Comparative Analysis of Type IV Pilin in Desulfuromonadales

Shu, Chuanjun; Xiao, Ke; Yan, Qin; Sun, Xiao

doi:10.3389/fmicb.2016.02080

Cited by 14 publications

(17 citation statements)

References 63 publications

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“…These relationships suggest that aromatic amino acids probably play a decisive role in the magnitude of conductivity. The three aromatic amino acids (F1, F24, and Y27) in each N-terminus of the WT and W51W57 pilin were arranged in a potential electrically conductive geometry in which they were sufficiently close (around 3.5 Å) to account for the experimentally observed metallic-like conductivity of the pili [3,14]. Therefore, the mechanism by which the G. sulfurreducens pilus transfers electrons along pili is attributed, at least in part, to the conjugation of aromatic amino acids (π-π interactions).…”

Section: Discussionmentioning

confidence: 99%

“…The conductivity of the Geobacter sulfurreducens pilus was increased by the genetic substitution of a tryptophan for each of the two aromatic amino acids (+51 tyrosines and +57 phenylalanines) in PilA (W51W57 mutant) [12], since tryptophan facilitates electron transport more effectively than tyrosines or phenylalanines [10,13]. Additionally, other studies also suggested that aromatic amino acids from different subunits were likely packed closely, resulting in π-π interactions that contribute to pili conductivity [3,8,14]. These results indicated that the mechanism for electron transfer in Geobacter has been attributed to the stacking of aromatic amino acids [3,15].…”

Section: Introductionmentioning

confidence: 99%

“…Under this condition, homology modeling and molecular dynamics simulation may be useful to achieve this goal [15]. Furthermore, these techniques have been extensively validated by comparison to experimental results in the past [8,14,15,17].…”

Section: Introductionmentioning

confidence: 99%

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Structural Basis for the Influence of A1, 5A, and W51W57 Mutations on the Conductivity of the Geobacter sulfurreducens Pili

2017

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Abstract:The metallic-like conductivity of the Geobacter sulfurreducens pilus and higher conductivity of its mutants reflected that biological synthesis can be utilized to improve the properties of electrically conductive pili. However, the structural basis for diverse conductivities of nanowires remains uncertain. Here, the impacts of point mutations on the flexibility and stability of pilins were investigated based on molecular dynamics simulations. Structures of the G. sulfurreducens pilus and its mutants were constructed by Rosetta. Details of the structure (i.e., electrostatic properties, helical parameters, residue interaction network, distances between amino acids, and salt bridges) were analyzed by PDB2PQR, Rosetta, RING, PyMOL, and VMD, respectively. Changes in stability, flexibility, residue interaction, and electrostatic properties of subunits directly caused wild-type pilin and its mutants assemble different structures of G. sulfurreducens pili. By comparing the structures of pili with different conductivities, the mechanism by which the G. sulfurreducens pilus transfers electron along pili was attributed, at least in part, to the density of aromatic rings, the distances between neighboring aromatic rings, and the local electrostatic environment around aromatic contacts. These results provide new insight into the potential for the biological synthesis of highly electrically conductive, nontoxic nanowires.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Structural Basis for the Influence of A1, 5A, and W51W57 Mutations on the Conductivity of the Geobacter sulfurreducens Pili

2017

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“…Also, unlike other T4a pilins, the gene encoding the precursor of the short pilins ( pilA‐N ) is organized in an operon with a gene ( pilA‐C ) coding for a hypothetical protein (Reguera et al ., 2005; Holmes et al ., 2016). The PilA‐C protein contains domains that could fold as antiparallel β‐sheets, a structural feature found in the globular head of canonical T4a pilins (Shu et al ., 2016). This has led to the suggestion that the genes encoding PilA‐N (pilin precursor) and PilA‐C (hypothetical protein) originated from the duplication of an ancestral full‐length pilin gene that lost the peptide's carboxyl‐ ( pilA‐N ) or amino‐ ( pilA‐C ) terminal regions (Shu et al ., 2016).…”

Section: Geobacter T4p: a Paradigm In Structure And Functionmentioning

confidence: 99%

“…The PilA‐C protein contains domains that could fold as antiparallel β‐sheets, a structural feature found in the globular head of canonical T4a pilins (Shu et al ., 2016). This has led to the suggestion that the genes encoding PilA‐N (pilin precursor) and PilA‐C (hypothetical protein) originated from the duplication of an ancestral full‐length pilin gene that lost the peptide's carboxyl‐ ( pilA‐N ) or amino‐ ( pilA‐C ) terminal regions (Shu et al ., 2016). The need to respire extracellular electron acceptors may indeed have exerted evolutionary pressure on an ancestral full‐length pilin to lose the more insulating β‐strands and acquire a predominantly α‐helical configuration for increased electronic coupling (Feliciano et al ., 2012).…”

Section: Geobacter T4p: a Paradigm In Structure And Functionmentioning

confidence: 99%

Harnessing the power of microbial nanowires

Reguera

2018

Microbial Biotechnology

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SummaryThe reduction of iron oxide minerals and uranium in model metal reducers in the genus Geobacter is mediated by conductive pili composed primarily of a structurally divergent pilin peptide that is otherwise recognized, processed and assembled in the inner membrane by a conserved Type IVa pilus apparatus. Electronic coupling among the peptides is promoted upon assembly, allowing the discharge of respiratory electrons at rates that greatly exceed the rates of cellular respiration. Harnessing the unique properties of these conductive appendages and their peptide building blocks in metal bioremediation will require understanding of how the pilins assemble to form a protein nanowire with specialized sites for metal immobilization. Also important are insights into how cells assemble the pili to make an electroactive matrix and grow on electrodes as biofilms that harvest electrical currents from the oxidation of waste organic substrates. Genetic engineering shows promise to modulate the properties of the peptide building blocks, protein nanowires and current‐harvesting biofilms for various applications. This minireview discusses what is known about the pilus material properties and reactions they catalyse and how this information can be harnessed in nanotechnology, bioremediation and bioenergy applications.

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Biology and biotechnology of microbial pilus nanowires

Clark

Reguera

2020

Journal of Industrial Microbiology and Biotechnology

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Type IV pili (T4P) are bacterial appendages used for cell adhesion and surface motility. In metal-reducing bacteria in the genus Geobacter, they have the unique property of being conductive and essential to wire cells to extracellular electron acceptors and other cells within biofilms. These electroactive bacteria use a conserved pathway for biological assembly and disassembly of a short and aromatic dense peptide subunit (pilin). The polymerization of the pilins clusters aromatic residues optimally for charge transport and exposes ligands for metal immobilization and reduction. The simple design yet unique functionalities of conductive T4P afford opportunities for the scaled-up production of recombinant pilins and their in vitro assembly into electronic biomaterials of biotechnological interest. This review summarizes current knowledge of conductive T4P biogenesis and functions critical to actualize applications in bioelectronics, bioremediation, and nanotechnology.

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Comparative Analysis of Type IV Pilin in Desulfuromonadales

Cited by 14 publications

References 63 publications

Structural Basis for the Influence of A1, 5A, and W51W57 Mutations on the Conductivity of the Geobacter sulfurreducens Pili

Structural Basis for the Influence of A1, 5A, and W51W57 Mutations on the Conductivity of the Geobacter sulfurreducens Pili

Harnessing the power of microbial nanowires

Biology and biotechnology of microbial pilus nanowires

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