Abstract
Apicomplexan parasites, such as the malaria-causing Plasmodium species, utilize a unique way of locomotion and host cell invasion. This substrate-dependent gliding motility requires rapid cycling of actin between the monomeric state and very short, unbranched filaments. Despite the crucial role of actin polymerization for the survival of the malaria parasite, the majority of Plasmodium cellular actin is present in the monomeric form. Plasmodium lacks most of the canonical actin nucleators, and formins are essentially the only candidates for this function in all Apicomplexa. The malaria parasite has two formins, containing conserved formin homology (FH) 2 and rudimentary FH1 domains. Here, we show that Plasmodium falciparum formin 1 associates with and nucleates both mammalian and Plasmodium actin filaments. Although Plasmodium profilin alone sequesters actin monomers, thus inhibiting polymerization, its monomer-sequestering activity does not compete with the nucleating activity of formin 1 at an equimolar profilin-actin ratio. We have determined solution structures of P. falciparum formin 1 FH2 domain both in the presence and absence of the lasso segment and the FH1 domain, and show that the lasso is required for the assembly of functional dimers.
Highlights
IntroductionBest-characterized members of this phylum are the causative agents of malaria (Plasmodium spp.) and toxoplasmosis (Toxoplasma gondii)
Apicomplexan parasites comprise an important group of human and animal pathogens
The light scattering profiles, confirm that P. falciparum formin 1 (Pf-Frm1)-FH1FH2 and Pf-Frm1-FH2 are dimeric in solution, with molecular weights of 105.0 kDa (61%) and 98.2 kDa (63%), respectively, whereas the majority of PfFrm1-FH2Dlasso is monomeric with a molecular weight of kDa (66%)
Summary
Best-characterized members of this phylum are the causative agents of malaria (Plasmodium spp.) and toxoplasmosis (Toxoplasma gondii) These pathogens share a unique mode of actin-dependent motility, characterized by the absence of any specialized organelles or obvious changes in the cell shape [1]. Instead, this so-called gliding motility involves peculiarly short, unstable actin filaments, which work in concert with an unconventional myosin, and a small set of regulatory proteins, governing the rapid cycling of actin monomers back to the growing end of the filament [2]. The core actin regulators in Plasmodium include two formins [6], one profilin [7], two actin depolymerization factors [8,9], two capping protein subunits [10], coronin [11], and a Cterminal cyclase-associated protein homologue [12]
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