Beneficial characteristics of mechanically functional amyloid fibrils evolutionarily preserved in natural adhesives

Mostaert, Anika S.; Jarvis, Suzanne P.

doi:10.1088/0957-4484/18/4/044010

Cited by 39 publications

(47 citation statements)

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“…Consequently, many naturally occurring bioadhesives are unusually tough by synthetic adhesive standards (Groshong 2007). In fact, sacrificial bonds are abundant in nature and can be found in many biomaterials such as bone (Smith et al 1999;Fantner et al 2005), spider silk (Becker et al 2003), natural adhesives from algae (Callow et al 2000;Mostaert et al 2006;Mostaert & Jarvis 2007), diatom mucilage (Higgins et al 2003;Dugdale et al 2005Dugdale et al , 2006a and adult barnacle cement (Sun et al 2004). In this paper, the morphology and nanomechanical properties of cyprid footprints were investigated with AFM.…”

Section: Introductionmentioning

confidence: 99%

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Phang

Aldred

Ling

et al. 2009

J. R. Soc. Interface.

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Barnacles are a major biofouler of man-made underwater structures. Prior to settlement, cypris larvae explore surfaces by reversible attachment effected by a 'temporary adhesive'. During this exploratory behaviour, cyprids deposit proteinaceous 'footprints' of a putatively adhesive material. In this study, footprints deposited by Balanus amphitrite cyprids were probed by atomic force microscopy (AFM) in artificial sea water (ASW) on silane-modified glass surfaces. AFM images obtained in air yielded better resolution than in ASW and revealed the fibrillar nature of the secretion, suggesting that the deposits were composed of single proteinaceous nanofibrils, or bundles of fibrils. The force curves generated in pulloff force experiments in sea water consisted of regions of gradually increasing force, separated by sharp drops in extension force manifesting a characteristic saw-tooth appearance. Following the relaxation of fibrils stretched to high strains, force -distance curves in reverse stretching experiments could be described by the entropic elasticity model of a polymer chain. When subjected to relaxation exceeding 500 ms, extended footprint proteins refolded, and again showed saw-tooth unfolding peaks in subsequent force cycles. Observed rupture and hysteresis behaviour were explained by the 'sacrificial bond' model. Longer durations of relaxation (.5 s) allowed more sacrificial bond reformation and contributed to enhanced energy dissipation (higher toughness). The persistence length for the protein chains (L P ) was obtained. At high elongation, following repeated stretching up to increasing upper strain limits, footprint proteins detached at total stretched length of 10 mm.

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Section: Introductionmentioning

confidence: 99%

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Phang

Aldred

Ling

et al. 2009

J. R. Soc. Interface.

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“…This was achieved in the AFM manipulation of amyloid fibrils formed from an 11 amino acid peptide segments of transthyratin, TTR Mostaert & Jarvis, 2007). When the force spectroscopy was conducted on TTR fibrils, similar plateaus were observed, corresponding to the peeling off of -sheets from the fibrils; in addition, force curves with sawtooth pattern were also captured (Figure 7), which were attributed to the successive unraveling of the peptide molecules from the fibril bulk.…”

Section: Applicationsmentioning

confidence: 85%

Nanomechanics of Amyloid Materials Studied by Atomic Force Microscopy

Zeng¹,

Duan²,

Besenbacher³

et al. 2012

Atomic Force Microscopy Investigations Into Biology - From Cell to Protein

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“…This sawtooth response has a much smaller persistence length than on the blue retraction part of the curve because in this case the ß-sheet is being unravelled as it is pushed into the adhesive matrix (in parallel with the additional stiffness of the adhesive matrix). Amyloid fibrils also readily self-assemble, thus constituting a self-healing material [9].Using a combination of AFM and complementary techniques, we have now identified amyloid structures in the permanent adhesive of five species of algae and one temporary adhesive from an invertebrate organism, leading us to postulate that physiological amyloid may occur far more commonly in nature than previously thought. To a large extent it may have remained undetected due to its lack of dependence on amino acid sequence and the difficulties associated with analyzing the composition of amyloid fibrils that are insoluble and resistant to proteolysis.…”

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confidence: 87%

“…Additional beneficial mechanical characteristics of amyloid arise due to the high degree of rotational symmetry of the fibrils. This means that any force applied tangential to the direction of the fibril will have the same beneficial unfolding characteristics [9]. An example of this can be observed on the red approach curve in figure 4.…”

mentioning

confidence: 90%

“…It is apparent from our work on amyloid-like fibrils that there exist qualitative similarities and quantitative differences between different fibrils where the maximum force and number of sawtooth peaks can vary considerably. However, force-extension curves often exhibit either sawtooth or plateau force responses under a tensile load [7].There has been considerable interest in the mechanical properties of amyloid fibrils [8] since the implication of the amyloid fold in spider silk, but our recent work provides the first experimental evidence explaining why this structure has superior mechanical characteristics based on "hidden length" and "sacrificial bonds" [5,7,9]. Additional beneficial mechanical characteristics of amyloid arise due to the high degree of rotational symmetry of the fibrils.…”

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confidence: 97%

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Functional Amyloid

Jarvis¹,

Mostaert²

2007

I&M

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Amyloid is notorious for its association with a range of debilitating and incurable human diseases. However, evidence is now emerging that the amyloid fold may be functional and utilized by a broad range of organisms. Atomic force microscopy has helped in the identification of amyloid in the natural adhesives of biofouling terrestrial algae that attach to a range of natural and man-made surfaces. AFM is now being used to pull apart a variety of amyloid fibrils in order to elucidate their structure.is because in their misfolded state they can readily aggregate into highly ordered amyloid fibrils. These fibrils are stable and insoluble, usually consisting of multiple levels of structure of which intermo- What Is Amyloid?Over the last decade it has become evident that misfolded proteins are of huge biological and medical importance. This l. to. r.: Prof. Suzanne P. Jarvis and Dr. Anika S. Mostaert Keywords:Nonpathogenic amyloid, physiological amyloid, force-extension curve, mechanical function, atomic force microscopy lecular β-sheets are a generic component. These sheets are the building blocks of protofilaments that can be several nanometres in diameter, and themselves make up the mature fibrils like strands of a rope. A variety of interactions have been implicated in amyloid structures, including strong hydrophobic interactions within the core of the fibril and interior salt-bridges. Amyloid, amyloid-like fibrils (the latter being defined S c a n n i n g S e c t i o n as "model" amyloid fibrils formed in vitro) and their precursor oligomers have been studied extensively due to the apparently central role of amyloid formation in diseases such as Alzheimer's, Parkinson's, type II diabetes and Creutzfield-Jacob disease. Recently, the possible role of amyloid aggregation in a far broader range of degenerative diseases has been highlighted, and it has been suggested that amyloidosis could be a universal disease of aging [1]. Indeed, there is increasing experimental evidence that the amyloid state is a generic protein fold [2] not dependent on amino acid sequence, but often depends on environmental conditions. It could thus be inferred that given sufficient time any proteinaceous part of any organism may suffer the consequences of pathogenic amyloid formation. It is therefore particularly important to understand what triggers and controls amyloid formation, the mechanism of toxicity and how this may be prevented. Nonpathogenic AmyloidSurprisingly, physiological amyloid has been found in a diverse range of organisms from bacteria [3] to mammals [4] in recent years. Due to the very repetitive nature of the amyloid quarternary structure, we have been able to apply AFM to pinpoint natural materials where the amyloid structure may occur. Pulling apart any repetitive structure is readily apparent in the force-extension curves produced when an AFM tip binds (usually non-specifically) to the sample surface, and the substrate and tip are moved gradually apart, thus unravelling the structure until it either breaks or detaches fr...

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Beneficial characteristics of mechanically functional amyloid fibrils evolutionarily preserved in natural adhesives

Cited by 39 publications

References 23 publications

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale

Nanomechanics of Amyloid Materials Studied by Atomic Force Microscopy

Functional Amyloid

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