Forest soil bacteria able to produce homo and copolymers of polyhydroxyalkanoates from several pure and waste carbon sources

Clifton-García, Berenice; González-Reynoso, Orfil; Robledo‐Ortíz, Jorge R.; Villafaña-Rojas, Juan Villafaña-RojasJ.; González‐García, Yolanda

doi:10.1111/lam.13272

Cited by 13 publications

(5 citation statements)

References 39 publications

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“…Polyhydroxyalkanoates (PHA) are biopolyesters synthesized via fermentation from bacteria that intracellularly accumulate the biopolymer under nutritional stress conditions 1–3 . The most common PHA are polyhydroxybutyrate (PHB) and the copolymer with polyhydroxyvalerate (PHBV), which have similar physico‐mechanical properties than petroleum‐based polymers such as polypropylene 4 . They also have good moisture resistance and good barrier properties to gases 3 .…”

Section: Introductionmentioning

confidence: 99%

Biodegradability and improved mechanical performance of polyhydroxyalkanoates/agave fiber biocomposites compatibilized by different strategies

Gallardo‐Cervantes

González‐García

Pérez‐Fonseca

et al. 2020

J of Applied Polymer Sci

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In this work, biocomposites made of polyhydroxyalkanoates (PHA) with natural fibers were produced via compression molding. In particular, polyhydroxybutyrate (PHB) and polyhydroxybutyrate‐co‐hydroxyvalerate (PHBV) were reinforced with 20 wt% of agave fibers. Different compatibilization strategies were investigated to improve the fiber‐matrix interaction: fiber surface treatment in PHA solution, fiber surface treatment in maleated PHA solution, fiber propionylation, and extrusion with maleated PHA. The biocomposites were characterized in terms of morphology, mechanical properties, water absorption, and biodegradability by CO2production tracking. In general, fiber propionylation was the best strategy for mechanical properties enhancement and water uptake decreasing. Biocomposites with propionylated fibers showed improved flexural strength (170% for PHB and 84% for PHBV). The flexural modulus was also enhanced with propionylated fibers up to 19% and 18% compared to uncompatibilized biocomposites (PHB and PHBV, respectively). Tensile strength increased by 16% (PHB) and 14% (PHBV), and the water absorption was reduced using propionylated fibers going from 6.6% to 4.4% compared with biocomposites with untreated fibers. Most importantly, the impact strength was also improved for all biocomposites by up to 96% compared with the neat PHA matrices. Finally, it was found that the compatibilization did not negatively modify the PHA biodegradability.

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Section: Introductionmentioning

confidence: 99%

Biodegradability and improved mechanical performance of polyhydroxyalkanoates/agave fiber biocomposites compatibilized by different strategies

Gallardo‐Cervantes

González‐García

Pérez‐Fonseca

et al. 2020

J of Applied Polymer Sci

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“…The dominant genera previously described as PHA-accumulating bacteria were Acidovorax [ 72 ], Acinetobacter [ 73 ], Alkaliphilus [ 74 ], Azospirillum [ 11 ], Calothrix [ 13 ], Comamonas [ 75 ], Corynebacterium [ 76 ], Gemmobacter [ 77 ], Leifsonia [ 78 ], Lysobacter [ 79 ], Novosphingobium [ 80 ], Oscillochloris [ 81 ], Pandoraea [ 82 ], Polynucleobacter [ 83 ], Pseudomonas [ 84 ], Rhizobium [ 85 ], Roseiflexus [ 86 ], Stenotrophomonas [ 87 ], and Tsukamurella [ 55 ]. Moreover, species of the diazotrophic genus Niveispirillum were formerly classified within the well-known PHA-accumulating genus Azospirillum [ 88 ].…”

Section: Resultsmentioning

confidence: 99%

Dynamics of PHA-Accumulating Bacterial Communities Fed with Lipid-Rich Liquid Effluents from Fish-Canning Industries

et al. 2022

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The biosynthesis of polyhydroxyalkanoates (PHAs) from industrial wastes by mixed microbial cultures (MMCs) enriched in PHA-accumulating bacteria is a promising technology to replace petroleum-based plastics. However, the populations’ dynamics in the PHA-accumulating MMCs are not well known. Therefore, the main objective of this study was to address the shifts in the size and structure of the bacterial communities in two lab-scale sequencing batch reactors (SBRs) fed with fish-canning effluents and operated under non-saline (SBR-N, 0.5 g NaCl/L) or saline (SBR-S, 10 g NaCl/L) conditions, by using a combination of quantitative PCR and Illumina sequencing of bacterial 16S rRNA genes. A double growth limitation (DGL) strategy, in which nitrogen availability was limited and uncoupled to carbon addition, strongly modulated the relative abundances of the PHA-accumulating bacteria, leading to an increase in the accumulation of PHAs, independently of the saline conditions (average 9.04 wt% and 11.69 wt%, maximum yields 22.03 wt% and 26.33% SBR-N and SBR-S, respectively). On the other hand, no correlations were found among the PHAs accumulation yields and the absolute abundances of total Bacteria, which decreased through time in the SBR-N and did not present statistical differences in the SBR-S. Acinetobacter, Calothrix, Dyella, Flavobacterium, Novosphingobium, Qipengyuania, and Tsukamurella were key PHA-accumulating genera in both SBRs under the DGL strategy, which was revealed as a successful tool to obtain a PHA-enriched MMC using fish-canning effluents.

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“…Por lo tanto, la limitación combinada de nutrientes pudo activar varios mecanismos de acumulación. Sin embargo, no se detectó la producción de biopolímero a partir de xilosa, lo cual es común ya que han sido reportadas pocas bacterias son capaces de crecer y producir el polímero a partir de este azúcar (Clifton et al, 2020). En cuanto al porcentaje de acumulación de polímero alcanzado en este estudio, está dentro del rango de muchas cepas nativas cultivadas bajo condiciones sin optimizar como en este caso (Clifton et al, 2020).…”

Section: Discusionesunclassified

“…Sin embargo, no se detectó la producción de biopolímero a partir de xilosa, lo cual es común ya que han sido reportadas pocas bacterias son capaces de crecer y producir el polímero a partir de este azúcar (Clifton et al, 2020). En cuanto al porcentaje de acumulación de polímero alcanzado en este estudio, está dentro del rango de muchas cepas nativas cultivadas bajo condiciones sin optimizar como en este caso (Clifton et al, 2020). Por lo tanto, sería de importancia seguir investigando el efecto de diferentes factores nutricionales y ambientales, así como estrategias de cultivo para optimizar la acumulación de PHB.…”

Section: Discusionesunclassified

Effect of culture medium composition on the growth and biopolyesters production by the marine bacterium Saccharophagus degradans

Enríquez-López,

Robledo-Ortíz,

González-Reynoso

et al. 2023

Mexjbiotechnol

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The production of biomass and biopolyesters (polyhydroxyalkanoates) by the marine bacterium Saccharophagus degradans from: glucose, starch, glucosamine, and xylose were studied. The effect of yeast extract, trace elements, vitamins, and initial concentration of each carbon source on biomass production was evaluated. The addition of yeast extract, together with trace elements, increased the biomass production by 5-fold, obtaining the maximum values when using an initial substrate concentration of 20 g/L for: starch, 8.61; glucosamine, 7.06; and xylose, 4.47 (g dry cell weight/ L). From glucose at 40 g/L the maximum biomass production was 9.07 g/L. Next, the biopolymer production under nutrient-limiting conditions (by N, P, S and Mg) was investigated, as well as the ability of S. degradans to produce copolymers from precursors. The biopolyester produced in all cases was poly(3-hydroxybutyrate) (PHB). Different accumulation percentages (g PHB/100 g biomass) were achieved depending on the carbon source used: glucose, 27.72; starch, 18.11; glucosamine 3.33; there was not biopolymer accumulated from xylose. Finally, the PHB produced from each carbohydrate was characterized, presenting molecular weights between 53 and 58 KDa, and fusion temperatures between 164 and 174°C.

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Forest soil bacteria able to produce homo and copolymers of polyhydroxyalkanoates from several pure and waste carbon sources

Cited by 13 publications

References 39 publications

Biodegradability and improved mechanical performance of polyhydroxyalkanoates/agave fiber biocomposites compatibilized by different strategies

Biodegradability and improved mechanical performance of polyhydroxyalkanoates/agave fiber biocomposites compatibilized by different strategies

Dynamics of PHA-Accumulating Bacterial Communities Fed with Lipid-Rich Liquid Effluents from Fish-Canning Industries

Effect of culture medium composition on the growth and biopolyesters production by the marine bacterium Saccharophagus degradans

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