrophin by way of postsynaptic density-95, Drosophila disc large protein, and the Zona occludens protein I protein-interaction domain. Co-localization of AQP4 and Kir4.1 may indicate that water flux mediated by AQP4 is associated with K+ siphoning.

Three-dimensional ultrastructure of anionic sites of the glomerular basement membrane by a quick-freezing and deep-etching method using a cationic tracer

SummaryThe ultrastructure of anionic sites in the lamina rara externa (LRE) of rat glomerular basement membrane (GBM) was studied in three dimensions by a quick-freezing and deep-etching method using polyethyleneimine (PEI) as a cationic tracer. Results were compared with those obtained with conventional ultrathin sections examined by transmission electron microscopy. Examination with the quick-freezing and deep-etching method was done without (group 1) or with (group 2) contrasting/fixation with a phosphotungstic acid and glutaraldehyde mixture and post-fixation with osmium tetroxide, which were necessary for visualization of PEI particles by conventional ultrathin sections. Using the quick-freezing and deep-etching method without following contrasting/fixation and post-fixation (group 1), many PEI particles were observed to decorate around fibrils, which radiated perpendicularly from the lamina densa to connect with the podocyte cell membrane. The arrangement of PEI particles was not as regular as that previously reported using conventional ultrathin sections. In contrast, the tissue that was studied with quick-freezing and deep-etching followed by contrasting/fixation and post-fixation (group 2) showed a shrunken appearance. The arrangement of PEI particles was regular (about 20 particles/1000 nm of LRE) as that previously observed using conventional ultrathin sections. However, the number of PEI particles on the LRE was markedly decreased and interruption of decorated fibrils was prominent, as compared with group 1. Ultrastructural examination using conventional ultrathin sections with contrasting/fixation and post-fixation (group 3) demonstrated PEI particles on the LRE in reasonable amounts (18–21 particles/1000 nm of LRE) with fairly regular interspacing (45–65 nm) as reported previously.This is the first report to identify the three-dimensional ultrastructure of anionic sites of GBM, and provides new information on the location and distribution of anionic sites in the glomerular capillary wall. In addition, these studies suggest that several chemical procedures used in conventional transmission electron microscopy to visualize PEI tracers, may produce structural changes and disarrangement of PEI particles that can be avoided with the quick-freezing and deep-etching method.

Actin -related protein 3 (Arp3) is mutated in proteinuric BUF/Mna rats

The BUF/Mna strain of rat is a model of focal and segmental glomerulosclerosis (FSGS) in which a quantitative trait locus (QTL) for proteinuria, Pur1, has been identified. The aim of the present study was to identify candidates for the Pur1 gene. To narrow the Pur1 QTL, we performed fine QTL mapping and single nucleotide polymorphism (SNP) genotyping. To identify candidate genes, sequencing and gene-expression analyses of all genes contained in the narrowed locus were conducted. The narrowed Pur1 region contained 25 genes. Among these genes, only the Arp3 gene was mutated in the BUF/Mna strain; it contained a missense mutation that caused an L111F substitution. This leucine is conserved across species. Gene-expression analysis failed to identify any other candidate genes for Pur1. Arp3-mediated actin assembly abnormalities were visible in immunohistochemical and electron microscopic examinations of podocytes in old BUF/Mna rats. Taken together, these data suggest that Arp3 is a candidate for the Pur1 gene. This observation is consistent with our growing recognition that abnormal signaling-induced assembly of actin in podocytes leads to the development of FSGS.

Merosin (laminin-2) localization in basal lamina of normal skeletal muscle fibers and changes in plasma membrane of merosin-deficient skeletal muscle fibers

Primary deficiency of merosin causes a severe congenital muscular dystrophy (CMD) and a mouse dystrophy (dy/dy mouse). Also, its secondary deficiency is seen in some CMD with abnormal glycosylation of Α-dystroglycan, an extracellular membrane protein, which is the receptor of merosin and binds to dystrophin underlying the sarcolenma via Β-dystroglycan, a transmembrane protein. In immunogold and freeze-etch electron microscopic studies, merosin in basal lamina of normal skeletal muscles has a zonation in the distribution and is localized at the lamina lucida of muscle basal lamina, and dystrophin molecules are often closed to merosin molecules at the inside and outside surface of muscle plasma membrane. Moreover, merosin molecules exist as the short fine cross-bridge fibrils connecting the basal lamina to the neighboring outer leaflet of the muscle plasma membrane. In freeze-fracture studies, the changes in muscle plasma membranes of dy/dy mice reveal a markedly decreased density of orthogonal arrays (OAs) but normal density of intramembranous particles (IMPs), whereas depletions of IMPs with decreased OAs have been found in Fukyama-type congenital muscular dystrophy, Duchenne muscular dystrophy, and mdx mice. Thus, further studies including the functional role of OAs would be required to understand the pathomechanism of merosin-deficient CMD.

Electron microscopic observations of triple immunogold labelling for dystrophin, β-dystroglycan and adhalin in human skeletal myofibers

Abstract Dystrophin is the Duchenne muscular dystrophy gene product and is a membrane cytoskeletal protein present in the network of the plasma membrane undercoat. Adhalin (50 kDa dystrophin-associated glycoprotein) and β-dystroglycan (43 kDa dystrophin-associated glycoprotein) are the transmembrane components of the normal muscle plasma membrane, and β-dystroglycan has been demonstrated to bind dystrophin at the inside surface of normal muscle plasma membrane. This investigation was undertaken to test whether the epitopes of dystrophin, β-dystroglycan and adhalin are closely associated with each other by using triple immunogold labelling electron microscopy on normal human skeletal myofibers. Although closely associated signals of triplet immunogold particles were observed, there were less numerous than expected. However, closely associated signals of two epitopes of dystrophin and β-dystroglycan, dystrophin and adhalin, or adhalin and β-dystroglycan were frequently observed. These ultrastructural findings are consistent with biochemical evidence implying that dystrophin, β-dystroglycan and adhalin are closely associated with each other at the normal muscle plasma membrane.

Changes in the distribution and density of caveolin 3 molecules at the plasma membrane of mdx mouse skeletal muscles: a fracture-label electron microscopic study

To analyze the molecular mechanism of the increased caveolin 3 activities in dystrophin-deficient muscles, we investigated three-dimensionally the changes in caveolin 3 molecular distribution and density at the sarcolemma of mdx mice by the fracture-label electron microscopic technique. At the sarcolemma of skeletal muscles from mdx mice, the densities of gold particles associated with caveolae, non-associated with caveolae and arranged circularly without caveolae were higher than those in control mice (P<0.01, P<0.01 and P<0.05 by two-tailed t-test), although in mdx mice, the overall arrangement of gold particles appeared to be irregular. These findings may reflect the active process of caveolar formation and the results of the disrupted protein-protein interaction in dystrophin-deficient muscle plasma membrane.