Dissecting the Polyhydroxyalkanoate-Binding Domain of the PhaF Phasin: Rational Design of a Minimized Affinity Tag

Mato, Aranzazu; Blanco, Francisco Garcı́a; Maestro, Beatríz; Sanz, Jesús M.; Pérez‐Gil, Jesús; Prieto, María Auxiliadora

doi:10.1128/aem.00570-20

Cited by 9 publications

(27 citation statements)

References 55 publications

(79 reference statements)

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“…However, a concentration-dependent elution was observed for Cpl-711 upon treatment with Triton X-100, while the amount of M711 retained in the NPs remained almost unchanged (at ≈ 80% of total protein) (Fig. 4), in agreement with previous results (14). Taking this into account, a possible binding scheme could be the soft and hard corona model (42), in which proteins bound to the PHA NPs via the MinP tag are tightly bound to the NPs while those bound via unspeci c interactions of Cpl-711 are loosely attached.…”

Section: M711-nps Physicochemical Characterizationsupporting

confidence: 92%

“…For instance, a small peptide of 48 amino acids, MinP, was designed based on the binding moiety of phasin PhaF from Pseudomonas putida. MinP maintains the global binding capability of the whole protein (14). Phasin-mediated immobilization has been demonstrated both in vivo, where the PHA synthesis, protein production, and binding to the polymer take place simultaneously within the cytoplasm of the bacterial host; and in vitro, where proteins are immobilized onto previously formulated materials (14)(15)(16).…”

Section: Introductionmentioning

confidence: 99%

“…MinP maintains the global binding capability of the whole protein (14). Phasin-mediated immobilization has been demonstrated both in vivo, where the PHA synthesis, protein production, and binding to the polymer take place simultaneously within the cytoplasm of the bacterial host; and in vitro, where proteins are immobilized onto previously formulated materials (14)(15)(16). The in vitro approach is more suitable to ensure endotoxin removal from both the polymer and the protein when targeting biomedical applications (17), as well as to tightly control protein load.…”

Section: Introductionmentioning

confidence: 99%

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Enzybiotic-mediated antimicrobial functionalization of polyhydroxyalkanoate nanoparticles

Blanco

Vázquez

Hernández‐Arriaga

et al. 2023

Preprint

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Background: Increasing antibiotic resistance is depleting the available arsenal of these conventional antimicrobials, thus making the development of alternative antibacterial agents a priority for biomedical research. This is the case for Streptococcus penumoniae, a severe respiratory pathogen which, upon colonization of the lung alveoli below the lung surfactant layer (LS), causes community-acquired pneumonia. One of the alternative approaches is the use of enzybiotics, phage-encoded peptidoglycan hydrolases that degrade the bacterial cell wall, thus leading to their death by osmotic shock. To meet therapeutic parameters such as longer in vivo half-life or targeted activity release, the design of enzybiotic formulations is required. Polyhydroxyalkanoates (PHAs) nanoparticles (NPs), present some ideal properties as biomedical nanocarriers such as their inherent biocompatibility, biodegradability, and ability to be vehiculized through hydrophobic barriers, including the lung surfactant (LS). Here, we develop PHA NPs as a platform for the immobilization of enzybiotics against S. pneumoniae via a minimal PHA affinity tag. Results In this study, we tagged the Cpl-711 enzybiotic, which specifically targets S. pneumoniae, with the minimal PHA affinity peptide MinP, resulting in the M711 protein. Then, a PHA nanoparticulate suspension with adequate physicochemical properties for pulmonary delivery was formulated, and M711 was immobilized on their surface. Finally, we assessed the antipneumococcal activity of the nanosystem against planktonic and sessile forms of the pathogen. The resulting pioneer nanosystem displayed sustained antimicrobial activity against free cells, and effectively disaggregated S. pneumoniae biofilms. Conclusions Our findings indicate tag-mediated immobilization of enzybiotics as an effective method for the antimicrobial functionalization of PHA NPs. This straightforward approach may be extrapolated to other enzybiotics (or cargo proteins) with other specificities, highlighting the versatility of the system

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Section: M711-nps Physicochemical Characterizationsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Enzybiotic-mediated antimicrobial functionalization of polyhydroxyalkanoate nanoparticles

Blanco

Vázquez

Hernández‐Arriaga

et al. 2023

Preprint

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“…Its versatility helps in the synthesis and depolymerizing of PHA molecules. Phasins are of high importance especially in biomedical applications because of their inherent ability of strong binding affinity to protein tags and also to PHA molecules, making them easily engineerable and helping in producing and performing biotechnological products for in vitro experiments [ 9 ]. Phasin protein is an important factor required to produce the nano sized PHA.…”

Section: Pha: a Biodegradable Microbial Biopolymer Synthesized As mentioning

confidence: 99%

Microbial Polyhydroxyalkanoates Granules: An Approach Targeting Biopolymer for Medical Applications and Developing Bone Scaffolds

et al. 2021

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Microbial polyhydroxyalkanoates (PHA) are proteinaceous storage granules ranging from 100 nm to 500 nm. Bacillus sp. serve as unique bioplastic sources of short-chain length and medium-chain length PHA showcasing properties such as biodegradability, thermostability, and appreciable mechanical strength. The PHA can be enhanced by adding functional groups to make it a more industrially useful biomaterial. PHA blends with hydroxyapatite to form nanocomposites with desirable features of compressibility. The reinforced matrices result in nanocomposites that possess significantly improved mechanical and thermal properties both in solid and melt states along with enhanced gas barrier properties compared to conventional filler composites. These superior qualities extend the polymeric composites’ applications to aggressive environments where the neat polymers are likely to fail. This nanocomposite can be used in different industries as nanofillers, drug carriers for packaging essential hormones and microcapsules, etc. For fabricating a bone scaffold, electrospun nanofibrils made from biocomposite of hydroxyapatite and polyhydroxy butyrate, a form of PHA, can be incorporated with the targeted tissue. The other methods for making a polymer scaffold, includes gas foaming, lyophilization, sol–gel, and solvent casting method. In this review, PHA as a sustainable eco-friendly NextGen biomaterial from bacterial sources especially Bacillus cereus, and its application for fabricating bone scaffold using different strategies for bone regeneration have been discussed.

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“…Por tanto, la maquinaria metabólica involucrada en la producción del PHA implica una importante conexión de la sintasa y depolimerasa con otras rutas centrales y periféricas del metabolismo del carbono bacteriano, que son las que generan el monómero que va a formar parte del bioplástico. Gracias a la biología de sistemas, en la actualidad se están utilizando estrategias holísticas tanto para abordar su estudio como para desarrollar nuevos materiales con nuevas aplicaciones mediante ingeniería metabólica combinada con la biología sintética (4)(5)(6). En este sentido, merece la pena mencionar el bioplástico antibacteriano PHACOS que fue generado mediante ingeniería metabólica en la bacteria P. putida.…”

Section: Biology-based Plastics or Bioplastics Are Becoming An Alterunclassified

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2020

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Dissecting the Polyhydroxyalkanoate-Binding Domain of the PhaF Phasin: Rational Design of a Minimized Affinity Tag

Cited by 9 publications

References 55 publications

Enzybiotic-mediated antimicrobial functionalization of polyhydroxyalkanoate nanoparticles

Enzybiotic-mediated antimicrobial functionalization of polyhydroxyalkanoate nanoparticles

Microbial Polyhydroxyalkanoates Granules: An Approach Targeting Biopolymer for Medical Applications and Developing Bone Scaffolds

Los bioplásticos, ¿qué son? ¿cuántos hay? ¿cómo se producen?

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