Immunocytological localization of an epitope-tagged plasma membrane proton pump (H(+)-ATPase) in phloem companion cells

In higher plants, the plasma membrane proton pump (H(+)-ATPase) is encoded by a surprisingly large multigene family whose members are expressed in different tissues. Using an 18-amino acid epitope tag derived from the animal oncogene c-Myc, we have performed immunocytolocalization measurements of the protein expressed by one member of this family, AHA3 (Arabidopsis H(+)-ATPase isoform 3). Immunofluorescence studies with tissue sections of transgenic plants have revealed that c-Myc-tagged AHA3 is restricted to the plasma membrane of phloem companion cells, whereas other AHA isoproteins are more widely distributed in the plasma membrane of other cell types. Electron microscopy with immunogold-labeled tissue sections suggests that there is a high concentration of proton pumps in the plasma membrane of companion cells but a much lower concentration in the plasma membrane of sieve elements. Due to plasmodesmata connecting the plasma membrane of these two adjacent cell types, it is likely that the proton motive force generated by the proton pump in companion cells can serve to power the uptake of sugar by proton-coupled symporters in either the companion cell or sieve element cell. The abundance of the proton pump in the plasma membrane of companion cells supports an apoplastic model for phloem loading in which the metabolic energy that drives sugar uptake is consumed by AHA3 at the companion cell plasma membrane. These experiments with a genetically altered integral plasma membrane protein demonstrate the utility of using a short c-Myc sequence as an epitope tag in Arabidopsis. Furthermore, our results demonstrate that, using genes encoding individual members of a gene family, it is possible to label plasma membrane proteins immunologically in specific, differentiated cell types of higher plants.

Immunolocalization of the 17 kDa vacuolar H(+)-ATPase subunit c in Heliothis virescens midgut and malpighian tubules with an anti-peptide antibody

The transmembrane sector of V-ATPases is involved in proton conduction across the membrane where a 15-17 kDa proteolipid forms a putative proton channel. An affinity-purified rabbit polyclonal antibody was developed to an antigenic and putatively extracellular region of a cloned 17 kDa proteolipid. In larval tissue sections, this antibody labeled the midgut goblet cell apical membrane in Heliothis virescens (Lepidoptera: Noctuidae) and the apical membrane in Malpighian tubules from H. virescens and Manduca sexta (Lepidoptera: Sphingidae). The antibody also recognized the 17 kDa protein in an immunoblot of H. virescens Malpighian tubule homogenate. Northern blot analysis revealed the presence of two transcript sizes in the midgut (1.9 and 1.2 kb) and Malpighian tubules (2.2 and 1.9 kb). Our results strongly support the hypothesis that the 17 kDa protein is a component of the V-ATPase, where it is thought to be the proton-conducting subunit. This polyclonal antibody may provide a powerful tool for V-ATPase regulation studies, while the use of the anti-peptide antibody approach may be helpful for the immunolocalization of other ductins.

Subunit E of the vacuolar H(+)-ATPase of Hordeum vulgare L.: cDNA cloning, expression and immunological analysis

A tonoplast protein of 31 kDa apparent molecular mass (TpP 31) was isolated from two-dimensional gels. Amino acid sequences were determined from LysC endoproteinase-peptide fragments. Using degenerate oligonucleotides, a corresponding cDNA clone of 1034 bp was isolated from a barley leaf cDNA library. It encodes for subunit E of the vacuolar H(+)-ATPase, the first one identified in plants so far. The open reading frame extends over 681 bp, encoding a gene product of 227 amino acids and a calculated molecular weight of 26,228 g mol-1. Northern and Western blot analysis indicates constitutive expression of subunit E in all plant organs with only small effects of salt stress. Localization of TpP 31 at the tonoplast was confirmed in fractions of purified vacuolar membrane obtained by free-flow electrophoresis. Immunoprecipitation of newly synthesized 35S-labelled membrane proteins with anti-TpP 31 gave two additional bands with apparent molecular masses of about 53 and 62 kDa. Gel filtration after mild solubilization showed co-purification of TpP 31 with the 55 kDa subunit of the H(+)-ATPase. Both results provide evidence beyond the sequence homology that TpP 31 is a structural component of the vacuolar H(+)-ATPase.

The presence of H+ and Na(+)-translocating ATPases in Methanobacterium thermoautotrophicum and their possible function under alkaline conditions

Two ATPases with different apparent molecular masses of approx. 500 kDa and 400 kDa were identified in the EDTA extract of the cell membranes of Methanobacterium thermoautotrophicum. Western blotting with polyclonal antiserum reactive with beta-subunit of mitochondrial ATPase from rat liver and yeast was used for further analysis of these ATPases. A strong crossreactivity with a single protein band with an apparent molecular weight of about 53 kDa (similar to beta-subunit of F-type ATPase from other sources) was found in protein extracts of whole cells of Methanobacterium thermoautotrophicum strains delta H and Marburg, as well as of Methanospirillum hungatei. This indicates the presence of F-type ATPase in methanogens. ATP synthesis driven by membrane potential which was generated by artificially-imposed delta pH in the presence of protonophorous uncoupler and sodium ions was stimulated by bafilomycin A1, an inhibitor of V- and A-type ATPases, as well as by harmaline, an inhibitor of Na+/H+ antiporter. These results indicate that cells of Methanobacterium thermoautotrophicum strain delta H contain the F-type ATP synthase which is Na(+)-translocating in addition to V- or A-type ATP synthase which is H(+)-translocating.

Localization of cyclic-AMP receptors with acidosomes in Dictyostelium discoideum

Earlier studies have shown that in Dictyostelium discoideum, a buoyant membrane fraction contained approximately 90% of the vacuolar proton pump (V-H(+)-ATPase) activity, leading to its designation acidosomes. It was proposed that acidosomes may be involved in endocytosis, specially in the acidification of endosomes. In this study we further investigated the putative function(s) of acidosomes. The findings suggest that acidosomes contain abundant receptors for cyclic AMP (CAR1) and that it may be the site for recycling of internalized receptors. Acidosomes also contain an abundance of Rab4 (Bush et al. 1994), a marker for early endosomes. By these criteria, we suggest that the acidosomes are analogous to early or recycling endosome present in mammalian cells. These findings suggest that the structure earlier defined biochemically, morphologically and immunologically as acidosomes may represent early and/or recycling endosomes in this protist.

Diagnoses of neuronal ceroid-lipofuscinosis by immunochemical methods

The neuronal ceroid-lipofuscinoses (NCL), also known as Batten disease, are a not uncommon group of disorders affecting infants, children, and young adults. The abnormal ultrastructural profiles seen in NCL are used for standard diagnosis; however, they can be missed, and are also found in other neurodegenerative conditions. Furthermore, there is an overlap between the types of inclusion profiles among the different forms of NCL. Therefore, a more specific and biochemically-based marker is necessary to confirm the diagnosis of NCL. Antibodies raised against the storage material from the ovine form of NCL (mitochondrial ATP synthase subunit c) were utilized to determine whether NCL could be distinguished from other metabolic-neurodegenerative disorders. By immunoblotting and immunohistochemistry, several brain samples of well-evaluated NCL cases confirmed increased accumulations in all NCL cases except in the brain of an infantile-onset NCL patient. The immunoblot studies of skin fibroblasts and brain were sensitive but not highly specific to NCL, due to the recognition of this material in normal controls as well as in other neurogenetic diseases. Immunocytochemistry of skin fibroblasts clearly distinguished LINCL and JNCL cases from controls, and with further refinement has the potential for becoming a diagnostic tool.

Palmitate oxidation in muscle mitochondria of patients with the juvenile form of neuronal ceroid-lipofuscinosis

The finding that the intracellular storage material in juvenile neuronal ceroid lipofuscinosis (JNCL) consists of the subunit c of ATP synthase prompted us to study energy conservation in JNCL patients. The activities of respiratory chain enzymes in isolated muscle mitochondria from 8 JNCL cases were normal, but oxidation of palmitate was reduced in 6 patients. The degree of reduction was related to the age of the patients. None of the patients had clinical symptoms or laboratory findings of impaired energy conservation, which suggest that the reduced palmitate oxidation was not associated with a major defect in fatty acid oxidation.

Immunocytochemical studies in the ceroid-lipofuscinoses (Batten disease) using antibodies to subunit c of mitochondrial ATP synthase

Immunocytochemistry, using antibodies against subunit c of mitochondrial ATP synthase, has been carried out in the ovine, canine, late infantile, and adult forms of ceroid-lipofuscinosis. Intensity of staining varied depending on the particular disease, species, fixation regime, and the antibody used. Differential staining of storage cytosomes in neurons of affected sheep and those in the late infantile patient suggested exposure of different epitopes. This was supported by the variable staining using two different antibodies in ovine, late infantile, and adult onset (Kufs) diseases. Immunostaining of muscle in the late infantile, and muscle and ear cartilage in affected sheep can assist diagnosis but positive results may depend on the age of the patient, at least in the latter species. In these tissues there was immunostaining of structures not identified by histochemical or fluorescence microscopy in addition to storage cytosomes that could be identified by these means. Poor or no immunostaining occurred with canine tissues. At the ultrastructural level, storage cytosomes but not other organelles stained with the immunogold method.

Role of subunit-9 of mitochondrial ATP synthase in Batten disease

The role of subunit-9 of mitochondrial ATP synthase in Batten disease was defined by characterizing the expression of genes encoding this protein in human tissues. Two genetically distinct neuronal ceroid-lipofuscinoses (NCL) comprise Batten disease: the late-infantile (LINCL) and juvenile (JNCL) types. We tested cell lines and tissues from both types of patients, along with normal controls. Differences in expression between diseased and normal samples were found for both mRNA and protein. Antibody staining of subunit-9 protein was detected in LINCL and JNCL tissues, and in 6 LINCL and 4 of 5 JNCL fibroblast lines. No immunoreactivity was seen in fibroblasts from obligate carriers, normal controls, and 6 other storage disease controls, with the exception of faint staining in Niemann-Pick, type C cells. There was an appreciable difference in staining pattern in both tissue sections and fibroblasts between LINCL and JNCL. Three subunit-9 transcripts (Hum1, Hum2, and Hum3) were specifically detected in NCL and normal human tissue from heart, liver, brain, muscle, and pancreas. Transcriptional regulation of subunit-9 genes was found to be altered in Batten disease. Pseudogenes related to each of the subunit-9 genes were isolated. Sequence analysis of cDNAs spanning the protein-coding regions of the Hum1, Hum2, and Hum3 genes showed conclusively that the primary defect(s) causing NCL are not mutations in the protein-coding regions of the 3 known subunit-9 genes.

Tissue and cellular distribution of subunit c of ATP synthase in Batten disease (neuronal ceroid-lipofuscinosis)

The major protein component of the storage bodies in the late infantile (LIB) and juvenile (JB) forms of Batten diseases is subunit c of ATP synthase (subunit c). Ultrastructurally the stored material may appear as curvilinear bodies, fingerprint profiles, or a mixture of both, dependent upon the form of Batten disease and the cell type. The mnd/mnd mouse, an animal model for Batten disease, also stores subunit c and has loosely stacked lamellae within the neurons of the brain and in other cells and tissues. Using a range of tissue samples, immunolocalization, using avidin-biotin techniques at the LM level and postembedding immunogold-labelling (5 nm) with silver enhancement at the EM level, were used to investigate specific subunit c immunoreactivity. Subunit c storage was displayed in a number of cells, including neurons, muscle cells, adipocytes, macrophages, endothelial and some epithelial cells, and exocrine and endocrine cells. By EM, subunit c was localized to all curvilinear-type storage bodies, but to nowhere else within the cell. It was not present over fingerprint profiles, the characteristic storage pattern of neurons within the JB gut, possibly due to steric factors. Preliminary studies in the mnd mouse showed subunit c immunoreactivity localized to storage profiles seen ultrastructurally in neurons of the brain, and liver and heart cells. We suggest that accumulation and distribution of subunit c within a variety of cell types, and its consistent absence in others, may be related to the particular cell type's longevity and its metabolic demand.

Batten disease and the ATP synthase subunit c turnover pathway: raising antibodies to subunit c

Analysis of storage bodies in the ceroid-lipofuscinoses (Batten disease) has demonstrated a high protein content suggestive of a proteinosis. Direct N-terminal sequencing has shown that subunit c of mitochondrial ATP synthase is specifically stored in the disease in sheep and cattle, and in the human late infantile and juvenile diseases, as well as in 3 breeds of dogs. No differences have been found between the stored subunit c and that in normal mitochondria. No other mitochondrial components are stored. Different proteins, sphingolipid activator proteins (SAPs or saposins) A and D, are stored in the infantile disease. Linkage studies have shown that different forms of ceroid-lipofuscinosis are coded for on different genes on different chromosomes. The genes for subunit c, its production, its insertion into mitochondria, and mitochondrial function are normal. This suggests that underlying the various forms of the disease is a family of lesions in the normal pathway of subunit c turnover, after its normal insertion into the ATP synthase complex. Antibodies to subunit c offer one way of mapping that pathway and detecting the sites of lesions. Specific antibodies have been raised against stored subunit c, using a liposomal adjuvant system which proved superior to classical adjuvants. These antibodies are also useful diagnostically, both in Western blotting and in immunocytochemistry.

Intimate association of H(+)-ATPase vesicles with mitochondria in the intercalated cell of the renal collecting duct

It is known that the intercalated cell of the renal collecting duct contains, in addition to abundant mitochondria, characteristic spherical or flat vesicles whose cytoplasmic surfaces were decorated with H(+)-ATPase studs. The intimate association of H(+)-ATPase vesicles with mitochondria was often observed. Here, the limiting membrane of the vesicle and the outer mitochondrial membrane were directly connected to each other by H(+)-ATPase studs. Namely, two membranes were bridged by these studs. This feature was especially evident in the case of flat vesicles. These findings indicated the close interplay between these two cell organellae.

Ultrastructural, immunocytochemical and stereological investigation of hepatocytes in a patient with the mutation of the ornithine transcarbamylase gene

We studied a male newborn suffering from deficiency of ornithine transcarbamylase (OTC) that is due to a G-to-A substitution in codon 269 of the OTC gene. This study intends to define the cell biological mechanisms in this naturally occurring OTC mutation which may explain the mild clinical course in spite of the very low residual enzyme activity. Using immunogold labeling of thawed thin frozen sections of liver from this patient and a control liver, we analyzed the quantitative distribution of several mitochondrial proteins in the cytosol and the mitochondria of hepatocytes. In addition, the absolute volumes and surface densities of mitochondria and peroxisomes were determined. Our results show that the absolute volume of mitochondria in the patient's hepatocytes was increased to 141% (P < 0.001) without any change in the surface density indicating an increased number of mitochondria. In the patient's hepatocytes the peroxisomes were increased in size but not in number. The concentration of OTC was elevated in the cytosol (P < 0.001) and to a lesser extent in mitochondria (P < 0.01) of the patient's hepatocytes thus indicating a doubling of OTC relative to control liver cells. The quantity of OTC in mitochondria was 63% higher in diseased liver cells. By conventional thin section electron microscopy, mitochondria-like structures with poorly defined cristae and an electron-dense matrix were observed in the cytoplasm of the diseased hepatocytes. By immunoelectron microscopy, they contained the cytochrome c oxidase II subunit as well as DNA but lacked OTC, carbamylphosphate synthetase, F1-ATPase beta subunit and catalase. Thus it appears that these structures represent defective and probably degenerating mitochondria. Our data indicate that the reduced enzyme activity of the mutant OTC is partly compensated by an increased amount of enzyme molecules in the cytosol as well as mitochondria combined with an increase in the biogenesis of mitochondria.

Ultrastructural and immunocytochemical evidence for the presence of polarised plasma membrane H(+)-ATPase in two specialised cell types in the chick embryo chorioallantoic membrane

The chick embryo, confined in the eggshell, has to dispose/buffer the acid generated by its metabolism, as well as to release calcium from the shell which is used for growth. To localise H(+)-ATPase, electron microscope and immunocytochemical studies were conducted on chorioallantoic membranes of 15-17 d chick embryos. Ultrastructural studies of the villus cavity (VC) cells in the chorionic epithelium demonstrated that their apical plasma membrane, juxtaposed with the shell membranes, contains microvilli as well as microplicae which possess 9-10 nm studs at a density of 16,700 particles/micron2, a characteristic feature of the polarised H(+)-ATPase pump. Immunocytochemical staining, using a monoclonal antibody to the 31 kDa subunit of H(+)-ATPase, confirmed the presence of large amounts of the vacuolar H(+)-ATPase in the VC shells with a distribution highly polarised towards the eggshell membranes. Immunoelectron-microscopic localisation studies using a rabbit antiserum to whole bovine H(+)-ATPase and immunogold technique, confirmed the localisation of H(+)-ATPase at the apical microvilli/microplicae as well as in the subapical vesicles. In the allantoic epithelium, the presence of mitochondria-rich (MR) cells was confirmed; it was shown that these cells extend through the full thickness of this epithelium. The MR cells also contained large numbers of 9-10 nm studs, typical of proton secreting cells, in their apical plasma membrane. This was confirmed by immunocytochemical staining which showed abundant localisation of H(+)-ATPase in these cells; this localisation was, however, diffuse rather than apical.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of plasma membrane V-ATPase activity by dissociation of peripheral subunits

The plasma membrane V-ATPase of Manduca sexta larval midgut is an electrogenic proton pump located in goblet cell apical membranes (GCAM); it energizes, by the voltage component of its proton motive force, an electrophoretic K+/nH+ antiport and thus K+ secretion (Wieczorek, H., Putzenlechner, M., Zeiske, W., and Klein, U. (1991) J. Biol Chem. 266, 15340-15347). Midgut transepithelial voltage, indicating net active K+ transport, was found to be more than 100 mV during intermoult stages but was abolished during moulting. Simultaneously, ATP hydrolysis and ATP-dependent proton transport in GCAM vesicles were found to be reduced to 10-15% of the intermoult level. Immunocytochemistry of midgut cryosections as well as SDS-polyacrylamide gel electrophoresis and immunoblots of GCAM demonstrated that loss of ATPase activity paralleled the disappearance of specific subunits. The subunits missing were those considered to compose the peripheral V1 sector, whereas the membrane integral V0 subunits remained in the GCAM of moulting larvae. The results provide, for the first time, evidence that a V-ATPase activity can be controlled in vivo by the loss of the peripheral V1 domain.

Perinatal maturation of rat kidney mitochondria

In the rat kidney, NaK-ATPase activity increased between days 19 and 20 of gestation (+50%) and between 1 and 24 h after birth (+20%), requiring an increased energy supply. In order to determine whether mitochondrial changes were involved, renal mitochondrial development was investigated from day 19 of gestation to 1 day after birth. Slot-blot analyses of mitochondrial-DNA/nuclear-DNA ratio and determination of citrate synthase activity showed a doubling in the mitochondrial pool between days 19 and 20 of gestation. In isolated mitochondria, oxygen consumption remained unchanged between days 19 and 20 of gestation, and then it was enhanced between days 20 and 21 of gestation (+70%) and between 1 and 24 h after birth (+50%). We also focused on one of the respiratory-chain complexes, ATP synthase, and measured its activity and content during the perinatal period. We demonstrated increases in both activity and content of ATP synthase between days 20 and 21 of gestation and between 1 and 24 h after birth, thus suggesting that changes in ATP synthase activity are ascribed to an increase in the mitochondrial density of ATP synthase complexes. Moreover, the mitochondrial ATP/ADP ratio only increased between 1 and 24 h (+90%), indicating a critical step in the renal respiratory-chain maturation at that time. We therefore conclude that the postnatal enhancement of renal mitochondrial oxidative capacity might depend on protein synthesis de novo and on changes in the adenine nucleotide concentrations.

Diseases of renal adenosine triphosphatase

Most renal transport is a primary or secondary result of the action of one of three membrane bound ion translocating ATPase pumps. The proximal tubule mechanisms for the reabsorption of salt, volume, organic compounds, phosphate, and most bicarbonate reabsorption depend upon the generation and maintenance of a low intracellular sodium concentration by the basolateral membrane Na-K-ATPase pump. The reabsorption of fluid and salt in the loop of Henle is similarly dependent on the energy provided by Na-K-ATPase activity. Some proximal tubule bicarbonate reabsorption and all distal nephron proton excretion is a product of one of two proton translocating ATPase pumps, either an electrogenic H-ATPase or an electroneutral H-K-ATPase. In this article, the authors review the biochemistry and physiology of pump activity and consider the pathophysiology of proximal and distal renal tubular acidosis, the Fanconi syndrome, and Bartter's syndrome as disorders of ATPase pump function.

Association and interactions of GTP-binding proteins with rat medullary H(+)-ATPase

Guanosine 5'-triphosphate (GTP)-binding proteins (G proteins) are expressed in a heterogeneous manner in the mammalian kidney. In particular, cells of the medullary collecting tubule demonstrate a complex pattern of G protein expression both between cell types and between the polarized surfaces of individual cells. Intercalated cells expressing the H(+)-ATPase are also prevalent in this nephron segment. To examine interactions between G proteins and the H(+)-ATPase, we performed immunocytochemical studies on perfusion-fixed sections of rat kidney using polyclonal anti-G protein antibodies and E11, a mouse monoclonal antibody to the 31-kDa subunit of the vacuolar H(+)-ATPase. G alpha s subunits were consistently not associated with cells containing the H(+)-ATPase in this nephron segment, whereas G alpha i-2, G alpha i-3, and G alpha q/11 were. Some intercalated cells that stained prominently for the proton pump in the apical membrane did not, however, stain for any G protein alpha-subunit. We prepared medullary membrane vesicles highly enriched for the H(+)-ATPase to examine possible functional interactions of G proteins with the H(+)-ATPase by the acridine orange method. These vesicles were also highly enriched for G protein subunits. Proton transport was significantly increased in the presence of guanosine 5'-O-(3-thiotriphosphate), and this held true in the absence of chloride. This excludes an effect on chloride conductance indirectly stimulating the H(+)-ATPase. Guanine nucleotides did not affect the proton leak of the vesicles. Thus some G proteins are associated with the H(+)-ATPase and can regulate its function; however, the particular G proteins involved remain to be identified.

Immunohistochemical localization of vacuolar H(+)-ATPase in osteoclasts of rat tibiae

The localization of vacuolar H(+)-atpASE (V-ATPase) in osteoclasts of rat tibiae was examined immunohistochemically using antibodies to 57 kD and 72 kD subunits of V-ATPase, with confocal laser scanning microscopy and transmission electron microscopy. The two antibodies showed similar immunoreactivities in osteoclasts. We distinguished three patterns of immunoreactivity in osteoclasts: The first pattern was that immunoreactivity was diffusely detected in cytoplasm of osteoclasts; The second one was that osteoclasts showed intense immunoreactivity in their regions contacting with bone surface; and the last was that little immunoreactivity was seen in osteoclasts. Post-embedding methods with protein A-gold complex revealed that the subunits of V-ATPase were localized not only on the membranes of the ruffled borders of osteoclasts, but also around the Golgi apparatus and accumulated tubular lysosomes. These findings suggest that: 1) immunoreactive patterns for V-ATPase in osteoclasts reflect the polarity and activity of osteoclasts; and 2) V-ATPase on ruffled borders may be transported through tubular lysosomes.

Purification of the synaptic vesicle-binding protein physophilin. Identification as 39-kDa subunit of the vacuolar H(+)-ATPase

Physophilin is a 36-kDa polypeptide originally identified in synaptic plasma membrane fractions, which binds to synaptic vesicles and has been implicated in vesicle docking and/or exocytosis during neurotransmitter release. Here we report on the purification, amino acid sequence analysis, and subcellular localization of physophilin. Physophilin was enriched from detergent extracts of crude synaptic plasma membranes by a combination of cation exchange and lentil-lectin chromatography. Sequence analysis of peptides generated after sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that physophilin is identical to the 39-kDa subunit (Ac39) of the vacuolar H(+)-ATPase. This was confirmed further by Western blot analysis with an Ac39-specific antiserum and by vesicle binding assays with recombinant Ac39 protein. Subcellular fractionation showed that Ac39 is enriched in synaptic vesicles, with lesser amounts being present in synaptic plasma membrane fractions. These results argue against a docking role of physophilin/Ac39 in synaptic vesicle exocytosis.

Analysis of successive endocytic compartments isolated from Dictyostelium discoideum by magnetic fractionation

A colloidal iron probe was fed to the amoeba Dictyostelium discoideum and chased for different intervals. Successive segments of the endocytic pathway were then isolated magnetically at high yield and purity. There were approx. 500 endocytic vacuoles per cell; their diameters increased from approx. 0.1-0.2 microns after 3 min of feeding to approx. 2 microns after 15 min of feeding and 60 min of chase. The wave-like progression of ingested probes along the endocytic pathway suggested that the transfer of cargo involved a maturation mechanism rather than the shuttling of cargo between stable compartments. The lifetime of primary pinosomes was calculated to be approx. 1 s. Multivesicular bodies were common in the 3 min fraction and abundant in 15 min lysosomes. alpha- and beta-adaptins of molecular masses of approx. 89 and 83 kDa were richer in the 3 min vesicles than in plasma membranes and later endocytic vacuoles. Acid phosphatase, intrinsic vacuole acidity, the vacuolar proton pump protein and pump activity were present at all endocytic stages but rose between the 3 min and 15 min vacuoles and declined thereafter. Bis(monoacyglycero)phosphate or BMP, a lipid characteristic of lysosomes, followed a similar time course; it contributed up to half of the total lipid in lysosomal vacuoles. We conclude that there is both continuity and differentiation along this endocytic pathway.

Expression of vacuolar H(+)-ATPase in osteoclasts and its role in resorption

By means of light- and electron-microscopic immunocytochemistry, we have demonstrated the expression of vacuolar H(+)-ATPase in mouse osteoclasts. In fully differentiated osteoclasts, intense immunolabeling was observed along the plasma membranes including those of ruffled borders and associated pale vesicles and vacuoles, whereas those of clear zones and basolateral cell surfaces were entirely free of immunoreaction. Specific expression of vacuolar H(+)-ATPase was also detected over polyribosomes and cisterns of the rough-surfaced endoplasmic reticulum. Multinucleated osteoclastic cells were suspended on dentine slices and cultured for 48 h in the presence or absence of either concanamycin B or bafilomycin A1, specific inhibitors of vacuolar H(+)-ATPase. Morphometric analysis of co-cultured dentine slices with backscattered electron microscopy revealed that both inhibitors strongly reduced the formation of resorption lacunae in a dose-dependent manner. These results suggest that vacuolar H(+)-ATPase is produced in the rough-surfaced endoplasmic reticulum, stored in the membrane vesicles, and transported into the ruffled border membranes of osteoclasts, and that this enzyme plays a key role in the creation of an acidic subosteoclastic microenvironment for the demineralization of co-cultured substrates.

A new member of a family of ATPases is essential for assembly of mitochondrial respiratory chain and ATP synthetase complexes in Saccharomyces cerevisiae

Respiration-defective pet mutants of Saccharomyces cerevisiae, assigned to complementation group G25, are grossly deficient in mitochondrial respiratory and ATPase complexes. This phenotype is usually found in strains impaired in mitochondrial protein synthesis. The G25 mutants, however, synthesize all of the proteins encoded by mitochondrial DNA. The mutants are also able to import and process cytoplasmically derived subunits of these enzymes. These results are most compatible with the idea that the gene defined by G25 mutants (RCA1) codes for a protein essential for the assembly of functional respiratory and ATPase complexes. The RCA1 gene has been cloned by complementation of an rca1 mutant with a yeast genomic library. The sequence of the encoded product shows Rca1 protein to be a new member of a recently described family of ATPases. The Rca1 protein is a mitochondrial membrane protein and is the third known member of this family implicated to function in the biogenesis of mitochondria. The primary structure of Rca1 protein indicates several distinct domains in addition to the common purine nucleotide binding region shared by all members of this protein family. One, located in the amino-terminal half, contains two hydrophobic stretches of sufficient length to span a membrane lipid bilayer.