Stephen L. Gluck

Initiation of Osteoclast Bone Resorption by Interstitial Collagenase

Osteoclasts form an acidic compartment at their attachment site in which bone demineralization and matrix degradation occur. Although both the cysteine proteinases and neutral collagenases participate in bone resorption, their roles have remained unclear. Here we show that interstitial collagenase has an essential role in initiating bone resorption, distinct from that of the cysteine proteinases. Treatment of osteoclasts with cysteine proteinase inhibitors did not affect the number of resorption lacunae (“pits”) formed on the surface of dentine slices, but it generated abnormal pits that were demineralized but filled with undegraded matrix. Treatment with metalloproteinase inhibitors did not alter the qualitative features of lacunae, but it greatly reduced the number of pits and surface area resorbed. Treatment of bone cells with an inhibitory anti-rat interstitial collagenase antiserum reduced bone resorption markedly. In the presence of collagenase inhibitors, resorption was restored by pretreatment of dentine slices with rat interstitial collagenase or by precoating the dentine slices with collagenase-derived gelatin peptides or heat-gelatinized collagen. Immunostaining revealed that interstitial collagenase is produced at high levels by stromal cells and osteoblasts adjacent to osteoclasts. These results indicate that interstitial collagenase can function as a “coupling factor,” allowing osteoblasts to initiate bone resorption by generating collagen fragments that activate osteoclasts.

The Amino-terminal Domain of the B Subunit of Vacuolar H+-ATPase Contains a Filamentous Actin Binding Site

Vacuolar H+-ATPase (V-ATPase) binds actin filaments with high affinity (K d = 55 nm; Lee, B. S., Gluck, S. L., and Holliday, L. S. (1999) J. Biol. Chem. 274, 29164–29171). We have proposed that this interaction is an important mechanism controlling transport of V-ATPase from the cytoplasm to the plasma membrane of osteoclasts. Here we show that both the B1 (kidney) and B2 (brain) isoforms of the B subunit of V-ATPase contain a microfilament binding site in their amino-terminal domain. In pelleting assays containing actin filaments and partially disrupted V-ATPase, B subunits were found in greater abundance in actin pellets than were other V-ATPase subunits, suggesting that the B subunit contained an F-actin binding site. In overlay assays, biotinylated actin filaments also bound to the B subunit. A fusion protein containing the amino-terminal half of B1 subunit bound actin filaments tightly, but fusion proteins containing the carboxyl-terminal half of B1 subunit, or the full-length E subunit, did not bind F-actin. Fusion proteins containing the amino-terminal 106 amino acids of the B1 isoform or the amino-terminal 112 amino acids of the B2 isoform bound filamentous actin withK d values of 130 and 190 nm, respectively, and approached saturation at 1 mol of fusion protein/mol of filamentous actin. The B1 and B2 amino-terminal fusion proteins competed with V-ATPase for binding to filamentous actin. In summary, binding sites for F-actin are present in the amino-terminal domains of both isoforms of the B subunit, and likely are responsible for the interaction between V-ATPase and actin filaments in vivo.

Interaction between Vacuolar H+-ATPase and Microfilaments during Osteoclast Activation

Vacuolar H+-ATPases (V-ATPases) are multisubunit enzymes that acidify compartments of the vacuolar system of all eukaryotic cells. In osteoclasts, the cells that degrade bone, V-ATPases, are recruited from intracellular membrane compartments to the ruffled membrane, a specialized domain of the plasma membrane, where they are maintained at high densities, serving to acidify the resorption bay at the osteoclast attachment site on bone (Blair, H. C., Teitelbaum, S. L., Ghiselli, R., and Gluck, S. L. (1989) Science 249, 855–857). Here, we describe a new mechanism involved in controlling the activity of the bone-resorptive cell. V-ATPase in osteoclasts cultured in vitro was found to form a detergent-insoluble complex with actin and myosin II through direct binding of V-ATPase to actin filaments. Plating bone marrow cells onto dentine slices, a physiologic stimulus that activates osteoclast resorption, produced a profound change in the association of the V-ATPase with actin, assayed by coimmunoprecipitation and immunocytochemical colocalization of actin filaments and V-ATPase in osteoclasts. Mouse marrow and bovine kidney V-ATPase bound rabbit muscle F-actin directly with a maximum stoichiometry of 1 mol of V-ATPase per 8 mol of F-actin and an apparent affinity of 0.05 μm. Electron microscopy of negatively stained samples confirmed the binding interaction. These findings link transport of V-ATPase to reorganization of the actin cytoskeleton during osteoclast activation.

The structure and biochemistry of the vacuolar H+ ATPase in proximal and distal urinary acidification

Vacuolar H+ ATPases participate in renal hydrogen ion secretion in both the proximal and distal nephron. These plasma membrane forms of the vacuolar H+ ATPase are regulated physiologically to maintain the acid-base balance of the organism. Proton transporting renal cells have requirements for constitutive acidification of intracellular compartments for normal endocytic and secretory functions. Recent experiments have begun to reveal how the kidney regulates these proton pumps independently. Vacuolar H+ ATPases are a family of structurally similar enzyme which differ in the composition of specific subunits. Cytosolic regulatory enzymes are present in renal cells which may affect vacuolar H+ ATPases in certain membrane compartments selectively. The vacuolar H+ ATPase in the plasma membrane of intercalated cells resides in a specialized proton-transporting apparatus that translocates the enzyme between an intracellular membrane pool and the plasma membrane in response to physiologic stimuli.

The Osteoclast as a Unicellular Proton-Transporting Epithelium

Osteoclasts dissolve bone mineral by the vectorial secretion of hydrogen ion at their osseous attachment site. To accomplish this, the osteoclast employs a vacuolar H+ ATPase that is polarized to the specialized proton-secreting plasma membrane domain, the ruffled border. Physiologically and biochemically, they resemble the specialized proton-secreting intercalated cells of the renal collecting duct, which also use a polarized vacuolar H+ ATPase to effect transepithelial hydrogen ion transport. Studies on the mechanism of hydrogen ion transport by the kidney may therefore provide insights into the control of acid secretion by the osteoclast.

DISTRIBUTION AND STRUCTURE OF THE VACUOLAR H+ ATPASE IN ENDOSOMES AND LYSOSOMES FROM LLC-PK1 CELLS

Vacuolar proton pumps acidify several intracellular membrane compartments in the endocytic pathway. We have examined the distribution of the vacuolar H+ ATPase in LLC-PK1 cells and the structure of the biosynthetically labeled enzyme in membrane fractions enriched for endosomes or lysosomes. LLC-PK1 cells were allowed to internalize cytochrome c-coated colloidal gold as a marker for endocytic compartments. Proton pumps were identified in these cells by staining the cells with a monoclonal antibody against the vacuolar pump detected with either immunogold or immunoperoxidase techniques. H+ ATPase labeling was seen on structures resembling endosomes and lysosomes, but not on Golgi or plasma membrane. To examine the structure of the H+ ATPase in these compartments, we labeled LLC-PK1 cells for 24 h with [35S]methionine and used a Percoll gradient to obtain fractions enriched for endosomes or lysosomes. H+ ATPase immunoprecipitated from both fractions with monoclonal anti-H+ ATPase antibodies had labeled polypeptides of 70, 56, and 31 kDa. On two-dimensional gels, a comparison of the H+ ATPase from the endosomal and lysosomal fractions revealed that the 70-, 56-, and 31-kDa subunits were similar in both fractions. The results show that the vacuolar H+ ATPase in these cells is distributed primarily in endosomes and lysosomes and that the structure of the enzyme is similar in both compartments.

An immunocytochemical study of H+ ATPase in kidney transplant rejection.

Kidney transplant rejection may be accompanied by defective urinary acidification. Its pathogenesis is unknown. There are shared histologic features between kidney transplant rejection and the distal renal tubular acidosis (RTA) of Sjogren syndrome, which led us to hypothesize that deficient collecting duct H+ adenosine triphosphatase (ATPase) expression--which is lacking in the RTA of Sjogren syndrome - may cause the RTA of kidney transplant rejection. Six kidney transplant recipients with biopsy evidence for rejection and two control subjects were studied physiologically and by immunohistochemistry. We found defective urinary acidification in all 6 kidney transplant patients. Ammonium excretion was diminished in relation to the degree of azotemia. There was an abnormal response to furosemide in all 6, suggesting distal tubular dysfunction. Distal H+ ATPase staining was reduced in relation to the degree of azotemia, although it was not totally absent even in the worst case. This was paralleled by the urinary PCO2 response. Both control subjects had good urine PCO2 and H+ ATPase staining and adequate urine pH response to furosemide. They had reduced urinary ammonium (NH4) concentrations in relation to modest azotemia. We conclude that kidney transplant rejection may be accompanied by defective urinary acidification, which is not primarily due to a lack of H+ ATPase. The RTA of kidney transplant rejection appears to result from defective ammonium excretion, generalized distal tubular malfunction, and--in severe cases--from a reduction in distal nephron H+ ATPase expression.

Properties of Kidney Plasma Membrane Vacuolar H + -ATPases: Proton Pumps Responsible for Bicarbonate Transport, Urinary Acidification, and Acid-Base Homeostasis

To maintain acid-base homeostasis, the kidney must reabsorb all of the 4500 millimoles of bicarbonate filtered by the glomerulus and regenerate the approximately 70 millimoles of bicarbonate consumed by daily metabolism.1, 2 The kidney accomplishes both bicarbonate reabsorption and regeneration by using hydrogen ion secretion,1, 2 and vacuolar H+-ATPases residing on the plasma membrane have an important or essential role in these processes in several nephron segments.3, 9 The plasma membrane vacuolar H+-ATPases differ from vacuolar H+-ATPases of intracellular organelles in several ways. The plasma membrane vacuolar H+-ATPase in hydrogen ion-transporting renal epithelial cells reside at high densities,10 and they have a polarized distribution11, 12 that allows for vectorial secretion of hydrogen ion. The plasma membrane vacuolar H+-ATPases of the nephron are also subject to physiologic regulation3, 8, 13 that allows the kidney to preserve acid-base balance.

Properties and Function of the Kidney Vacuolar H+ ATPase: a Versatile Proton Pump Responsible for Urinary Acidification

Approximately 30%–40% of hydrogen ion transport in the proximal tubule, and most or all of proton transport in the distal nephron, is generated by proton pumps belonging to the vacuolar class of H+WATPases. This ubiquitous type of proton pump is found in all eukaryotic cells, where it serves to acidify intracellular compartments, such as endosomes, lysosomes, and secretory vesicles, in the endocytic and secretory pathways. Certain renal tubular epithelial cells have amplified the expression of the enzyme, and are able to direct it in a polarized manner to specific domains of the plasma membrane, where it carries out transepithelial proton secretion. How amplified expression and polarized localization are achieved, how the enzyme is regulated, and the abnormalities in these processes that underlie disease processes, remain among the most important unanswered questions in this field.

Properties and regulation of the renal vacuolar H(+)-ATPase and H(+)-K(+)-ATPase.

Two proton-transporting ATPases participate in active proton transport in the nephron: the electrogenic vacuolar H(+)-ATPase and the electroneutral H(+)-K(+)-ATPase. The vacuolar H(+)-ATPase participates in proximal and distal hydrogen ion secretion related to acid-base homeostasis. The H(+)-K(+)-ATPase is located exclusively in the distal nephron, and its primary role may be in active potassium reabsorption. The properties, distribution, and regulation of these two enzymes are discussed.