Utilization of banana (Musa sp.) fronds extract as an alternative carbon source for poly(3-hydroxybutyrate) production by Cupriavidus necator H16

2021 ◽  
pp. 102048
Author(s):  
Tze Jian Low ◽  
Sharifah Mohammad ◽  
Kumar Sudesh ◽  
Siti Baidurah
Keyword(s):  
Carbon Source ◽  
Cupriavidus Necator ◽  
Musa Sp ◽  
Cupriavidus Necator H16 ◽  
Alternative Carbon Source

Biosynthesis of poly(3-hydroxybutyrate) (PHB) by Cupriavidus necator H16 from jatropha oil as carbon source

2013 ◽  
Vol 37 (5) ◽  
pp. 943-951 ◽  
Author(s):  
Abeed Fatima Mohidin Batcha ◽  
D. M. Reddy Prasad ◽  
Maksudur R. Khan ◽  
Hamidah Abdullah
Keyword(s):  
Carbon Source ◽  
Cupriavidus Necator ◽  
Jatropha Oil ◽  
Cupriavidus Necator H16

scholarly journals Complete Genome Sequence of Cupriavidus necator H16 (DSM 428)

2019 ◽  
Vol 8 (37) ◽  
Author(s):  
Gareth T. Little ◽  
Muhammad Ehsaan ◽  
Christian Arenas-López ◽  
Kamran Jawed ◽  
Klaus Winzer ◽  
...  
Keyword(s):  
Genome Sequence ◽  
Complete Genome Sequence ◽  
Complete Genome ◽  
Cupriavidus Necator ◽  
Rrna Genes ◽  
Trna Genes ◽  
Protein Coding ◽  
Content Type ◽  
Protein Coding Genes ◽  
Cupriavidus Necator H16

The hydrogen-utilizing strain Cupriavidus necator H16 (DSM 428) was sequenced using a combination of PacBio and Illumina sequencing. Annotation of this strain reveals 6,543 protein-coding genes, 263 pseudogenes, 64 tRNA genes, and 15 rRNA genes.

Use of bacteriostatic antibiotics for the optimization of new media in view of supplementing POME as an alternative carbon source for PHA production - a statistical approach

2019 ◽  
Vol 16 ◽  
pp. 1692-1701
Author(s):  
Ponnaiah Paulraj ◽  
Harvie Anak Shukri ◽  
Vnootheni Nagiah ◽  
Nagaraja Suryadevara ◽  
Balavinayagamani Ganapathy
Keyword(s):  
Carbon Source ◽  
New Media ◽  
Statistical Approach ◽  
Alternative Carbon Source ◽  
Pha Production

scholarly journals Adaptive Laboratory Evolution of Cupriavidus necator H16 for Carbon Co-Utilization with Glycerol

2019 ◽  
Vol 20 (22) ◽  
pp. 5737 ◽  
Author(s):  
Miriam González-Villanueva ◽  
Hemanshi Galaiya ◽  
Paul Staniland ◽  
Jessica Staniland ◽  
Ian Savill ◽  
...  
Keyword(s):  
Type Strain ◽  
Wild Type Strain ◽  
Carbon Sources ◽  
Strain Engineering ◽  
Cupriavidus Necator ◽  
Superior Performance ◽  
Wild Type ◽  
Adaptive Laboratory Evolution ◽  
Laboratory Evolution ◽  
Cupriavidus Necator H16

Cupriavidus necator H16 is a non-pathogenic Gram-negative betaproteobacterium that can utilize a broad range of renewable heterotrophic resources to produce chemicals ranging from polyhydroxybutyrate (biopolymer) to alcohols, alkanes, and alkenes. However, C. necator H16 utilizes carbon sources to different efficiency, for example its growth in glycerol is 11.4 times slower than a favorable substrate like gluconate. This work used adaptive laboratory evolution to enhance the glycerol assimilation in C. necator H16 and identified a variant (v6C6) that can co-utilize gluconate and glycerol. The v6C6 variant has a specific growth rate in glycerol 9.5 times faster than the wild-type strain and grows faster in mixed gluconate–glycerol carbon sources compared to gluconate alone. It also accumulated more PHB when cultivated in glycerol medium compared to gluconate medium while the inverse is true for the wild-type strain. Through genome sequencing and expression studies, glycerol kinase was identified as the key enzyme for its improved glycerol utilization. The superior performance of v6C6 in assimilating pure glycerol was extended to crude glycerol (sweetwater) from an industrial fat splitting process. These results highlight the robustness of adaptive laboratory evolution for strain engineering and the versatility and potential of C. necator H16 for industrial waste glycerol valorization.

scholarly journals Cupriavidus necator H16 Uses Flavocytochrome c Sulfide Dehydrogenase To Oxidize Self-Produced and Added Sulfide

2017 ◽  
Vol 83 (22) ◽  
Author(s):  
Chuanjuan Lü ◽  
Yongzhen Xia ◽  
Daixi Liu ◽  
Rui Zhao ◽  
Rui Gao ◽  
...  
Keyword(s):  
Gas Phase ◽  
Heterotrophic Bacteria ◽  
Sulfide Oxidation ◽  
Cupriavidus Necator ◽  
Content Type ◽  
Sulfide:Quinone Oxidoreductase ◽  
Transport Chain ◽  
Genes Encoding ◽  
Cupriavidus Necator H16 ◽  
Chemolithotrophic Bacteria

ABSTRACT Production of sulfide (H2S, HS−, and S2−) by heterotrophic bacteria during aerobic growth is a common phenomenon. Some bacteria with sulfide:quinone oxidoreductase (SQR) and persulfide dioxygenase (PDO) can oxidize self-produced sulfide to sulfite and thiosulfate, but other bacteria without these enzymes release sulfide into the medium, from which H2S can volatilize into the gas phase. Here, we report that Cupriavidus necator H16, with the fccA and fccB genes encoding flavocytochrome c sulfide dehydrogenases (FCSDs), also oxidized self-produced H2S. A mutant in which fccA and fccB were deleted accumulated and released H2S. When fccA and fccB were expressed in Pseudomonas aeruginosa strain Pa3K with deletions of its sqr and pdo genes, the recombinant rapidly oxidized sulfide to sulfane sulfur. When PDO was also cloned into the recombinant, the recombinant with both FCSD and PDO oxidized sulfide to sulfite and thiosulfate. Thus, the proposed pathway is similar to the pathway catalyzed by SQR and PDO, in which FCSD oxidizes sulfide to polysulfide, polysulfide spontaneously reacts with reduced glutathione (GSH) to produce glutathione persulfide (GSSH), and PDO oxidizes GSSH to sulfite, which chemically reacts with polysulfide to produce thiosulfate. About 20.6% of sequenced bacterial genomes contain SQR, and only 3.9% contain FCSD. This is not a surprise, since SQR is more efficient in conserving energy because it passes electrons from sulfide oxidation into the electron transport chain at the quinone level, while FCSD passes electrons to cytochrome c. The transport of electrons from the latter to O2 conserves less energy. FCSDs are grouped into three subgroups, well conserved at the taxonomic level. Thus, our data show the diversity in sulfide oxidation by heterotrophic bacteria. IMPORTANCE Heterotrophic bacteria with SQR and PDO can oxidize self-produced sulfide and do not release H2S into the gas phase. C. necator H16 has FCSD but not SQR, and it does not release H2S. We confirmed that the bacterium used FCSD for the oxidation of self-produced sulfide. The bacterium also oxidized added sulfide. The common presence of SQRs, FCSDs, and PDOs in heterotrophic bacteria suggests the significant role of heterotrophic bacteria in sulfide oxidation, participating in sulfur biogeochemical cycling. Further, FCSDs have been identified in anaerobic photosynthetic bacteria and chemolithotrophic bacteria, but their physiological roles are unknown. We showed that heterotrophic bacteria use FCSDs to oxidize self-produced sulfide and extraneous sulfide, and they may be used for H2S bioremediation.

Recycling of Bakery Waste as an Alternative Carbon Source for Rhamnolipid Biosurfactant Production

2018 ◽  
Vol 22 (2) ◽  
pp. 373-384 ◽  
Author(s):  
Kaustuvmani Patowary ◽  
Moonjit Das ◽  
Rupshikha Patowary ◽  
Mohan Chandra Kalita ◽  
Suresh Deka
Keyword(s):  
Carbon Source ◽  
Biosurfactant Production ◽  
Alternative Carbon Source ◽  
Rhamnolipid Biosurfactant

Transformation of Alachlor by Microbial Communities

Weed Science ◽  
1990 ◽  
Vol 38 (4-5) ◽  
pp. 416-420 ◽  
Author(s):  
Hone L. Sun ◽  
Thomas J. Sheets ◽  
Frederick T. Corbin
Keyword(s):  
Carbon Source ◽  
Growth Medium ◽  
Basal Medium ◽  
Sole Source ◽  
Ring Cleavage ◽  
Side Chain ◽  
Microbial Culture ◽  
Mixed Microbial Culture ◽  
Alternative Carbon Source ◽  
Thin Layer Chromatographic Analysis

A mixed microbial culture able to transform alachlor at a concentration of 50 μg ml-1was obtained from alachlor-treated soil after an enrichment period of 84 days. The microbial community was composed of seven strains of bacteria. No single isolate was able to utilize alachlor as a sole source of carbon. There was no alachlor left in the enriched culture after a 14-day incubation, but only 12% of the14C-ring-labeled alachlor was converted to14CO2through ring cleavage during 14 days in the basal medium amended with alachlor as a sole carbon source. The presence of sucrose as an alternative carbon source decreased the mineralization potential of the enriched culture, but sucrose increased the mineralizing ability of a three-member mixed culture. Thin-layer chromatographic analysis showed that there were four unidentified metabolites of alachlor produced by the enriched culture. Sucrose decreased the amount of two of the four metabolites. The absence of a noticeable decline in radioactivity beyond the initial 12% suggested that the side chain of alachlor was utilized as carbon source by the enriched culture. Little difference in radioactivity between growth medium and cell-free supernatant of the growth medium suggested that the carbon in the ring was not incorporated into the cells of the degrading microorganisms.

scholarly journals Poly-β-Hydroxybutyrate (PHB) Production By Amylolytic Micrococcus sp. PG1 Isolated From Soil Polluted Arrowroot Starch Waste

2015 ◽  
Vol 19 (1) ◽  
pp. 56
Author(s):  
Sebastian Margino ◽  
Erni Martani ◽  
Andriessa Prameswara
Keyword(s):  
Carbon Source ◽  
Internal Energy ◽  
Organic Polymer ◽  
Ftir Analysis ◽  
Phb Production ◽  
Alternative Carbon Source ◽  
Arrowroot Starch ◽  
Physiological Characters

Poly-β-hydroxybutyrate (PHB) production from amylolytic Micrococcus sp. PG1. Poly-β-hydroxybutyrate(PHB) is an organic polymer, which synthesized by many bacteria and serves as internal energy. PHB ispotential as future bioplastic but its price is very expensive due to glucose usage in PHB industry. Thedevelopment of PHB production using starch as an alternative carbon source has been conducted to reducethe dependence of glucose in PHB production. In this study, amylolytic bacteria from arrowroot processingsite were screened quantitavely based on amylase specifi c activity and PHB producing ability. The result of thestudy showed that among of 24 amylolytic isolates, 12 isolates of them were able to accumulate PHB rangedfrom 0,68-11,65% (g PHB/g cdw). The highest PHB production from substrate arrowroot starch was PG1 andafter optimization resulted in increasing of PHB production up to 16,8% (g PHB/g cdw) 40 hours incubationtime. Based on morphological, biochemical and physiological characters, the PG1 isolate was identifi ed asMicrococcus sp. PG1. Result of the FTIR analysis of produced polymer by Micrococcus sp. PG1 was indicatedas poly-β- hydroxybutyrate (PHB)

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