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Vol. 13, Issue 11, 3787-3799, November 2002
Institut für Zellbiologie, Universität Bern, CH-3012
Bern, Switzerland
In cycling between the mammalian host and the tsetse fly vector,
African trypanosomes undergo adaptive differentiation steps that are
coupled to growth control. The signaling pathways underlying these
cellular processes are largely unknown. Mitogen-activated protein
kinases (MAPKs) are known mediators of growth and differentiation in
other eukaryotic organisms. To establish the function of a MAPK
homologue, TbMAPK2, in T. brucei, a null
mutant was constructed. Bloodstream forms of a
mapk2/mapk2 clone were able to grow normally and
exhibited no detectable phenotype. When these cells were triggered to
differentiate in vitro, however, they developed to the procyclic (fly
midgut) form with delayed kinetics and subsequently underwent cell
cycle arrest. Introduction of an ectopic copy of the
TbMAPK2 gene into the null mutant restored its ability
to differentiate and to divide. In contrast, a TbMAPK2
mutant, in which the T190 and Y192 residues of the activating
phosphorylation site were replaced by A and F, was unable to restore
the growth and differentiation phenotypes. Analysis of the DNA content
and the nucleus/kinetoplast configuration of individual cells showed
that the null mutant was arrested in all phases of the cell cycle and
that 25-30% of the cells had failed to segregate their nucleus and
kinetoplast correctly. This implies that cell cycle progression by the
procyclic form depends on a constitutive stimulus exerted by the
signaling cascade operating through TbMAPK2.
Corresponding author. E-mail address:
erik.vassella{at}izb.unibe.ch.
*
Both authors contributed equally to this work.
Present address: Bernhard Nocht Institut für
Tropenmedizin, Abteilung Biochemische Parasitologie, D-20359 Hamburg, Germany.
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