Toshitaka Akisaka

Organization of cytoskeletal F-actin, G-actin, and gelsolin in the adhesion structures in cultured osteoclast.

Immunofluorescence using Gc protein (group‐specific component or vitamin D binding protein [DBP]) as a marker of G‐actin showed that nonfilamentous, monomeric G‐actin is a component of the podosomes of osteoclasts cultured on glass plates or bone slices. Typical individual podosomes of the well‐spread cells on glass plates were rosette in form. When viewed from the basolateral surface, the core portion of the dotlike podosomes was associated with packed F‐actin filaments surrounded by G‐actin organized in a ringlike structure. The podosomes, when viewed perpendicular to the substrate, showed a conical shape as a bundle of short F‐actin core and a ring of G‐actin. With cell spreading on glass plates, the clustering of the podosomes formed a continuous belt of tightly packed podosomes as an adhesion structure at the paramarginal area. In addition, these structures were seen on the ventral cell surface. Similar changes in cell shape were seen in the osteoclasts when they were plated on bone slices. With the loss of dotlike podosomes, a continuous band of F‐actin was formed around the resorption lacunae. It became evident then that F‐ and G‐actin dissociated from each other in the podosomes. The staining patterns of G‐actin varied from a discrete dot to a diffuse one. Toward the nonresorption phase, the osteoclasts lost their continuous F‐actin band but dotlike podosomes appeared in the leading and the trailing edges. In such a cell undergoing translational movements, G‐actin was located diffusely in the cytoplasm behind the lamellipodia and along some segments of the leading edge. Cytochalasin B treatment caused cells to disorganize the actin cytoskeletal architecture, which indicated the disassembling of F‐actin into G‐actin in podosomes and disappearance of actin‐ring of cultured osteoclasts. Staining with polyclonal actin antibody or monoclonal β‐actin was overlapped with the distribution pattern of G‐ and F‐actin. Gelsolin was detected in the region of the adhesion area corresponding to the podosome. The observation that F‐actin, G‐actin, and gelsolin were detected in the osteoclastic adhesion structures suggests that the podosomes may represent sites where a rapid polymerization/depolymerization of actin occurs. These dynamic changes in cytoskeletal organization and reorganization of G‐actin may reflect changes in the functional polarization of the osteoclast during the bone resorption cycle and suggest the important role of G‐actin in the regulation of osteoclast adhesion.

Adhesion structures and their cytoskeleton-membrane interactions at podosomes of osteoclasts in culture

The organization of the cytoskeleton in the podosomes of osteoclasts was studied by use of cell shearing, rotary replication, and fluorescence cytochemical techniques. After shearing, clathrin plaques and particles associated with the cytoskeleton were left behind on the exposed cytoplasmic side of the membrane. The cytoskeleton of the podosomes was characterized by two types of actin filaments: relatively long filaments in the portion surrounding the podosome core, and highly branched short filaments in the core. Individual actin filaments radiating from the podosomes interacted with several membrane particles along the length of the filaments. Many lateral contacts with the membrane surface by the particles were made along the length of individual actin filaments. The polarity of actin filaments in podosomes became oriented such that their barbed ends were directed toward the core of podosomes. The actin cytoskeletons terminated or branched at the podosomes, where the membrane tightly adhered to the substratum. Microtubules were not usually present in the podosome structures; however, certain microtubules appeared to be morphologically in direct contact with the podosome core. Most of the larger clathrin plaques consisted of flat sheets of clathrin lattices that interconnected neighboring clathrin lattices to form an extensive clathrin area. However, the small deeply invaginated clathrin plaques and the podosomal cytoskeleton were located close together. Thus, the clathrin plaques on the ventral membrane of osteoclasts might be involved in both cell adhesion and the formation of receptor-ligand complexes, i.e., endocytosis.

Ultrastructural Localization of Calcium-Activated Adenosine Triphosphatase (Ca2-ATPase) in Growth-Plate Cartilage'

The electron-microscopic cytochemical localization of calcium-activated adenosine triphosphatase (Ca2+-ATPase) was determined in chick epiphyseal growth-plate cartilage. In the reserve zone, mitochondria and lysosomes contained substantial amounts of reaction product, while the plasma membrane and the Golgi complex showed very weak enzymatic activity, and matrix vesicle membranes did not exhibit the cytochemical reaction. As maturation proceeded, the plasma membrane, Golgi complex, and matrix vesicle membranes also stained and were most intense in the proliferative and early hypertrophic zones. From the hypertrophic to the calcifying zone, cytochemical staining decreased progressively in the plasma membrane, the Golgi complex, and lysosomes, while in some cases mitochondrial reaction product remained intense. Matrix vesicles lost their enzymatic activity at the same time that matrix vesicle calcification commenced. It is proposed that this event allows matrix vesicles to calcify, since efflux of calcium would no longer occur.

Visualization of acidic compartments in cultured osteoclasts by use of an acidotrophic amine as a marker for low pH

Abstract. Using the acidotrophic amine 3-(2,4-dinitroanillino)-3´-amino-N-methyldipropylamine (DAMP) as a marker for low pH and immunofluorescence cytochemistry, we examined acidic compartments of osteoclasts cultured on cover glasses or bone slices, where they could resorb the bone surface, forming resorptive lacunae. DAMP-positive structures were seen as vesicular and tubular forms in the cytoplasm, indicating lysosomes and endosomes. Not only the osteoclastic cytoplasm but also the extracellular area around the ruffled border and resorptive lacunae were stained with DAMP, suggesting acidic regions. Immunofluorescence was localized predominantly on the substratum side of actively resorbing osteoclasts, whereas an evenly distributed staining pattern was seen in the nonactive cell. The most intensive reaction was seen at the advancing front of resorptive lacunae within the actively resorbing osteoclasts. The distribution pattern of DAMP seemed to be correlated with the osteoclastic activity, since osteoclasts exhibit alternating resorption and migration phases during the bone-remodeling cycle. In this culture system, the resorptive lacunae were left behind after the osteoclasts had completed resorption and migrated along the bone surface. These exposed resorptive lacunae were also stained with DAMP, which were presumably kept at an acidic pH. The effect of treatment with monensin, chloroquine, ammonium chloride, or nigericin was varied in terms of the immunoreactivity for DAMP, but no complete abolition of the staining was obtained. Weak bases such as chloroquine or ammonium chloride inhibited both intra- and extracellular immunoreactivity. Immunoreactivity for the vacuolar type of proton ATPase (V-ATPase) was demonstrable in the cytoplasm of the osteoclasts but was weakened by the addition of bafilomycin. Immunofluorescence of the resorptive lacunae was still retained even after the treatment with bafilomycin and acetazolamide. Besides, both bafilomycin and acetazolamide reversibly inhibited cellular acidity as judged by DAMP immunocytochemistry, which agrees with the fact that ostoeclastic acidification results from the action of vacuolar proton-pump ATPase coupled with carbonic anhydrase.

True enamel matrix of the newt, Triturus pyrrhogaster, contains no sulfated glycoconjugates

SummaryThe ultrastructural distibution and histochemical properties of sulfated glycoconjugates were investigated in the developing enamel of the adult newt, Triturus pyrrhogaster, by use of the high-iron diamine thiocarbohydrazide silver proteinate (HID-TCH-SP) staining and enzymatic digestion methods. Development and ultrastructure of the enamel were also studied. After deposition of the mantle dentin matrix to a certain thickness, the first enamel matrix, globular in shape, appeared in juxtaposition to the dental basement membrane and tended to be intermixed with the previously deposited dentin matrix. Subsequently, enamel matrix was deposited outside (ameloblastic side) of the dental basal lamina and formed a true enamel layer. Thus, developing enamel of the newt consists of two layers: (1) an inner layer made up of a dentin-enamel mixed matrix and (2) an outer layer composed of only true enamel matrix. HID-TCH-SP precipitates resulting from the abovementioned studies were found in the mixed matrix and were identified as chondroitin sulfates; in contrast, the true enamel matrix contained no sulfated glycoconjugates.

Heterogeneity of Distribution Pattern at the Electron Microscopic Level of Heparan Sulfate in Various Basement Membranes

Using the high-iron diamine thiocarbohydrazide silver proteinate (HID-TCH-SP) staining technique and enzymatic digestion, we investigated the ultrastructural distribution pattern of heparan sulfate side chains of heparan sulfate proteoglycan (HSPG) in various basement membranes (nerve, capillary, oral epithelial, muscle, and dental basement membranes). Four different distribution patterns of stain deposits were identified as heparan sulfate on the basis of enzymatic degradation by heparitinase. In some basement membranes associated with tooth germs and oral epithelium, HID-TCH-SP stain deposits were regularly located at both sides of the lamina densa, but few were observed in the lamina densa itself. In nerve, muscle, and capillary basement membranes, the stain deposits were localized at the external side of the lamina densa adjacent to the underlying connective tissue, but were not found in the laminae lucida and densa. In the internal basal lamina of junctional epithelium of gingiva, the stain deposits were detected mainly in the lamina lucida region. Finally, in some dental and oral epithelial basement membranes, the stain deposits were randomly distributed throughout both laminae lucida and densa. Thus, the present study demonstrated distinct differences in heparan sulfate distribution pattern among various basement membranes, suggesting their architectural heterogeneity.

The reaction of osteoclasts when releasing osteocytes from osteocytic lacunae in the bone during bone modeling

Osteocytes are released from the osteocytic lacunae when osteoclasts resorb the bone matrix during bone modeling and remodeling. It remains unknown how osteoclasts react when releasing osteocytes during bone modeling, and the fate of these released osteocytes is also unclear. Femoral mid-shafts of 2-day-old kittens were sectioned into serial 0.5 microm-thick semithin or 0.1 microm-thick ultrathin sections, and examined by light microscopy (LM) and transmission electron microscopy (TEM). The sections showed many osteoclasts at the endosteum but there were no osteoblasts. There were many half-released, fully released, half-exposed, and fully exposed osteocytes on the bone surfaces. Many cell-like structures were seen in the cell bodies of osteoclasts by LM, and some semithin sections were re-sectioned into ultrathin sections for re-observation by TEM. By TEM, these were determinated to be mononuclear cells. The serial ultrathin sections showed that the mononuclear cells appeared to be engulfed in osteoclasts on one section but that the cell was connected with the bone surface of the osteocytic lacuna on another section. These results show that the mononuclear cells in the osteoclasts were osteocytes. The present study suggests that osteoclasts engulf some osteocytes but do not engulf others when releasing osteocytes during bone modeling.

Differential Distribution of Posttranslationally Modified Microtubules in Osteoclasts

The differential distribution of microtubules in osteoclasts in culture was examined by using antibodies against acetylated, tyrosinated, or detyrosinated tubulins. Tyrosinated tubulin was found throughout the cytoplasmic microtubules in all cells examined. An expanding protrusion that contained tyrosinated tubulin but none of the detyrosinated or acetylated form was seen in the immature osteoclasts. Detyrosinated or acetylated tubulin was detectable in the peripheral cytoplasm of the mature osteoclasts displaying the loss of the expanding protrusion. Although most of the microtubules were derived from the centrosome, noncentrosomal microtubules were distributed in the expanding protrusion, which was predominantly positive for tyrosinated tubulin. By tracing single microtubules, the authors found that their growing ends were always rich in tyrosinated tubulin subunits. End binding protein 1 bound preferentially to the microtubule ends. Both acetylated and tyrosinated microtubules were shown to be closely associated with podosomes. Microtubules appeared to grow over or into the podosomes; in addition, the growing ends of single microtubules could be observed to target the podosomes. Moreover, a microtubule-associated histone deacetylase 6 was localized in the podosomes of the osteoclast. On the basis of these results, the authors conclude that posttranslational modifications of microtubules may correlate with characteristic changes in podosome dynamics in osteoclasts.

A cytoplasmic xylanase (XynX) of Aeromonas caviae ME-1 is released from the cytoplasm to the periplasm by osmotic downshock

Aeromonas caviae ME-1 is a multiple xylanase-producing gram-negative bacterium which was isolated from the gut contents of a wild silkworm, Samia cynthia pryeri. One of the xylanases produced by A. caviae ME-1, XynX (38 kDa, family 10 xylanase), hydrolyzes xylan to xylobiose and xylotetraose as final degradation products. Generally, xylanases are extracellular or cell surface enzymes. However, XynX is not exported to the extracellular fluid by A. caviae ME-1 and an Escherichia coli transformant harboring the xynX gene. In this study, we investigated the intracellular localization of XynX in A. caviae ME-1 and an E. coli transformant. XynX was found in the cytoplasm when the cells were grown under normal culture conditions. However, XynX was released from the cytoplasm to the periplasm during osmotic downshock. This release of XynX in the E. coli transformant was blocked in the presence of gadolinium chloride, which has been reported to be an inhibitor of bacterial mechanosensitive channels.

Ultrastructure of quick-frozen and freeze-substituted chick osteoclasts

For comparison with chemically fixed osteoclasts, we prepared chick osteoclasts by quick freezing followed by freeze‐substitution. In spite of technical difficulties this demonstrated that osteoclasts can be satisfactorily frozen in situ by the metal contact method. Ultrastructural differences were revealed between conventional fixation and quick freezing. Compared with conventional fixation, the quick freezing method appeared to improve preservation: (1) a discrete trilaminar plasma membrane and other intracellular membranes showed a smooth profile without undulation or rupture; (2) cytoskeletal components appeared to be clearer, straighter, and more numerous; (3) the interior of the ruffled finger contained interconnected lattice structures whereas highly organised microfilaments were seen in the clear zone; (4) well developed tubulovesicular structures (TVSs) that branched or anastomosed with each other were revealed in the cytoplasm; (5) the contents of intracellular membrane systems including the nuclear envelope, endoplasmic reticulum, and Golgi complex were stained to a various extent; (6) vesicles and vacuoles were much smaller, round and well‐defined with electron‐dense contents; (7) crystalline structures were seen at the extracellular channels of the ruffled border, in the lumen of TVSs, and in vesicles; (8) in some instances mitochondrial granules were visible; (9) within the resorptive lacuna, osteoclasts adhered to the degraded bone matrix without any intervening empty space.