Protein Engineering Reveals Mechanisms of Functional Amyloid Formation in Pseudomonas aeruginosa Biofilms

Bleem, Alissa; Christiansen, Gunna; Madsen, Daniel Jhaf; Maric, Hans Michael; Strømgaard, Kristian; Bryers, James D.; Daggett, Valerie; Meyer, Rikke Louise; Otzen, Daniel E.

doi:10.1016/j.jmb.2018.06.043

Cited by 46 publications

(51 citation statements)

References 50 publications

(60 reference statements)

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“…This repeat‐free construct aggregates in a highly stochastic nature which prevents proper fitting with Amylofit; furthermore, the ensuing fibrils show an unusual mesh‐like structure and are also much less stable against solubilization by formic acid than all the other mutants (Christensen et al, unpublished data). Furthermore, Figure (A) shows a certain level of similarity between the regions flanking the repeats (although much weaker than between the actual repeats), while bioinformatics analyses also indicate a significant amyloidogenicity in these regions, although less so than with the repeats . A likely explanation is that the repeats drive fibrillation so efficiently that they override any alternative aggregative behavior of the linker regions, and it is only the complete removal of the repeats proper that allows the linker regions to “take their place in the sun” and aggregate on their own.…”

Section: Discussionmentioning

confidence: 98%

“…Furthermore, Figure 1(A) shows a certain level of similarity between the regions flanking the repeats (although much weaker than between the actual repeats), while bioinformatics analyses also indicate a significant amyloidogenicity in these regions, although less so than with the repeats. 30 A likely explanation is that the repeats drive fibrillation so efficiently that they override any alternative aggregative behavior of the linker regions, and it is only the complete removal of the repeats proper that allows the linker regions to "take their place in the sun" and aggregate on their own. Linker regions may also serve an independent purpose by modulating the physical-chemical surface properties of the ensuing fibrils and thus interactions between individual fibrils.…”

Section: Fibrillation Of a Fapc Construct Lacking All Three Repeats Imentioning

confidence: 99%

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Imperfect repeats in the functional amyloid protein FapC reduce the tendency to fragment during fibrillation

et al. 2019

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Functional amyloid (FA) is widespread in bacteria and serves multiple purposes such as strengthening of biofilm and contact with eukaryotic hosts. Unlike pathological amyloid, FA has been subjected to evolutionary optimization which is likely to be reflected in the aggregation mechanism. FA from different bacteria, including Escherichia coli (CsgA) and Pseudomonas (FapC), contains a number of imperfect repeats which may be key to efficient aggregation. Here we report on the aggregative behavior of FapC constructs which represent all single, double, and triple deletions of the protein's three imperfect repeats. Analysis of the fibrillation kinetics by the program Amylofit reveals that the removal of these repeats increases the tendency of the growing fibrils to fragment and also generally increases aggregation half‐times. Remarkably, even the mutant lacking all three repeats was able to fibrillate, although fibrillation was much more irregular and led to significantly altered and destabilized fibrils. We conclude that imperfect repeats can promote fibrillation efficiency thanks to their modular design, though the context of the imperfect repeats also plays a significant role.

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Section: Discussionmentioning

confidence: 98%

Section: Fibrillation Of a Fapc Construct Lacking All Three Repeats Imentioning

confidence: 99%

Imperfect repeats in the functional amyloid protein FapC reduce the tendency to fragment during fibrillation

et al. 2019

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“…In prokaryotes, disulfide bonds also play an important role in the stability of the extracellular substances. For example, P. aeruginosa secretes an array of proteins, many of which contain disulfide bonds, such as FapC, an amyloid protein abundant in P. aeruginosa EPS, which requires two highly conserved cysteines to form disulfide linkages between two monomers to form mature fibrils [47]. A 29 kDa extracellular lipase secreted by P. aeruginosa contains two cysteine residues to maintain its active conformation [48].…”

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confidence: 99%

N-Acetyl-cysteine and Mechanisms Involved in Resolution of Chronic Wound Biofilm

Jane

et al. 2020

Journal of Diabetes Research

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Chronic wounds are a major global health problem with the presence of biofilm significantly contributing to wound chronicity. Current treatments are ineffective in resolving biofilm and simultaneously killing the bacteria; therefore, effective biofilm-resolving drugs are needed. We have previously shown that, together with α-tocopherol, N-acetyl-cysteine (NAC) significantly improves the healing of biofilm-containing chronic wounds, in a diabetic mouse model we developed, by causing disappearance of the bacteria and breakdown of the extracellular polymeric substance (EPS). We hypothesize that NAC creates a microenvironment that affects bacterial survival and EPS integrity. To test this hypothesis, we developed an in vitro biofilm system using microbiome taken directly from diabetic mouse chronic wounds. For these studies, we chose mice in which chronic wound microbiome was rich in Pseudomonas aeruginosa (97%). We show that NAC at concentrations with pH < pKa causes bacterial cell death and breakdown of EPS. When used before biofilm is formed, NAC leads to bacterial cell death whereas treatment after the biofilm is established NAC causes biofilm dismantling accompanied by bacterial cell death. Mechanistically, we show that NAC can penetrate the bacterial membrane, increase oxidative stress, and halt protein synthesis. We also show that low pH is important for the actions of NAC and that bacterial death occurs independently of the presence of biofilm. In addition, we show that both the acetyl and carboxylic groups play key roles in NAC functions. The results presented here provide insight into the mechanisms by which NAC dismantles biofilm and how it could be used to treat chronic wounds after debridement (NAC applied at the start of culture) or without debridement (NAC applied when biofilm is already formed). This approach can be taken to develop biofilm from microbiome taken directly from human chronic wounds to test molecules that could be effective for the treatment of specific biofilm compositions.

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“…An amyloidogenic or amyloid‐forming protein (Figure H) is a protein that misfolds upon certain conditions, and the misfolded structure experiences irreversible aggregation forming amyloid fibrils. They are mostly related to neurodegenerative diseases, but some functional amyloids have also been described …”

Section: Introductionmentioning

confidence: 99%

“…They are mostly relatedt on eurodegenerative diseases,b ut some functional amyloids have also been described. [27][28][29] Hereinafter,w ef ocus on three closely related types of sequences:c hameleon sequences, metamorphic proteins, and switchp eptides. We use the generic term "turncoat" polypeptides to encompass all of them.…”

Section: Introductionmentioning

confidence: 99%

Turncoat Polypeptides: We Adapt to Our Environment

et al. 2019

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A common interpretation of Anfinsen's hypothesis states that one amino acid sequence should fold into a single, native, ordered state, or a highly similar set thereof, coinciding with the global minimum in the folding‐energy landscape, which, in turn, is responsible for the function of the protein. However, this classical view is challenged by many proteins and peptide sequences, which can adopt exchangeable, significantly dissimilar conformations that even fulfill different biological roles. The similarities and differences of concepts related to these proteins, mainly chameleon sequences, metamorphic proteins, and switch peptides, which are all denoted herein “turncoat” polypeptides, are reviewed. As well as adding a twist to the conventional view of protein folding, the lack of structural definition adds clear versatility to the activity of proteins and can be used as a tool for protein design and further application in biotechnology and biomedicine.

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Protein Engineering Reveals Mechanisms of Functional Amyloid Formation in Pseudomonas aeruginosa Biofilms

Cited by 46 publications

References 50 publications

Imperfect repeats in the functional amyloid protein FapC reduce the tendency to fragment during fibrillation

Imperfect repeats in the functional amyloid protein FapC reduce the tendency to fragment during fibrillation

N-Acetyl-cysteine and Mechanisms Involved in Resolution of Chronic Wound Biofilm

Turncoat Polypeptides: We Adapt to Our Environment

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