Ultra-High Resolution 3D Imaging of Whole Cells

Huang, Fang; Sirinakis, George; Allgeyer, Edward S.; Schroeder, Lena K.; Duim, Whitney C.; Kromann, Emil B.; Phan, Thomy; Rivera‐Molina, Felix; Myers, Jordan; Irnov, Irnov; Lessard, Mark D.; Zhang, Yongdeng; Handel, Mary Ann; Jacobs‐Wagner, Christine; Lusk, C. Patrick; Rothman, James E.; Toomre, Derek; Booth, Martin J.; Bewersdorf, Joerg

doi:10.1016/j.cell.2016.06.016

Cited by 274 publications

(314 citation statements)

References 61 publications

(95 reference statements)

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“…S2). We grew the mEos3.2-PrgH-expressing bacteria under conditions that stimulate the expression of the type III secretion system and imaged them by SMSN (32,34). Superresolution images of these live bacteria showed the appearance of fluorescent clusters with a diameter of ∼45 nm ( Fig.…”

Section: Resultsmentioning

confidence: 99%

“…For SMSN or 4Pi-SMSN, bacteria were placed on agarose pads or on poly-D-lysine-coated glass-bottom microwell dishes, respectively. The 2D and 3D superresolution imaging was performed with a custom-built FPALM system as previously described (31,32,34,53). Cluster analysis was carried out using a DBSCAN clustering algorithm (54,55) and a wavelet algorithm (56) as described in SI Appendix, Materials and Methods.…”

Section: Methodsmentioning

confidence: 99%

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Visualization and characterization of individual type III protein secretion machines in live bacteria

Zhang

Lara‐Tejero

Bewersdorf

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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103

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Type III protein secretion machines have evolved to deliver bacterially encoded effector proteins into eukaryotic cells. Although electron microscopy has provided a detailed view of these machines in isolation or fixed samples, little is known about their organization in live bacteria. Here we report the visualization and characterization of the Salmonella type III secretion machine in live bacteria by 2D and 3D single-molecule switching superresolution microscopy. This approach provided access to transient components of this machine, which previously could not be analyzed. We determined the subcellular distribution of individual machines, the stoichiometry of the different components of this machine in situ, and the spatial distribution of the substrates of this machine before secretion. Furthermore, by visualizing this machine in Salmonella mutants we obtained major insights into the machine's assembly. This study bridges a major resolution gap in the visualization of this nanomachine and may serve as a paradigm for the examination of other bacterially encoded molecular machines.bacterial nanomachines | protein secretion | superresolution microscopy | bacterial pathogenesis | Salmonella virulence T ype III secretion systems are remarkable molecular machines with the capacity to inject multiple bacterial proteins into eukaryotic cells (1, 2). These machines play an essential role in the pathogenic or symbiotic relationships between the bacteria that encode them and their respective hosts. Consequently, type III secretion systems are rapidly emerging as targets for the development of novel therapeutic and prevention strategies with the potential to combat several important infectious diseases (3-5). The components of type III secretion machines are highly conserved across bacterial species although the effector proteins that they deliver are customized for the specific bacteria that harbor them (1, 6, 7). The entire type III secretion machine or injectisome is ∼40 nm in width and ∼150 nm in length and is organized in defined substructures (Fig. 1A). The bestcharacterized substructure is the needle complex, which is a multi-ring cylindrical structure embedded in the bacterial envelope with a needle-like extension that projects several nanometers from the bacterial surface. The needle complex is traversed by a narrow channel that serves as the conduit for the proteins that travel this secretion pathway (8). The needle is capped at its end by the tip complex, which is thought to coordinate the activation of the secretion machine upon contact with target cells (9, 10). Because the needle complex can be isolated in a manner suitable for single-particle cryo-electron microscopy, its organization at the quasi-atomic level is known (11-18). Passage of the secreted proteins through the inner membrane requires the export apparatus, which is composed of a group of poly-topic inner membrane proteins located at the center of the needle complex base (19). Finally, several cytoplasmic proteins form a large complex known as the...

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Visualization and characterization of individual type III protein secretion machines in live bacteria

Zhang

Lara‐Tejero

Bewersdorf

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

103

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“…To understand how signalling pathways interact with cytoskeletal structures to achieve specific mechanical and regulatory functions, future studies will likely benefit from improvements in these areas. Advances in optical microscopy have been making long strides towards three-dimensional high-resolution imaging and it will be exciting to see this new technology employed for studies of immune cells 76, [163][164][165] . Genetic manipulation is more accessible and precise than ever before, and new optogenetic and nanomechanical methods offer unprecedented temporal and spatial control of manipulation of live cells 166,167 .…”

Section: [H1] Conclusion and Outlookmentioning

confidence: 99%

Cytoskeletal control of B cell responses to antigens

Tolar

2017

Nat Rev Immunol

121

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The actin cytoskeleton is essential for cell mechanics and has increasingly been implicated in the regulation of cell signalling. In B cells, the actin cytoskeleton couples extensively to B cell receptor (BCR) signalling pathways and its defects can either enhance or suppress B cell activation. Recent insights from single-cell imaging and biophysical techniques suggest that actin orchestrates BCR signalling at the plasma membrane through effects on protein diffusion, and that it regulates antigen discrimination through the biomechanics of immune synapses. These mechanical functions also play a role in the adaptation of B cell subsets to specialized tasks during antibody responses.3

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“…However, since any given color 534 will have only a finite set of possible neighboring mistakes with associated error rates, a 535 substitution matrix of possible errors can be integrated into both the extension phase 536 and exploration phase of the suffix tree [26], changing the formulation of the problem into 537 a likelihood model of seeing the 3D position of probes given a certain path labeling. In 538 addition, recent advances in labeling techniques such as the 'Exchange-PAINT' method 539 now allow sequential hybridization and image capture, allowing to separate up to 10 540 pseudocolors based on a single dye in time [21]. This labeling technology requires long 541 super-resolution image acquisition times, but could massively increase the number of 542 probes available for the reconstruction algorithm.…”

mentioning

confidence: 99%

“…Super-resolution microscopy can resolve unprecedentedly small volume elements 66 (approximately 20 x 20 x 20 nm [21]) inside the total nuclear volume (approximately 67 8 × 10 −6 µm 3 ), which will on average contain only up to 2 kb or a few nucleosomes. This 68 fundamental increase in information of the relative positioning of defined loci in the 69 genome can now be leveraged computationally.…”

mentioning

confidence: 99%

ChromoTrace: Computational Reconstruction of 3D Chromosome Configurations for Super-Resolution Microscopy

Barton

Morganella

Ødegård-Fougner

et al. 2017

Preprint

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Motivation: The 3D structure of chromatin plays a key role in genome function, including gene expression, DNA replication, chromosome segregation, and DNA repair. Furthermore the location of genomic loci within the nucleus, especially relative to each other and nuclear structures such as the nuclear envelope and nuclear bodies strongly correlates with aspects of function such as gene expression. Therefore, determining the 3D position of the 6 billion DNA base pairs in each of the 23 chromosomes inside the nucleus of a human cell is a central challenge of biology. Recent advances of superresolution microscopy in principle enable the mapping of specific molecular features with nanometer precision inside cells. Combined with highly specific, sensitive and multiplexed fluorescence labeling of DNA sequences this opens up the possibility of mapping the 3D path of the genome sequence in situ.

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Ultra-High Resolution 3D Imaging of Whole Cells

Cited by 274 publications

References 61 publications

Visualization and characterization of individual type III protein secretion machines in live bacteria

Visualization and characterization of individual type III protein secretion machines in live bacteria

Cytoskeletal control of B cell responses to antigens

ChromoTrace: Computational Reconstruction of 3D Chromosome Configurations for Super-Resolution Microscopy

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