64 ELECTROLYTES IN BIOLOGICAL SYSTEMS 



Role of Pliospkorons in Plants and Animals, edited by W. D. McElroy and B. 

 Glass. Baltimore: John Hopkins Press, 1952. vol. 2, p. 748. 



23. LooMis, W. F. AND F. J. LiPMANN. Reversible inhibition of the coupling between phos- 

 phorylation and oxidation. /. Biol. Client. 173: 807, 1948. 



24. LuNDEGARDH, H. Spectroscopic evidence of the participation of the cytochrome — cyto- 

 chrome oxidase system in the active transport of salts. Arkiv. Kemi. Mineral. Geol. 3: 

 69, 1951. 



25. Maizels, M. Factors in the active transport of cations. /. Physiol. 112: 59, 1951. 



26. MuDGE, G. H. Electrolyte and water metabolism of rabbit kidney slices: efifect of met- 

 abolic inhibitors. Am. J. Physiol. 167: 206, 1951. 



27. MuDGE, G. H. Electrolyte metabolism of rabbit-kidney slices: studies with radioactive 

 potassium and sodium. Am. J. Physiol. 173: 511, 1953. 



28. OsTERHOUT, W. J. V. The accumulation of electrolytes. II. Suggestions as to the nature 

 of accumulation in Valonia. J. Gen. Physiol. 14: 285, 1930. 



29. OsTERHOUT, W. J. V. and S. E. Kamerling. The accumulation of electrolytes. VIII. The 

 accumulation of KCl in models. /. Gen. Physiol. 19: 167, 1935. 



30. OsTERHOUT, W. J. V. Some models of protoplasmic surfaces. Cold Spring Harbor Symp. 

 Quanl. Biol. 8: 51, 1940. 



31. Ponder, E. Accumulation of potassium by human red cells. J. Gtn. Physiol. 2,^: 745, 1950. 



32. Raker, J. \V., I. M. Taylor, J. M. Weller .and A. B. Hastings. Rate of potassium 

 exchange of the human erj-throcyte. J. Gen. Physiol. 33: 691, 1950. 



33. Roberts, R. B., I. Z. Roberts and D. B. Cowie. Potassium metabolism in Escherichia 

 coli. II, metabohsm in the presence of carbohydrates and their metabolic derivatives. 

 /. Cell. & Comp. Physiol. 34: 259, 1949. 



34. Rothenberg, M. a. Studies on permeability in relation to nerve function. II. Ionic 

 movements across axonal membranes. Biochim. el biophys. acta. 4: 96, 1950. 



35. Scott, G. T. and H. R. Hayward. Metabolic factors influencing the sodium and po- 

 tassium distribution in Ulva lactuca. J. Gen. Physiol. 36: 659, 1953. 



36. Scott, G. T. and H. R. Hayward. The influence of iodoacetate on the sodium and po- 

 tassium content of Ulva lactuca and the prevention of its influence by light. Science iiT. 



719, 1953- 



37. Scott, G. T. and H. R. Hayward. The influence of temperature and illumination on the 

 exchange of potassium ion in Uha lactuca. Biochim. et biophys. acta. 12: 401, 1953. 



38. Scott, G. T. and H. R. Hayward. Evidence for the presence of separate mechanisms 

 regulating potassium and sodium distribution in Ulva lactuca. J. Gen. Physiol. 37: 601, 



1954. 



39. Scott, G. T., M. J.acobson .a.nd M. E. Rice. The influence of glycolytic factors on the 

 potassium and sodium content of Saccharomyces cerevisiae. Arch. Biochem. 30: 282, 1951. 



40. Sheppard, C. W. New developments in potassium and cell physiology: 1940-1950. 

 Science 114: 85, 1951. 



41. Sheppard, C. W. and W. R. Martin. Cation exchange l)etween cells and plasma of 

 mammalian blood. I. Methods and application to potassium exchange in human blood. 

 /. Gen. Physiol. 33: 703, 1950. 



42. Steinbach, H. B. Permeability. Ann. Rero. Physiol. 13: 21, 1951. 



43. Steinbach, H. B. On the sodium and potassium balance of isolated frog muscles. Proc. 

 Nat. Acad. Sc. 38: 451, 1952. 



44. Ussing, H. H. Transport of ions across cellular meml)ranes. Physiol. Rev. 29: 127, 1949 



45. Warburg, O. Uber die Geschwindigkeit der photochemischen Kohlensaurezersetzung 

 in lebenden Zellen. Biochem. Ztschr. 103: 188, 1920. 



46. Warburg, O. and W. Christian. Isolierung und Kristallisation des Proteins des oxydi- 

 erenden Garungsferments. Biochem. Ztschr. 303: 40, 1940 



