Self-assembly of proteins to β-sheet rich amyloid fibrils is commonly observed in various neurodegenerative diseases. However, amyloid also occurs in the extracellular matrix of bacterial biofilm, which protects bacteria from environmental stress and antibiotics. Many Pseudomonas strains produce functional amyloid where the main component is the highly fibrillation-prone protein FapC. FapC fibrillation may be inhibited by small molecules such as plant polyphenols, which are already known to inhibit formation of pathogenic amyloid, but the mechanism and biological impact of inhibition is unclear. Here, we elucidate how polyphenols modify the self-assembly of functional amyloid, with particular focus on epigallocatechin gallate (EGCG), penta-O-galloyl-β-d-glucose (PGG), baicalein, oleuropein, and procyanidin B2. We find EGCG and PGG to be the best inhibitors. These compounds inhibit amyloid formation by redirecting the aggregation of FapC monomers into oligomeric species, which according to small-angle X-ray scattering (SAXS) measurements organize into core-shell complexes of short axis diameters 25–26 nm consisting of ~7 monomers. Using peptide arrays, we identify EGCG-binding sites in FapC’s linker regions, C and N-terminal parts, and high amyloidogenic sequences located in the R2 and R3 repeats. We correlate our biophysical observations to biological impact by demonstrating that the extent of amyloid inhibition by the different inhibitors correlated with their ability to reduce biofilm, highlighting the potential of anti-amyloid polyphenols as therapeutic agents against biofilm infections.
Functional amyloid is produced by many organisms but is particularly well understood in bacteria, where proteins such as CsgA (E. coli) and FapC (Pseudomonas) are assembled as functional bacterial amyloid (FuBA) on the cell surface in a carefully optimized process. Besides a host of helper proteins, FuBA formation is aided by multiple imperfect repeats which stabilize amyloid and streamline the aggregation mechanism to a fast-track assembly dominated by primary nucleation. These repeats, which are found in variable numbers in Pseudomonas, are most likely the structural core of the fibrils, though we still lack experimental data to determine whether the repeats give rise to β-helix structures via stacked β-hairpins (highly likely for CsgA) or more complicated arrangements (possibly the case for FapC). The response of FuBA fibrillation to denaturants suggests that nucleation and elongation involve equal amounts of folding, but protein chaperones preferentially target nucleation for effective inhibition. Smart peptides can be designed based on these imperfect repeats and modified with various flanking sequences to divert aggregation to less stable structures, leading to a reduction in biofilm formation. Small molecules such as EGCG can also divert FuBA to less organized structures, such as partially-folded oligomeric species, with the same detrimental effect on biofilm. Finally, the strong tendency of FuBA to self-assemble can lead to the formation of very regular two-dimensional amyloid films on structured surfaces such as graphite, which strongly implies future use in biosensors or other nanobiomaterials. In summary, the properties of functional amyloid are a much-needed corrective to the unfortunate association of amyloid with neurodegenerative disease and a testimony to nature’s ability to get the best out of a protein fold.
Formation of amyloid structures is originally linked to human disease. However, amyloid materials are found extensively in the animal and bacterial world where they stabilize intra‐ and extra‐cellular environments like biofilms or cell envelopes. To date, functional amyloids have largely been studied using optical microscopy techniques in vivo, or after removal from their biological context for higher‐resolution studies in vitro. Furthermore, conventional microscopies only indirectly identify amyloids based on morphology or unspecific amyloid dyes. Here, the high chemical and spatial (≈20 nm) resolution of Infrared Nanospectroscopy (AFM‐IR) to investigate functional amyloid from Escherichia coli (curli), Pseudomonas (Fap), and the Archaea Methanosaeta (MspA) in situ is exploited. It is demonstrated that AFM‐IR identifies amyloid protein within single intact cells through their cross β‐sheet secondary structure, which has a unique spectroscopic signature in the amide I band of protein. Using this approach, nanoscale‐resolved chemical images and spectra of purified curli and Methanosaeta cell wall sheaths are provided. The results highlight significant differences in secondary structure between E. coli cells with and without curli. Taken together, these results suggest that AFM‐IR is a new and powerful label‐free tool for in situ investigations of the biophysical state of functional amyloid and biomolecules in general.
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Functional amyloids are highly organized protein/peptide structures
that
inter alia
promote biofilm formation in different
bacteria. One such example is provided by a family of 20–45
residue-long peptides called phenol-soluble modulins (PSMs) from
Staphylococcus aureus
. External components such as
eukaryotic host proteins, which alter self-assembly of bacterial amyloids,
can affect the biofilm matrix. Here, we studied the effect of the
highly prevalent human plasma protein fibrinogen (Fg) on fibrillation
of PSMs. Fg inhibits or suppresses fibrillation of most PSMs tested
(PSMα1, PSMβ1, and PSMβ2) except for PSMα3,
whose already rapid aggregation is accelerated even further by Fg
but leads to amorphous β-rich aggregates rather than fibrils.
Fg also induces PSMβ2 to form amorphous aggregates and diverts
PSMα1 into off-pathway oligomers which consist of both Fg and
PSMα1 and cannot seed fibrillation. Peptide arrays showed that
Fg bound to the N-terminus of PSMα1, while it bound to the entire
length of PSMα3 (except the C terminus) and to the C-termini
of PSMβ1 and PSMβ2. The latter peptides are all positively
charged, while Fg is negatively charged at physiological pH. The positive
charges complement Fg’s net negative charge of −7.6
at pH 7.4. Fg’s ability to inhibit PSM fibrillation reveals
a potential host-defense mechanism to prevent bacterial biofilm growth
and infections in the human body.
Unlike misfolding in neurodegenerative diseases, aggregation of functional amyloids involved in bacterial biofilm, e.g. CsgA (E. coli) and FapC (Pseudomonas), is carefully regulated. However, it is unclear whether functional aggregation...
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