Staphylococcal biofilm-forming protein has a contiguous rod-like structure

Gruszka, Dominika T.; Wojdyla, Justyna Aleksandra; Bingham, Richard J.; Turkenburg, J.P.; Manfield, Iain W.; Steward, Annette; Leech, Andrew; Geoghegan, Joan A.; Foster, Timothy J.; Clarke, Jane; Potts, Jennifer R.

doi:10.1073/pnas.1119456109

Cited by 76 publications

(96 citation statements)

References 65 publications

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“…1). We have previously shown that the E domain is fully unfolded in isolation (10). Because SasG domains have no tryptophans, (un)folding was followed by monitoring intrinsic tyrosine fluorescence.…”

Section: Resultsmentioning

confidence: 99%

Disorder drives cooperative folding in a multidomain protein

Gruszka

Mendonca

Paci

et al. 2016

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

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Many human proteins contain intrinsically disordered regions, and disorder in these proteins can be fundamental to their function-for example, facilitating transient but specific binding, promoting allostery, or allowing efficient posttranslational modification. SasG, a multidomain protein implicated in host colonization and biofilm formation in Staphylococcus aureus, provides another example of how disorder can play an important role. Approximately one-half of the domains in the extracellular repetitive region of SasG are intrinsically unfolded in isolation, but these E domains fold in the context of their neighboring folded G5 domains. We have previously shown that the intrinsic disorder of the E domains mediates long-range cooperativity between nonneighboring G5 domains, allowing SasG to form a long, rod-like, mechanically strong structure. Here, we show that the disorder of the E domains coupled with the remarkable stability of the interdomain interface result in cooperative folding kinetics across long distances. Formation of a small structural nucleus at one end of the molecule results in rapid structure formation over a distance of 10 nm, which is likely to be important for the maintenance of the structural integrity of SasG. Moreover, if this normal folding nucleus is disrupted by mutation, the interdomain interface is sufficiently stable to drive the folding of adjacent E and G5 domains along a parallel folding pathway, thus maintaining cooperative folding.IDP | protein folding | parallel pathways | protein engineering | cooperativity I t has been suggested that as much as 20% of the proteome may be intrinsically disordered (1), mainly manifested as intrinsically disordered regions within multidomain proteins, although a few proteins are apparently entirely disordered. Some proteins function as a consequence of disorder: for example, disordered PEVK regions of titin act as an entropic spring (2), whereas in the nuclear pore complex, disordered nucleoporins provide a thick selective barrier controlling nuclear import (3). Disorder can also play other roles: it facilitates posttranslational modification and may promote allostery (4, 5). SasG (Staphylococcus aureus surface protein G) is a cell wall-attached protein from S. aureus that promotes intercellular adhesion during the accumulation phase of biofilm formation via its C-terminal repetitive region (6-8). We previously showed that this part of SasG contains alternating E and G5 domains (Fig. 1A) and that E folds when it is N-terminal of a G5 domain. The disorder of E domains in isolation is essential for formation of a long, stiff, mechanically strong, rod-like structure (9) capable of projecting the N-terminal A domain, which is involved in host colonization (6).Here, we combine biophysical measurements, protein engineering, and simulation to show that the disorder in the E domains of SasG also promotes cooperative folding and unfolding pathways. We find that SasG domains have a highly polarized transition-state (TS) structure, where formation of a sm...

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Section: Resultsmentioning

confidence: 99%

Disorder drives cooperative folding in a multidomain protein

Gruszka

Mendonca

Paci

et al. 2016

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

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“…The length of the B region was shown to be critical for biofilm development because only SasG (or Aap) constructs with five or more B-repeats supported biofilm formation, while constructs with four or fewer B-repeats did not. Structural studies revealed that Aap B-repeats of the appropriate length adopt an elongated, rope-like structure coordinated by zinc ions and wrap around one another in an antiparallel fashion to form bundles of fibers that establish homophilic interactions and have the potential to interconnect neighbor cells (46,47).…”

Section: Fig 6 Effect Of Ph On the Isdc Expression And Biofilm Formatmentioning

confidence: 99%

“…The structural characterization of Aap and SasG in biofilm development has been recently defined (46,47). Aap and SasG comprise an N-terminal A region and repeated B domains toward the C terminus.…”

Section: Fig 6 Effect Of Ph On the Isdc Expression And Biofilm Formatmentioning

confidence: 99%

IsdC from Staphylococcus lugdunensis Induces Biofilm Formation under Low-Iron Growth Conditions

et al. 2014

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Staphylococcus lugdunensis is a coagulase-negative staphylococcus that is a commensal of humans and an opportunistic pathogen. It can cause a spectrum of infections, including those that are associated with the ability to form biofilm, such as occurs with endocarditis or indwelling medical devices. The genome sequences of two strains revealed the presence of orthologues of the ica genes that are responsible for synthesis of poly-N-acetylglucosamine (PNAG) that is commonly associated with biofilm in other staphylococci. However, we discovered that biofilm formed by a panel of S. lugdunensis isolates growing in iron-restricted medium was susceptible to degradation by proteases and not by metaperiodate, suggesting that the biofilm matrix comprised proteins and not PNAG. When the iron concentration was raised to 1 mM biofilm formation by all strains tested was greatly reduced. A mutant of strain N920143 lacking the entire locus that encodes iron-regulated surface determinant (Isd) proteins was defective in biofilm formation under iron-limited conditions. An IsdC-null mutant was defective, whereas IsdK, IsdJ, and IsdB mutants formed biofilm to the same level as the parental strain. Expression of IsdC was required both for the primary attachment to unconditioned polystyrene and for the accumulation phase of biofilm involving cell-cell interactions. Purified recombinant IsdC protein formed dimers in solution and Lactococcus lactis cells expressing only IsdC adhered to immobilized recombinant IsdC but not to IsdJ, IsdK, or IsdB. This is consistent with a specific homophilic interaction between IsdC molecules on neighboring cells contributing to accumulation of S. lugdunensis biofilm in vivo.

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“…1). Several studies have demonstrated that Aap is a rod-like fibril extending from the cell surface (26,31,44). Bioinformatics analysis suggests Aap consists of two distinct domains, the A domain and B domain (28,45).…”

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confidence: 99%

“…Each of these B repeats is composed of 2 subdomains, G5 and E. The G5 unit is the functional component of the B repeat due to its propensity for self association; thus, it coordinates Aap-dependent intercellular interactions (27,30). E spacer regions are located between G5 units and likely prevent misfolding of the protein, a potential consequence of its extended fibrillar nature and repetitive domain architecture (44). Following extracellular export directed by the N-terminal signal sequence, Aap is anchored to the cell wall at the C-terminally located LPDTG sortase recognition motif (28,47).…”

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confidence: 99%

Accumulation-Associated Protein Enhances Staphylococcus epidermidis Biofilm Formation under Dynamic Conditions and Is Required for Infection in a Rat Catheter Model

et al. 2015

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Biofilm formation is the primary virulence factor of Staphylococcus epidermidis. S. epidermidis biofilms preferentially form on abiotic surfaces and may contain multiple matrix components, including proteins such as accumulation-associated protein (Aap). Following proteolytic cleavage of the A domain, which has been shown to enhance binding to host cells, B domain homotypic interactions support cell accumulation and biofilm formation. To further define the contribution of Aap to biofilm formation and infection, we constructed an aap allelic replacement mutant and an icaADBC aap double mutant. When subjected to fluid shear, strains deficient in Aap production produced significantly less biofilm than Aap-positive strains. To examine the in vivo relevance of our findings, we modified our previously described rat jugular catheter model and validated the importance of immunosuppression and the presence of a foreign body to the establishment of infection. The use of our allelic replacement mutants in the model revealed a significant decrease in bacterial recovery from the catheter and the blood in the absence of Aap, regardless of the production of polysaccharide intercellular adhesin (PIA), a well-characterized, robust matrix molecule. Complementation of the aap mutant with full-length Aap (containing the A domain), but not the B domain alone, increased initial attachment to microtiter plates, as did in trans expression of the A domain in adhesion-deficient Staphylococcus carnosus. These results demonstrate Aap contributes to S. epidermidis infection, which may in part be due to A domain-mediated attachment to abiotic surfaces.

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Staphylococcal biofilm-forming protein has a contiguous rod-like structure

Cited by 76 publications

References 65 publications

Disorder drives cooperative folding in a multidomain protein

Disorder drives cooperative folding in a multidomain protein

IsdC from Staphylococcus lugdunensis Induces Biofilm Formation under Low-Iron Growth Conditions

Accumulation-Associated Protein Enhances Staphylococcus epidermidis Biofilm Formation under Dynamic Conditions and Is Required for Infection in a Rat Catheter Model

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