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Improved HaloTag for analyses of translocation of type III secretion system effector proteins

Fritsch, V. N.; Holtmannspoetter, M.; Hensel, M.

2026-06-01 microbiology
10.64898/2026.05.31.729057 bioRxiv
Show abstract

Effector translocation during host-pathogen interactions is a prerequisite for the entry of Salmonella into non-phagocytic cells and establishment of a replication permissive intracellular niche. Deciphering the dynamics and kinetics of translocation and subcellular localization demands live-cell imaging and tagging approaches that do not introduce detection delays or perturb the translocation process via the type III secretion system (T3SS). Effector fusions with self-labelling enzymes (SLE), such as HaloTag, allow localization and tracking at high temporal and spatial resolution. However, interference with T3SS-dependent translocation has hampered analyses of the process of translocation and early subcellular distribution and dynamics. Herein, we report that amino acid substitutions of the HaloTag can reduce the thermodynamic stability, resulting in less steric hindrance during translocation of effector-HaloTag fusions by the T3SS in mammalian cells. The top variant, HT-SP5, showed reduced retention in Salmonella, enabling more sensitive and earlier detection of translocated effector proteins of the SPI1 and SPI2 T3SS of Salmonella and of the T3SS effector Map of enteropathogenic Escherichia coli (EPEC). We applied the improved HaloTag HT-SP5 to single molecule tracking, and to follow effector protein dynamics in living host cells early after translocation by invading and intracellular bacteria. Taken together, the improved HaloTag variant HT-SP5 represents a robust and versatile SLE tag for dynamic real-time analyses of delivery and fate of T3SS-translocated effector proteins in living cells host. Application of HT-SP5 will facilitate research on effectors throughout the entire infection process at native effector levels to understand host-pathogen interactions.

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