Protein diffusion in
            <i>Escherichia coli</i>
            cytoplasm scales with the mass of the complexes and is location dependent

Śmigiel, Wojciech M.; Mantovanelli, Luca; Linnik, Dmitrii S.; Punter, Michiel; Silberberg, Jakob M; Xiang, Limin; Xu, Ke; Poolman, Bert

doi:10.1126/sciadv.abo5387

Cited by 35 publications

(129 citation statements)

References 76 publications

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“…Previous work by others has shown that the cytosolic diffusion rate of proteins scales with molecular weight, but not according to the Stokes-Einstein equation, which stipulates that D ∝ (Molecular Weight) -1/3 . Instead, a D ∝ (Molecular Weight) -2/3 scaling has been observed by others independently for different proteins(45–48). Here, we obtain a D ∝(Molecular Weight) -0.71 scaling when plotting the measured diffusion coefficients against the molecular weights of monomeric eYFP and the protein complexes discussed above (likely stoichiometries were estimated based on current biophysical models of the cytosolic injectisome protein complexes) (Fig.…”

Section: Discussionmentioning

confidence: 87%

Distinct cytosolic complexes containing the type III secretion system ATPase resolved by 3D single-molecule tracking in liveYersinia enterocolitica

Prindle

Rocha

Wang

et al. 2022

Preprint

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The membrane-embedded injectisome, the structural component of the virulence-associated type III secretion system (T3SS), is used by gram-negative bacterial pathogens to inject species-specific effector proteins into eukaryotic host cells. The cytosolic injectisome proteins are required for export of effectors and display both stationary, injectisome-bound populations as well as freely-diffusing cytosolic populations. How the cytosolic injectisome proteins interact with each other in the cytosol and associate with membrane-embedded injectisomes remains unclear. Here, we utilize 3D single-molecule tracking to resolve distinct cytosolic complexes of injectisome proteins in living Yersinia enterocolitica cells. Tracking of the eYFP-labeled ATPase, YeSctN, and its regulator, YeSctL, reveals that these proteins form a cytosolic complex with each other and then further with YeSctQ. YeSctNL and YeSctNLQ complexes can be observed in both in wild type cells and in ΔsctD mutants, which cannot assemble injectisomes. In ΔsctQ mutants, the relative abundance of the YeSctNL complex is considerably increased. These data indicate that distinct cytosolic complexes of injectisome proteins can form prior to injectisome binding - a feature that could contribute to injectisome functional regulation.

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Section: Discussionmentioning

confidence: 87%

Distinct cytosolic complexes containing the type III secretion system ATPase resolved by 3D single-molecule tracking in liveYersinia enterocolitica

Prindle

Rocha

Wang

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Size- and position-dependency had previously been reported for the diffusion of smaller components in different cells. They were attributed to properties such as the hierarchy of cytoplasm pore sizes (33), glass-like transitions of bulk material (15), or to heterogeneities across cells (16). Our data for large objects, support a different physical origin, in which both size and position dependency can emerge solely from hydrodynamic interactions with the surface.…”

Section: Discussionmentioning

confidence: 99%

“…These have shown that cytoplasm response will depend on time-scale, force amplitude or component size (9)(10)(11)(12)(13). The question of object size has notably raised important notions for cytoplasm mechanics, as for components smaller or larger than a typical mesh size, the cytoplasm may exhibit different rheological signatures ranging from fluid, to viscoelastic, poroelastic, or even glassy materials (14)(15)(16)(17)(18)(19). However, these studies were restricted to regimes of relatively small objects typically below the micron size, as well as low forces and displacement amplitudes.…”

Section: Introductionmentioning

confidence: 99%

Size and position dependent cytoplasm viscoelasticity through hydrodynamic interactions with the cell surface

Najafi

Dmitrieff

Minc

2022

Preprint

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Many studies of cytoplasm rheology have focused on small components in the sub-micrometer scale. However, the cytoplasm also baths large organelles like nuclei, microtubule asters or spindles that often take significant portions of cells and move across the cytoplasm to regulate cell division or polarization. Here, we translated passive components of sizes ranging from few up to ~50 percent of the cell diameter, through the vast cytoplasm of live sea urchin eggs, with calibrated magnetic forces. Creep and relaxation responses indicate that for objects larger than the micron size, the cytoplasm behaves as a Jeffreys material, viscoelastic at short time-scales and fluidizing at longer times. However, as components size approached that of cells, cytoplasm viscoelastic resistance increased in a non-monotonic manner. Flow analysis and simulations suggest that this size-dependent viscoelasticity emerges from hydrodynamic interactions between the moving object and the static cell surface. This effect also yields to position-dependent viscoelasticity with objects initially closer to the cell surface being harder to displace. These findings suggest that the cytoplasm hydrodynamically couples large organelles to the cell surface to restrain their motion, with important implications for cell shape sensing and cellular organization.

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“…Cell components compartmentalize by demixing or preferential interactions in which protein crowders assemble with other biomolecules or membranes. Indeed, diffusion experiments have shown significant spatial heterogeneity in prokaryotes and eukaryotes 8,9 . Crowders captured in large complexes crowd less effectively because a crowder needs to diffuse to generate the depletion force, and complexation reduces the crowder number density.…”

Section: Introductionmentioning

confidence: 99%

“…These probes are based on diffusion or protein conformation. The former measures viscosity, which, among others, depends on the relative size of the tracer and crowders and is sensitive to large immobile obstacles such as a membrane 9,11 . Conformationally-sensitive probes rely on compressing a probe protein 12,13 .…”

Section: Introductionmentioning

confidence: 99%

Cell wall damage increases macromolecular crowding effects in the Escherichia coli cytoplasm

Pittas

Zuo

Boersma

2022

Preprint

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The intracellular milieu is crowded with biomacromolecules. Macromolecular crowding changes the interactions, diffusion, and conformations of the biomacromolecules. Changes in intracellular crowding effects have been mostly ascribed to differences in biomacromolecule concentration. However, the spatial organization of these molecules should play a significant role in crowding effects. Here, we find that cell wall damage causes increased macromolecular crowding effects in the Escherichia coli cytoplasm. Using a genetically-encoded macromolecular crowding sensor, we see that crowding effects in E. coli spheroplasts and Penicillin G-treated cells well surpass crowding effects obtained using hyperosmotic stress. The crowding increase is not due to osmotic pressure, cell shape, crowder synthesis, or volume changes, and therefore not crowder concentration. Instead, a genetically-encoded nucleic acid stain and a small molecule DNA stain show nucleoid expansion and cytoplasmic mixing, which could cause these increased crowding effects. Our data demonstrate that cell stress from antibiotics or cell wall damage alters the biochemical organization in the cytoplasm and induces significant conformational changes in a probe protein.

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Protein diffusion in Escherichia coli cytoplasm scales with the mass of the complexes and is location dependent

Cited by 35 publications

References 76 publications

Distinct cytosolic complexes containing the type III secretion system ATPase resolved by 3D single-molecule tracking in liveYersinia enterocolitica

Distinct cytosolic complexes containing the type III secretion system ATPase resolved by 3D single-molecule tracking in liveYersinia enterocolitica

Size and position dependent cytoplasm viscoelasticity through hydrodynamic interactions with the cell surface

Cell wall damage increases macromolecular crowding effects in the Escherichia coli cytoplasm

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