2025
mBio (American Society for Microbiology)

Host-encoded ETP2 is involved in recruiting the dynamin-like protein ETP9 to the endosymbiont division site in trypanosomatid Angomonas deanei

Authors:

Anay K. Maurya, Lawrence Rudy Cadena, Georg Ehret, Eva C. M. Nowack

Keywords:

Host-Microbial Interactions; ETP2; ETP9; endosymbiont division site; Angomonas deanei; Candidatus Kinetoplastibacterium crithidii; β-proteobacterium; endosymbiont; endosymbiont-targeted host protein; division

Abstract:

A single β-proteobacterial endosymbiont, Candidatus Kinetoplastibacterium crithidii, resides in the cytosol of the trypanosomatid Angomonas deanei and divides at a defined stage of its host’s cell cycle. This endosymbiont has a highly reduced genome of 0.8 Mb and, notably, has lost most essential bacterial division genes, resulting in a loss of division autonomy. It has been previously demonstrated that a host-encoded dynamin-like protein, endosymbiont-targeted host protein (ETP)9, plays an indispensable role in the division of the endosymbiont. In this study, we identified a second nucleus-encoded component of the endosymbiont division machinery, termed ETP2, currently annotated as a “hypothetical protein.” We observed that ETP2 arrives before ETP9 at the bacterial division site. ETP2 deletion or depletion results in division phenotypes with long, filamentous endosymbionts accompanied by severely distorted host cells or host daughter cells lacking endosymbionts. We found that ETP2 depletion results in mis-localization of ETP9, whereas ETP2 localization to the endosymbiont division site is independent of ETP9. In silico analyses revealed that ETP2 is found exclusively in endosymbiont-harboring trypanosomatids of the subfamily Strigomonadinae and is most likely an intrinsically disordered protein. Collectively, our data suggests that ETP2 is an integral component of the endosymbiont division machinery involved in recruiting ETP9 to the division site. This finding highlights the evolution of a complex host-derived molecular mechanism that exerts tight control over its endosymbiont without requiring gene transfers from the bacterium.