Changes in oxidative metabolism and ultrastructure accompanying differentiation of the mitochondrion in Trypanosoma brucei

A method is described for obtaining optimal growth and morphological transformation of Trypanosoma brucei 792G in a monophasic blood lysate medium starting from populations of bloodstream trypanosomes containing over 90 per cent intermediate and stumpy forms. Transformation was accompanied by: (1) an increase in length of the trypanosomes from 13·8 (± 3·0) μm to 23·0 (± 2·5) μm; (2) an increase in the kinetoplastic index from 1·0 to greater than 2·0; (3) development of the mitochondrion from a single abflagellar canal to a network of subpellicular canals, with outgrowth of the post-kineto-plastic region of the mitochondrion; (4) replacement of some of the tubular mitochondrial cristae by plate-like cristae; (5) the acquisition of succinoxidase, succinate-cytochrome c reductase, and glycerophosphate-cytochrome c reductase activities; (6) a marked increase in proline oxidase and NADH-cytochrome c reductase activities; (7) loss of the surface coat of the flagellate and concomitant reduction in the smooth-membrane systems lying between the nucleus and flagellar pocket; (8) reduction in infectivity of the trypanosomes to the mammalian host. Although growth in primary culture continued up to 100 h, transformation was completed in 48 h. All the respiratory enzyme activities tested were insensitive to cyanide throughout transformation. Division of trypanosomes appeared to be taking place throughout the transformation process. Cyanide sensitivity developed only after subculture of the trypanosomes into a biphasic medium.