Summary
Microinjection of adenine nucleotides and substrates into the cytoplasm of Amoeba proteus followed by EM examination has been used in an attempt to relate alterations in mitochondrial morphology with functional changes. Contracted mitochondria with dark matrix and wide cristae (Type I), and expanded mitochondria with light matrix and narrower cristae (Type II) coexist in normal active amoebae, but their numbers can be varied according to different cell activity states. Following injection of ATP, the mitochondria of the amoebae showed a time-dependent movement towards a predominately Type II form, whilst injections of ADP produced predominately the Type I form. Injection of succinate or deionised water, even in large amounts, had little effect on the numbers of Type I or Type II forms. The change induced by ATP was of long duration; that induced by ADP was influenced by both concentration injected and the cell's substrate levels. With 3 mM solutions of ADP the mitochondrial population was primarily of Type I organelles; higher ADP concentrations or the simultaneous injection of succinate, however, resulted in a switch with time to increased proportions of Type II mitochondria. The results extend the findings of previous in vivo and in vitro mitochondrial studies and are discussed in the light of these.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Buffa P, Pasquali-Ronchetti I, Barasa A, Godina G (1977) Biochemical lesions of respiratory enzymes and configurational changes in vivo. II. Early ultrastructural modifications correlated to the biochemical lesion induced by fluoroacetate. Cell Tissue Res 183:1–23
Commandon J, DeFonbrune P (1939) Greffe nucléaire totale, simple ou multiple chez une Amibe. CR Séanc Soc Biol 130:744–748
Flickinger CJ (1968) Mitochondrial polymorphism in Amoeba proteus. Protoplasma 66:139–151
Goldacre RJ, Lorch IJ (1950) Folding and unfolding of protein molecules in relation to cytoplasmic streaming, amoeboid movement and osmotic work. Nature 166:497–500
Griffin JL (1960) An improved mass culture method for the large free-living amoebae. Expl Cell Res 21:170–178
Hackenbrock CR (1966) Ultrastructural bases for mechanically linked activity in mitochondria. I. Reversible ultrastructural changes with change in metabolic steady state in isolated liver mitochondria. J Cell Biol 30:269–297
Hackenbrock CR (1972) States of activity and structure in mitochondrial membranes. Annals NY Acad Sci 195:492–505
Hackenbrock CR, Rehn TG, Weinbach EC, LeMasters JJ (1971) Oxidative phosphorylation and ultrastructural transformation in mitochondria in the intact ascites tumour cells. J Cell Biol 51:123–137
Innis MA, Beers TR, Craig SP (1976) Mitochondrial regulation in sea urchins. I. Mitochondrial ultrastructural transformation and changes in the ADP:ATP ratio at fertilisation. Expl Cell Res 98:47–56
Jeon KW, Lorch IJ (1968) A new simple method of micrurgy on living cells. Nature Lond 217:463
Koukl JF, Vorbeck ML, Martin AP (1977) Mitochondrial three-dimensional form in ascites tumor cells during changes in respiration. J Ultrastruct Res 61:158–165
Lang RDA, Bronk JR (1978) A study of rapid mitochondrial structural changes in vitro by spray-freeze etching. J Cell Biol 77:134–147
Manchester KL, Bullock G, Roetzscher VM (1973) Influence of methylxanthines and local anaesthetics on the metabolism of muscle and associated changes in mitochondrial morphology. Chem Biol Interactions 6:273–296
Mityushin VM, Kozyreva EV (1978) Some ultrastructural types of animal cell mitochondria and their energy production. Tsitologia 20:371–379 (In Russian)
Morisset C (1974) Variations de mitochondries dans des racines de Lycopersicum esculentum isolées, culturées “in vitro” et sonmises à divers traitments: anoxie prolongée, agent découplant plasmolysee. Cr hebd Seanc Acad Sci Paris Ser D279:1257–1260
Munn EA (1974) “The Structure of Mitochondria”. Acad Press Inc (London) Ltd
Muscatello U, Guarriera-Bobyleva V, Buffa P (1972) Configurational changes in isolated rat liver mitochondria as revealed by negative staining. II. Modifications caused by changes in respiratory states. J Ultrastruct Res 40:235–260
Ord MJ (1970) Mutations induced in Amoeba proteus by the carcinogen N-methyl-N-nitrosourethane. J Cell Sci 7:531–548
Ord MJ (1979) The effects of chemicals and radiations within the cell: An ultrastructural and micrurgical study using Amoeba proteus as a single cell model. Int Rev Cytol 61:229–281
Ord MJ, Al-Atia GR (1979) The intracellular effects of cadmium: an experimental study using Amoeba proteus as a single cell model. In: Webb M (ed) The chemistry, biochemistry and biology of cadmium. Elsevier, North Holland Biomedical Press, pp 141–173
Packer L, Wigglesworth JM, Fortes P, Pressman BC (1968) Expansion of the inner membrane compartment and its relationship to mitochondrial volume and ion transport. J Cell Biol 39:282–291
Rydzynski K, Cieciura L (1980) Modification of the configurational states of mitochondria of the choroid plexus ependyma in vivo. J Ultrastruct Res 70:118–127
Schmidt GE, Martin AP, Vorbeck ML (1977) Mitochondrial ultrastructure and volume during swelling. J Ultrastruct Res 60:52–62
Smith RA (1979) Growth temperature acclimation by Amoeba proteus: Effects on cytoplasmic organelle morphology. Protoplasma 101:23–35
Smith RA (1980) Mitochondrial alterations produced by misonidazole: A study using Amoeba proteus as a single-cell model. Brit J Cancer 41:305–308
Smith RA, Ord MJ (1979) Morphological alterations in the mitochondria of Amoeba proteus induced by uncoupling agents. J Cell Sci 37:217–229
Smith RA, Bell LGE, Ord MJ (1979) The effects of anaerobiosis and metabolic inhibitors on mitochondrial ultrastructure in Amoeba proteus. Protoplasma 99:275–288
Weakley BS (1976) Variations in mitochondrial size and ultrastructure during germ cell development. Cell Tissue Res 169:531–550
Weber N (1972) Ultrastructure studies of beef heat mitochondria. III. The inequality of gross morphological change and oxidative phosphorylation. J Cell Biol 55:457–470
Author information
Authors and Affiliations
Additional information
Member of the MRC Toxicology Unit, Carshalton, Surrey, SM5 4EF.
Rights and permissions
About this article
Cite this article
Ord, M.J., Smith, R.A. Correlation of mitochondrial form and function in vivo: Microinjection of substrate and nucleotides. Cell Tissue Res. 227, 129–137 (1982). https://doi.org/10.1007/BF00206336
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00206336