Crystalline mitochondrial inclusion bodies isolated from creatine depleted rat soleus muscle.

Rats were fed a 2% guanidino propionic acid diet for up to 18 weeks to induce cellular creatine depletion by inhibition of creatine uptake by this creatine analogue. Ultrastructural analysis of creatine depleted tissues showed that mitochondrial intermembrane inclusion bodies appeared in all skeletal muscles analysed, after 11 weeks of feeding. Heart had relatively few even after 18 weeks of analogue feeding and none were evident in kidney, brain or liver. These structures were strongly immuno-positive for sarcomeric mitochondrial creatine kinase and upon removal from mitochondria, the inclusion bodies were shown to diffract to a resolution of 2.5 nm. Two-dimensional image analysis and three-dimensional reconstruction revealed arrays of creatine kinase octamers with additional components between the octameric structures. The same mitochondria had a 3-fold higher extractable specific creatine kinase activity than controls. Molecular mass gel filtration of inclusion body containing mitochondrial extracts from analogue fed rat solei revealed mitochondrial creatine kinase eluting as an aggregate of an apparent molecular mass > or = 2,000 kDa. Mitochondrial creatine kinase of control soleus mitochondrial extract eluted as an octamer, with a molecular mass of 340 kDa. Respiration measurements of control solei mitochondria displayed creatine mediated stimulation of oxidative phosphorylation that was absent in analogue-fed rat solei mitochondria. The latter also had 19% and 14% slower rates of state 4 and maximal state 3 respiration, respectively, than control mitochondria. These results indicate that mitochondrial creatine kinase co-crystallises with another component within the inter membrane space of select mitochondria in creatine depleted skeletal muscle, and is inactive in situ.

[1]  T. Wallimann,et al.  Membrane-binding and lipid vesicle cross-linking kinetics of the mitochondrial creatine kinase octamer. , 1996, Biochemistry.

[2]  D. Hood,et al.  Protein Import into Subsarcolemmal and Intermyofibrillar Skeletal Muscle Mitochondria , 1996, The Journal of Biological Chemistry.

[3]  D. Johns The other human genome: Mitochondrial DNA and disease , 1996, Nature Medicine.

[4]  T. Wallimann,et al.  Differential effects of creatine depletion on the regulation of enzyme activities and on creatine-stimulated mitochondrial respiration in skeletal muscle, heart, and brain. , 1996, Biochimica et biophysica acta.

[5]  G. Radda,et al.  The utilisation of creatine and its analogues by cytosolic and mitochondrial creatine kinase. , 1996, Biochimica et biophysica acta.

[6]  Theo Wallimann,et al.  Structure of mitochondrial creatine kinase , 1996, Nature.

[7]  P. Kaldis,et al.  In vitro complex formation between the octamer of mitochondrial creatine kinase and porin. , 1994, The Journal of biological chemistry.

[8]  L. Hagenfeldt,et al.  Creatine treatment in MELAS. , 1994, Muscle & nerve.

[9]  C. Denis,et al.  ATP synthesis kinetic properties of mitochondria isolated from the rat extensor digitorum longus muscle depleted of creatine with beta-guanidinopropionic acid. , 1994, Biochimica et biophysica acta.

[10]  H. Eppenberger,et al.  Mitochondrial creatine kinase: a major constituent of pathological inclusions seen in mitochondrial myopathies. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[11]  G. Radda,et al.  Actions of the creatine analogue beta-guanidinopropionic acid on rat heart mitochondria. , 1994, Biochemical Journal.

[12]  T. Wallimann,et al.  Crystallization of mitochondrial creatine kinase on negatively charged lipid layers. , 1994, Journal of structural biology.

[13]  E. Bergamini,et al.  The induction of mitochondrial myopathy in the rat by feeding beta-guanidinopropionic acid and the reversibility of the induced mitochondrial lesions: a biochemical and ultrastructural investigation. , 1993, International journal of experimental pathology.

[14]  J. Holloszy,et al.  Adaptation of rat skeletal muscle to creatine depletion: AMP deaminase and AMP deamination. , 1992, Journal of applied physiology.

[15]  T. Wallimann,et al.  Mitochondrial creatine kinase mediates contact formation between mitochondrial membranes. , 1991, The Journal of biological chemistry.

[16]  M. Perryman,et al.  Regulatory element analysis and structural characterization of the human sarcomeric mitochondrial creatine kinase gene. , 1991, The Journal of biological chemistry.

[17]  H. Eppenberger,et al.  Adult rat cardiomyocytes cultured in creatine-deficient medium display large mitochondria with paracrystalline inclusions, enriched for creatine kinase , 1991, The Journal of cell biology.

[18]  H. Eppenberger,et al.  Muscle-type MM creatine kinase is specifically bound to sarcoplasmic reticulum and can support Ca2+ uptake and regulate local ATP/ADP ratios. , 1990, The Journal of biological chemistry.

[19]  M. Kushmerick,et al.  Administration of a creatine analogue induces isomyosin transitions in muscle. , 1989, The American journal of physiology.

[20]  M. Wyss,et al.  Native mitochondrial creatine kinase forms octameric structures. I. Isolation of two interconvertible mitochondrial creatine kinase forms, dimeric and octameric mitochondrial creatine kinase: characterization, localization, and structure-function relationships. , 1988, The Journal of biological chemistry.

[21]  G. Farrants,et al.  Two types of mitochondrial crystals in diseased human skeletal muscle fibers , 1988, Muscle & nerve.

[22]  D. J. Hayes,et al.  Biochemical adaptation in the skeletal muscle of rats depleted of creatine with the substrate analogue beta-guanidinopropionic acid. , 1985, The Biochemical journal.

[23]  H. Eppenberger,et al.  Function of M-line-bound creatine kinase as intramyofibrillar ATP regenerator at the receiving end of the phosphorylcreatine shuttle in muscle. , 1984, The Journal of biological chemistry.

[24]  V. Saks,et al.  Role of creatine phosphokinase in cellular function and metabolism. , 1978, Canadian journal of physiology and pharmacology.

[25]  S. Schiaffino,et al.  Mitochondrial changes in ischemic skeletal muscle. , 1977, Journal of ultrastructure research.

[26]  A. Eisen,et al.  Experimental ischemic myopathy. , 1974, Journal of the neurological sciences.

[27]  G. L. Kenyon,et al.  On the specificity of creatine kinase. New glycocyamines and glycocyamine analogs related to creatine. , 1971, Journal of the American Chemical Society.

[28]  J. Dickinson,et al.  Localization of Encephalitogenic Basic Protein in the Intraperiod Line of Lamellar Myelin , 1970, Nature.

[29]  U. K. Laemmli,et al.  Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4 , 1970, Nature.

[30]  G. Attardi,et al.  The biogenesis of mitochondria. , 1970, The Biochemical journal.

[31]  M. Wyss,et al.  Intracellular compartmentation, structure and function of creatine kinase isoenzymes in tissues with high and fluctuating energy demands: the 'phosphocreatine circuit' for cellular energy homeostasis. , 1992, The Biochemical journal.

[32]  D. Wallace,et al.  Diseases of the mitochondrial DNA. , 1992, Annual review of biochemistry.

[33]  Y. Ohira,et al.  Intramitochondrial inclusions caused by depletion of creatine in rat skeletal muscles. , 1988, The Japanese journal of physiology.

[34]  M. Unser,et al.  A new resolution criterion based on spectral signal-to-noise ratios. , 1987, Ultramicroscopy.

[35]  W. O. Saxton,et al.  Three-dimensional reconstruction of imperfect two-dimensional crystals. , 1984, Ultramicroscopy.

[36]  Theodor Bücher,et al.  Einfache und zusammengesetzte optische Tests mit Pyridinnucleotiden , 1964 .