Summary
Although it is generally accepted that phagosome acidification is induced through the activity of a vacuolar proton pump (V-ATPase) present on the phagosome membrane, exactly how these pumps are delivered to the phagosomes is not well understood. To study this question inParamecium, it was necessary to first show that an authentic V-ATPase was present on their phagosomal membranes. Three antibodies raised against V-ATPases or their subunits were each found to label one or two large digestive vacuoles (DVs) inParamecium multimicronucleatum when immunofluorescence microscopy was used. Using horseradish peroxidase immunocytochemistry to increase sensitivity, about 10 DVs were shown to contain a V-ATPase. In high magnification images and cryoultramicrotomy these proton pumps were found to be located on the acidosomes, suggesting the vacuolar proton pumps on the DVs originate from the acidosomes. The authenticity of the V-ATPase was further confirmed by its sensitivity to cold temperature and to the V-ATPase specific inhibitor, concanamycin B, which at 10 nM doubled the t1/2 for vacuole acidification. Thus, we conclude that (1) acidosomes and some DVs ofParamecium have a bona-fide concanamycin B-sensitive and cold-sensitive V-ATPase, (2) the V-ATPase is delivered to the young DVs during acidosome fusion, and (3) the V-ATPase is involved in vacuole acidification. Finally, we have now determined thatParamecium has two immunologically related V-ATPases that are involved in two very different functions, (1) the acidification of phagosomes and (2) fluid segregation in the contractile vacuole complexes.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- BS-FITC:
-
bovine serum albumin-fluorescein isothiocyanate
- CVC:
-
contractile vacuole complex
- DV-I to DV-IV:
-
digestive vacuole stages 1 to 4
- HRP:
-
horseradish peroxidase
- V-ATPase:
-
vacuolar proton pump
References
Allen RD (1974) Food vacuole membrane growth with microtubule-associated membrane transport inParamecium. J Cell Biol 63: 904–922
—, Fok AK (1980) Membrane recycling and endocytosis inParamecium confirmed by horseradish peroxidase pulse-chase studies. J Cell Sci 45: 131–145
— — (1983a) Phagosome fusion vesicles ofParamecium. I. Thinsection morphology. Eur J Cell Biol 29: 150–158
— — (1983b) Phagosome fusion vesicles ofParamecium. II. Freeze-fracture evidence for membrane replacement. Eur J Cell Biol 29: 159–165
— — (1983c) Nonlysosomal vesicles (acidosomes) are involved in phagosome acidification inParamecium. J Cell Biol 97: 566–570
— — (1984a) Retrieval of lysosomal membrane and acid phosphatase from phagolysosomes ofParamecium caudaium. J Cell Biol 99: 1955–1959
— — (1984b) Stages of digestive vacuoles inParamecium: membrane surface difference and location. Eur J Cell Biol 35: 149–155
—, Staehelin LA (1981) Digestive system membranes: freezefracture evidence for differentiation and flow inParamecium, J Cell Biol 89: 9–20
—, Wolf RW (1974) The cytoproct ofParamecium caudatum: structure and function, microtubules, and fate of food vacuole membranes. J Cell Sci 14: 611–631
—, Ueno MS, Pollard LW, Fok AK (1990) Monoclonal antibody study of the decorated spongiome of contractile vacuole complexes ofParamecium. J Cell Sci 96: 469–475
—, Bala NP, Ali RF, Nishida DM, Aihara MS, Ishida M, Fok AK (1995) Rapid bulk replacement of acceptor membrane by donor membrane during phagosome to phagoacidosome transformation inParamecium. J Cell Sci 108: 1263–1274
Choi I, Mego JL (1988) Purification ofPlasmodium flaciparum digestive vacuoles and partial characterization of the vacular membrane ATPase. Mol Biochem Parasitol 31: 71–78
Fok AK, Allen RD (1979) AxenicParamecium caudatum. I. Mass culture and structure. J Protozool 26: 463–470
—, Lee Y, Allen RD (1982) The correlation of digestive vacuole pH and size with the digestive cycle inParamecium caudatum. J Protozool 29: 409–414
—, Muraoka JH, Allen RD (1984) Acid phosphatase in the digestive vacuoles and lysosomes ofParamecium caudatum: a timed study. J Protozool 31: 216–220
—, Ueno MS, Azada EA (1985) Rapid and sensitive assays for phagosomal acidification inParamecium andTetrahymena. Eur J Cell Biol 38: 306–311
—, Aihara MS, Ishida M, Nolta KV, Steck TL, Allen RD (1995) The pegs on the decorated tubules of the contractile vacuole complex ofParamecium are proton pumps. J Cell Sci 108: 3163–3170
Forgac M (1989) Structure and function of vacuolar class of ATP- driven proton pumps. Physiol Rev 69: 765–796
Geisow MJ, D'Arcy Hart P, Young MR (1981) Temporal changes of lysosome and phagosome pH during phagolysosome formation in macrophages: studies by fluorescence spectroscopy. J Cell Biol 89: 645–652
Graham RC Jr, Karnovsky MJ (1966) The early stages of absorption of injected horseradish peroxidase in the proximal tubules of mouse kidney: ultrastructural cytochemistry by a new technique. J Histochem Cytochem 14: 291–302
Heiple JM, Taylor DL (1982) pH changes in pinosomes and phagosomes in the ameba,Chaos carolinensis. J Cell Biol 94: 143–149
Ishida M, Fok AK, Aihara MS, Allen RD (1996) Hyperosmotic stress leads to reversible dissociation of the proton pump-bearing tubules from the contractile vacuole complex inParamecium. J Cell Sci 109: 229–237
Mast SO (1947) The food-vacuole inParamecium. Biol Bull 92: 31–72
McNeil PL, Tanasugarn L, Meigs JB, Taylor DL (1983) Acidification of phagosomes is initiated before lysosomal enzyme activity is detected. J Cell Biol 97: 692–702
Mellman I, Fuchs R, Helenius A (1986) Acidification of the endocytic and exocytic pathways. Annu Rev Biochem 55: 663–700
Metchnikoff E (1893) Lectures on the comparative pathology of inflammation. Kegan Paul Trench Truber & Co, London
Müller M, Törö I (1962) Studies on the feeding and digestion in protozoa. III. Acid phosphatase activity in food vacuoles ofParamecium multimicronucleatum. J Protozool 9: 98–102
—, Röhlich P, Toth J, Törö I (1963) Fine structure and enzyme activity of protozoan food vacuoles. In: de Reuck AVS, Cameron MP (eds) Ciba Foundation Symposium on Lysosomes. Churchill, London, pp 201–216
Nelson N (1992) The vacuolar H+-ATPase — one of the most fundamental ion pumps in nature. J Exp Biol 172: 19–27
Nolta KV, Padh H, Steck TL (1993) An immunocytochemical analysis of the vacuolar proton pump inDictyostelium discoideum. J Cell Sci 105: 849–859
Padh H, Lavasa M, Steck TL (1989) Characterization of a vacuolar proton ATPase inDictyostelium discoideum. Biochem Biophys Acta 982: 271–278
Sturgill-Koszycki S, Schlesinger PH, Chakraborty P, Haddix PL, Collins HL, Fok AK, Allen RD, Gluck SL, Heuser J, Russell DG (1994) Lack of acidification inMycobacterium phagosomes produced by exclusion of the vesicular proton-ATPase. Science 263: 678–681
Sumner J-P, Dow JAT, Earley FGP, Klein U, Jager D, Wieczorek H (1995) Regulation of plasma membrane V-ATPase activity by dissociation of peripheral subunits. J Biol Chem 270: 5649–5653
Uchida E, Ohsumi Y, Anraku Y (1985) Purification and properties of a H+ translocating, Mg2+-dependent-adenosine triphosphatase from vacuolar membranes ofSaccharomyces cerevisiae. J Biol Chem 260: 1090–1095
Wang Y, Sze H (1985) Similarities and differences between the tonoplast-type and the mitochondrial H+ ATPases of oat root. J Biol Chem 260: 10434–10443
Woo J-T, Shinohara C, Sakai K, Hasumi K, Endo A (1992) Inhibition of the acidification of endosomes and lysosomes by the antibiotic concanamycin B in macrophage J774. Eur J Biochem 207: 383–389
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Ishida, M., Aihara, M.S., Allen, R.D. et al. Acidification of the young phagosomes ofParamecium is mediated by proton pumps derived from the acidosomes. Protoplasma 196, 12–20 (1997). https://doi.org/10.1007/BF01281054
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF01281054