Immunoenzyme localization of cathepsins in the Golgi region of rat hepatocytes and renal tubule cells

Localization of carboxyl proteinase (cathepsin D) and cysteine proteinases (cathepsins B, H, and L) in Golgi region was studied using an immunoenzyme technique. Rat livers and kidneys were used. The results obtained from the livers were similar to those from the kidneys. All cathepsins were detected in lysosomal compartments such as secondary lysosomes, multivesicular bodies (endosomes), and autophagosomes. Rough endoplasmic reticulum (rER), including nuclear envelope was focally stained. Most of Golgi cisternae were negative, but sometimes only one cisterna or the terminal portion of the cisterna were stained focally. Rarely, the trans Golgi network (TGN) was positive for the proteinases. Among numerous Golgi vesicles, only a few of them were stained. The positive vesicles were divided into two groups, one had a bristle coat and heavily stained, and other were smaller than 40 nm in diameter and weakly stained. The small vesicles seemed to bud from the ER and to fuse with the Golgi cisternae, while the large clathrin-coated vesicles seem to bud from the TGN. The results suggests that cathepsins are transported by vesicular system from the rER to lysosomes via Golgi apparatus. In addition, it is suggested that the small vesicles transport the proteinases from the ER to the Golgi cisternae and the large clathrin-coated vesicles from the Golgi cisternae to the lysosomes.     

Immunoenzyme localization of cathepsins in the Golgi region of rat hepatocytes and renal tubule cells

Summary Localization of carboxyl proteinase (cathepsin D) and cysteine proteinases (cathepsins B, H, and L) in Golgi region was studied using an immunoenzyme technique. Rat livers and kidneys were used. The results obtained from the livers were similar to those from the kidneys. All cathepsins were detected in lysosomal compartments such as secondary lysosomes, multivesicular bodies (endosomes), and autophagosomes. Rough endoplasmic reticulum (rER), including nuclear envelope was focally stained. Most of Golgi cisternae were negative, but sometimes only one cisterna or the terminal portion of the cisterna were stained focally. Rarely, the trans Golgi network (TGN) was positive for the proteinases. Among numerous Golgi vesicles, only a few of them were stained. The positive vesicles were divided into two groups, one had a bristle coat and heavily stained, and other were smaller than 40 nm in diameter and weakly stained. The small vesicles seemed to bud from the ER and to fuse with the Golgi cisternae, while the large clathrin-coated vesicles seem to bud from the TGN. The results suggests that cathepsins are transported by vesicular system from the rER to lysosomes via Golgi apparatus. In addition, it is suggested that the small vesicles transport the proteinases from the ER to the Golgi cisternae and the large clathrin-coated vesicles from the Golgi cisternae to the lysosomes.     

Vacuolar H+ Pumping ATPases in Luminal Acidic Organelles and Extracellular Compartments: Common Rotational Mechanism and Diverse Physiological Roles

Cytoplasmic organelles with an acidic luminal pH include vacuoles, coated vesicles, lysosomes, the Golgi apparatus, and synaptic vesicles. Acidic compartments are also known outside specialized cells such as osteoclasts. The unique acidic pH is formed by V-ATPase (Vacuolar type ATPase), other ion transporters, and the buffering action of proteins inside the organelles. V-ATPase hydrolyzes ATP and transports protons inside an organelle or extracellular compartment. We have summarized recent progress on mouse V-ATPases and their varying localizations together with their mechanism emphasizing similarities with F-type ATPases.     

Diverse and essential roles of mammalian vacuolar-type proton pump ATPase: toward the physiological understanding of inside acidic compartments

The vacuolar-type H(+)-ATPases (V-ATPase) are a family of multi-subunit ATP-dependent proton pumps involved in a wide variety of physiological processes. They are present in endomembrane organelles such as vacuoles, lysosomes, endosomes, the Golgi apparatus, chromaffin granules and coated vesicles, and acidify the luminal pH of these intracellular compartments. They also pump protons across the plasma membranes of specialized cells including osteoclasts and epithelial cells in kidneys and male genital tracts. Here, we briefly summarize our recent studies on the diverse and essential roles of mammalian V-ATPase.     

The mannose 6-phosphate receptor and the biogenesis of lysosomes

Localization of the 215 kd mannose 6-phosphate receptor (MPR) was studied in normal rat kidney cells. Low levels of receptor were detected in the trans Golgi network, Golgi stack, plasma membrane, and peripheral endosomes. The bulk of the receptor was localized to an acidic, reticular-vesicular structure adjacent to the Golgi complex. The structure also labeled with antibodies to lysosomal enzymes and a lysosomal membrane glycoprotein (lgp120). While lysosome-like, this structure is not a typical lysosome that is devoid of MPRs. The endocytic marker alpha 2 macroglobulin-gold entered the structure at 37 degrees C, but not at 20 degrees C. With prolonged chase, most of the marker was transported from the structure into lysosomes. We propose that the MPR/lgp-enriched structure is a specialized endosome (prelysosome) that serves as an intermediate compartment into which endocytic vesicles discharge their contents, and where lysosomal enzymes are released from the MPR and packaged along with newly synthesized lysosomal glycoproteins into lysosomes.     

Structure and Properties of the Clathrin-Coated Vesicle and Yeast Vacuolar V-ATPases

The V-ATPases are a family of ATP-dependent proton pumps responsible foracidification of intracellular compartments in eukaryotic cells. This reviewfocuses on the the V-ATPases from clathrin-coated vesicles and yeastvacuoles. The V-ATPase of clathrin-coated vesicles is a precursor to thatfound in endosomes and synaptic vesicles, which function in receptorrecycling, intracellular membrane traffic, and neurotransmitter uptake. Theyeast vacuolar ATPase functions to acidify the central vacuole and to drivevarious coupled transport processes across the vacuolar membrane. TheV-ATPases are composed of two functional domains. The V₁ domain isa 570-kDa peripheral complex composed of eight subunits of molecular weight70—14 kDa (subunits A—H) that is responsible for ATP hydrolysis.The V₀ domain is a 260-kDa integral complex composed of fivesubunits of molecular weight 100—17 kDa (subunits a, d, c, c8 and c9)that is responsible for proton translocation. Using chemical modification andsite-directed mutagenesis, we have begun to identify residues that play arole in ATP hydrolysis and proton transport by the V-ATPases. A centralquestion in the V-ATPase field is the mechanism by which cells regulatevacuolar acidification. Several mechanisms are described that may play a rolein controlling vacuolar acidification in vivo. One mechanisminvolves disulfide bond formation between cysteine residues located at thecatalytic nucleotide binding site on the 70-kDa A subunit, leading toreversible inhibition of V-ATPase activity. Other mechanisms includereversible assembly and dissociation of V₁ and V₀domains, changes in coupling efficiency of proton transport and ATPhydrolysis, and regulation of the activity of intracellular chloride channelsrequired for vacuolar acidification.     

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.     

VAMP-7 mediates vesicular transport from endosomes to lysosomes.

A more complete picture of the molecules that are critical for the organization of membrane compartments is beginning to emerge through the characterization of proteins in the vesicle-associated membrane protein (also called synaptobrevin) family of membrane trafficking proteins. To better understand the mechanisms of membrane trafficking within the endocytic pathway, we generated a series of monoclonal and polyclonal antibodies against the cytoplasmic domain of vesicle-associated membrane protein 7 (VAMP-7). The antibodies recognize a 25-kD membrane-associated protein in multiple tissues and cell lines. Immunohistochemical analysis reveals colocalization with a marker of late endosomes and lysosomes, lysosome-associated membrane protein 1 (LAMP-1), but not with other membrane markers, including p115 and transferrin receptor. Treatment with nocodozole or brefeldin A does not disrupt the colocalization of VAMP-7 and LAMP-1. Immunoelectron microscopy analysis shows that VAMP-7 is most concentrated in the trans-Golgi network region of the cell as well as late endosomes and transport vesicles that do not contain the mannose-6 phosphate receptor. In streptolysin- O-permeabilized cells, antibodies against VAMP-7 inhibit the breakdown of epidermal growth factor but not the recycling of transferrin. These data are consistent with a role for VAMP-7 in the vesicular transport of proteins from the early endosome to the lysosome.     

Antibodies to hepatic endosomes. Identification of two endosome antigens

Endosome fractions were prepared from rat liver homogenates, and antibodies were raised in rabbits against the integral membrane proteins. Immunofluorescent studies showed that these antibodies identified primarily intracellular structures in liver sections, isolated hepatocytes and HepG-2 cells. Immunoelectron microscopy using protein A-gold confirmed that endocytic multivesicular structures, especially those located at the biliary pole of the hepatocyte, were labeled. Biochemical analysis showed that approximately 12 endosome antigens were present. A major 43 kDa glycosylated antigen corresponded to the asialoglycoprotein receptor subunit. A further antigen identified in endosomes was a 115 kDa polypeptide pI 4.3 previously identified as a major calmodulin-binding protein. The antigens identified in rat liver endosomes were different to those previously shown by other studies to be present in the Golgi apparatus and lysosomes.     

Consequences of loss of Vph1 protein-containing vacuolar ATPases (V-ATPases) for overall cellular pH homeostasis

In yeast cells, subunit a of the vacuolar proton pump (V-ATPase) is encoded by two organelle-specific isoforms, VPH1 and STV1. V-ATPases containing Vph1 and Stv1 localize predominantly to the vacuole and the Golgi apparatus/endosomes, respectively. Ratiometric measurements of vacuolar pH confirm that loss of STV1 has little effect on vacuolar pH. Loss of VPH1 results in vacuolar alkalinization that is even more rapid and pronounced than in vma mutants, which lack all V-ATPase activity. Cytosolic pH responses to glucose addition in the vph1Δ mutant are similar to those in vma mutants. The extended cytosolic acidification in these mutants arises from reduced activity of the plasma membrane proton pump, Pma1p. Pma1p is mislocalized in vma mutants but remains at the plasma membrane in both vph1Δ and stv1Δ mutants, suggesting multiple mechanisms for limiting Pma1 activity when organelle acidification is compromised. pH measurements in early prevacuolar compartments via a pHluorin fusion to the Golgi protein Gef1 demonstrate that pH responses of these compartments parallel cytosolic pH changes. Surprisingly, these compartments remain acidic even in the absence of V-ATPase function, possibly as a result of cytosolic acidification. These results emphasize that loss of a single subunit isoform may have effects far beyond the organelle where it resides.     

Immunocytochemical localization of acid phosphatase in rat liver

Localization of acid phosphatase (ACPase) in rat liver was investigated by immunocytochemical techniques. Rat liver was fixed by perfusion and cut into thick tissue slices, which were embedded in Epon or Lowicryl K4M. For light microscopy (LM), semithin Epon sections were stained for the enzyme ACPase by an indirect immunoenzyme technique. For electron microscopy (EM), ultra-thin Lowicryl K4M sections were stained by a protein A-gold technique. By means of LM, granular reaction deposits were observed in hepatocytes and sinus-lining cells. Stained granules were present in the juxtanuclear cytoplasm, but they did not correspond to a typical staining pattern for the Golgi complex. EM revealed that gold particles indicating ACPase antigens were present on lysosomes and on some vesicles locating in the trans Golgi region. Endosomelike vesicles were strongly positive for the labeling. Golgi cisterna were mostly negative, but weak signals were noted in dilated sacules. The plasma membranes on the sinusoidal and bile canalicular sides were labeled by a few gold particles. The results indicate that ACPase is present in endosomes and in a restricted area of plasma membrane, as well as in the lysosomal system.     

The Peripheral Vesicles of Trophozoites of the Primitive ProtozoanGiardia lambliaMay Correspond to Early and Late Endosomes and to Lysosomes

Giardia lamblia,a primitive eukaryotic cell, lacks organelles such as mitochondria, peroxisomes, and a typical Golgi complex and presents a system of vesicles located below the plasma membrane. We used fluorescence and electron microscopy to better characterize the peripheral vesicles. Incubation of living cells with acridine orange showed that the peripheral vesicles correspond to an acidic compartment. Incubation with lucifer yellow, and with horseradish peroxidase, showed labeling of the peripheral vesicles even after several hours. Acid phosphatase was localized in the endoplasmic reticulum and in most of the peripheral vesicles. On the other hand, glucose 6-phosphatase, an endoplasmic reticulum marker, was observed in the endoplasmic reticulum cisternae and in some peripheral vesicles. A similar labeling pattern was observed using the zinc iodide technique, which reveals SH-containing proteins. Three-dimensional reconstruction and electron microscopy tomography of cells stained for acid phosphatase and glucose-6-phosphatase revealed the connection between some vesicles and profiles of the endoplasmic reticulum. Taken together, our observations suggest that trophozoites ofG. lambliapresent an endosomal–lysosomal system concentrated in a single system, the peripheral vesicles, which may represent an ancient organellar system that later on subdivided into compartments such as early and late endosomes and lysosomes.     

Syntaxin 6 functions in trans-Golgi network vesicle trafficking.

The specific transfer of vesicles between organelles is critical in generating and maintaining the organization of membrane compartments within cells. Syntaxin 6 is a recently discovered member of the syntaxin family, whose constituents are required components of several vesicle trafficking pathways. To better understand the function of syntaxin 6, we generated a panel of monoclonal antibodies that specifically recognize different epitopes of the protein. Immunoelectron microscopy shows syntaxin 6 primarily on the trans-Golgi network (TGN), where is partially colocalizes with the TGN adapter protein AP-1 on clathrin-coated membranes. Additional label is present on small vesicles in the vicinity of endosome-like structures. Immunoprecipitation of syntaxin 6 revealed that it is present in a complex or complexes with alpha-soluble NSF attachment protein, vesicle-associated membrane protein 2, or cellubrevin and a mammalian homologue of VPS45, which is a member of the sec1 family implicated in Golgi to prevacuolar compartment trafficking in yeast. We show that mammalian VPS45 is found in multiple tissues, is partially membrane associated, and is enriched in the Golgi region. Converging lines of evidence suggest that syntaxin 6 mediates a TGN trafficking event, perhaps targeting to endosomes in mammalian cells.     

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 LLCPK₁ 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.     

Functional symmetry of endomembranes

In higher eukaryotic cells pleiomorphic compartments composed of vacuoles, tubules and vesicles move from the endoplasmic reticulum (ER) and the plasma membrane to the cell center, operating in early biosynthetic trafficking and endocytosis, respectively. Besides transporting cargo to the Golgi apparatus and lysosomes, a major task of these compartments is to promote extensive membrane recycling. The endocytic membrane system is traditionally divided into early (sorting) endosomes, late endosomes and the endocytic recycling compartment (ERC). Recent studies on the intermediate compartment (IC) between the ER and the Golgi apparatus suggest that it also consists of peripheral ("early") and centralized ("late") structures, as well as a third component, designated here as the biosynthetic recycling compartment (BRC). We propose that the ERC and the BRC exist as long-lived "mirror compartments" at the cell center that also share the ability to expand and become mobilized during cell activation. These considerations emphasize the functional symmetry of endomembrane compartments, which provides a basis for the membrane rearrangements taking place during cell division, polarization, and differentiation.     

Mutant Huntingtin Impairs Post-Golgi Trafficking to Lysosomes by Delocalizing Optineurin/Rab8 Complex from the Golgi Apparatus

Huntingtin regulates post-Golgi trafficking of secreted proteins. Here, we studied the mechanism by which mutant huntingtin impairs this process. Colocalization studies and Western blot analysis of isolated Golgi membranes showed a reduction of huntingtin in the Golgi apparatus of cells expressing mutant huntingtin. These findings correlated with a decrease in the levels of optineurin and Rab8 in the Golgi apparatus that can be reverted by overexpression of full-length wild-type huntingtin. In addition, immunoprecipitation studies showed reduced interaction between mutant huntingtin and optineurin/Rab8. Cells expressing mutant huntingtin produced both an accumulation of clathrin adaptor complex 1 at the Golgi and an increase of clathrin-coated vesicles in the vicinity of Golgi cisternae as revealed by electron microscopy. Furthermore, inverse fluorescence recovery after photobleaching analysis for lysosomal-associated membrane protein-1 and mannose-6-phosphate receptor showed that the optineurin/Rab8-dependent post-Golgi trafficking to lysosomes was impaired in cells expressing mutant huntingtin or reducing huntingtin levels by small interfering RNA. Accordingly, these cells showed a lower content of cathepsin D in lysosomes, which led to an overall reduction of lysosomal activity. Together, our results indicate that mutant huntingtin perturbs post-Golgi trafficking to lysosomal compartments by delocalizing the optineurin/Rab8 complex, which, in turn, affects the lysosomal function.     

ATG16L1 meets ATG9 in recycling endosomes

Autophagosomes are formed by double-membraned structures, which engulf portions of cytoplasm. Autophagosomes ultimately fuse with lysosomes, where their contents are degraded. The origin of the autophagosome membrane may involve different sources, such as mitochondria, Golgi, endoplasmic reticulum, plasma membrane, and recycling endosomes. We recently observed that ATG9 localizes on the plasma membrane in clathrin-coated structures and is internalized following a classical endocytic pathway through early and then recycling endosomes. By contrast, ATG16L1 is also internalized by clathrin-mediated endocytosis but via different clathrin-coated pits, and appears to follow a different route to the recycling endosomes. The R-SNARE VAMP3 mediates the coalescence of the 2 different pools of vesicles (containing ATG16L1 or ATG9) in recycling endosomes. The heterotypic fusion between ATG16L1- and ATG9-containing vesicles strongly correlates with subsequent autophagosome formation. Thus, ATG9 and ATG16L1 both traffic from the plasma membrane to autophagic precursor structures and provide 2 routes from the plasma membrane to autophagosomes.     

Lysosome associated membrane protein 1 (Lamp1) traffics directly from the TGN to early endosomes

The precise trafficking routes followed by newly synthesized lysosomal membrane proteins after exit from the Golgi are unclear. To study these events we created a novel chimera (YAL) having a lumenal domain comprising two tyrosine sulfation motifs fused to avidin, and the transmembrane and cytoplasmic domains of lysosome associated membrane protein 1 (Lamp1). The newly synthesized protein rapidly transited from the trans- Golgi Network (TGN) to lysosomes (t(1/2) approximately 30 min after a lag of 15-20 min). However, labeled chimera was captured by biotinylated probes endocytosed for only 5 min, indicating that the initial site of entry into the endocytic pathway was early endosomes. Capture required export of YAL from the TGN, and endocytosis of the biotinylated reagent, and was essentially quantitative within 2 h of chase, suggesting that all molecules were following an identical route. There was no evidence of YAL trafficking via the cell surface. Fusion of TGN-derived vesicles with 5 min endosomes could be recapitulated in vitro, but neither late endosomes nor lysosomes could serve as acceptor compartments. This suggests that contrary to previous conclusions, most if not all newly synthesized Lamp1 traffics from the TGN to early endosomes prior to delivery to late endosomes and lysosomes.     

From lysosomes to the plasma membrane: localization of vacuolar-type H+ -ATPase with the a3 isoform during osteoclast differentiation

Osteoclasts generate a massive acid flux to mobilize bone calcium. Local extracellular acidification is carried out by vacuolar type H+-ATPase (V-ATPase) localized in the plasma membrane. We have shown that a3, one of the four subunit a isoforms (a1, a2, a3, and a4), is a component of the plasma membrane V-ATPase (Toyomura, T., Oka, T., Yamaguchi, C., Wada, Y., and Futai, M. (2000) J. Biol. Chem. 275, 8760-8765). To establish the unique localization of V-ATPase, we have used a murine macrophage cell line, RAW 264.7, that can differentiate into multinuclear osteoclast-like cells on stimulation with RANKL (receptor activator of nuclear factor kappaB ligand). The V-ATPase with the a3 isoform was localized to late endosomes and lysosomes, whereas those with the a1 and a2 isoforms were localized to organelles other than lysosomes. After stimulation, the V-ATPase with the a3 isoform was immunochemically colocalized with lysosome marker lamp2 and was detected in acidic organelles. These organelles were also colocalized with microtubules, and the signals of lamp2 and a3 were dispersed by nocodazole, a microtubule depolymerizer. In RAW-derived osteoclasts cultured on mouse skull pieces, the a3 isoform was transported to the plasma membrane facing the bone and accumulated inside podosome rings. These findings indicate that V-ATPases with the a3 isoform localized in late endosomes/lysosomes are transported to the cell periphery during differentiation and finally assembled into the plasma membrane of mature osteoclasts.     

Commentary: ATG16L1 meets ATG9 in recycling endosomes: Additional roles for the plasma membrane and endocytosis in autophagosome biogenesis

Autophagosomes are formed by double-membraned structures, which engulf portions of cytoplasm. Autophagosomes ultimately fuse with lysosomes, where their contents are degraded. The origin of the autophagosome membrane may involve different sources, such as mitochondria, Golgi, endoplasmic reticulum, plasma membrane, and recycling endosomes. We recently observed that ATG9 localizes on the plasma membrane in clathrin-coated structures and is internalized following a classical endocytic pathway through early and then recycling endosomes. By contrast, ATG16L1 is also internalized by clathrin-mediated endocytosis but via different clathrin-coated pits, and appears to follow a different route to the recycling endosomes. The R-SNARE VAMP3 mediates the coalescence of the 2 different pools of vesicles (containing ATG16L1 or ATG9) in recycling endosomes. The heterotypic fusion between ATG16L1- and ATG9-containing vesicles strongly correlates with subsequent autophagosome formation. Thus, ATG9 and ATG16L1 both traffic from the plasma membrane to autophagic precursor structures and provide 2 routes from the plasma membrane to autophagosomes.