Efficient simultaneous production of extracellular polyol esters of fatty acids and intracellular lipids from inulin by a deep-sea yeast Rhodotorula paludigena P4R5

Wang, Mengqi; Mao, Weian; Wang, Xiaoxiang; Li, Fengyi; Wang, Jiming; Chi, Zhe; Liu, Guanglei

doi:10.1186/s12934-019-1200-3

Cited by 16 publications

(44 citation statements)

References 37 publications

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“…It is a member of glycoside hydrolase family 32 (GH32) with a size of 71.24 kDa and harbors conserved protein sequence motifs with the catalytic triad ( 192 D-316 D-366 E). Previous studies reported this enzyme also in other fungi identifying the well-known sequence signatures and catalytic triad of exo-inulinases [23][24][25]. In conclusion, our results suggest that the fungal mannitol pathway and exo-inulinase enzyme hold key roles for PEFA production in Rhodotorula strains.…”

Section: Biosynthetic Potential Of the Deep-sea R Mucilaginosa 50-3-supporting

confidence: 74%

“…The knowledge on the PEFA biosynthetic pathway and its components is limited. A recent study suggested that an exo-inulinase enzyme holds key roles in the PEFA production via a mannitol biosynthesis pathway using the polysaccharide inulin as the carbon source [ 23 ]. Hence, we used the recently identified protein sequence of exo-inulinase enzyme from R. paludigena P4R5 [ 23 ] to detect enzymes in the marine R. mucilaginosa 50-3-19/20B genome aided by BLAST suite [ 22 ].…”

Section: Resultsmentioning

confidence: 99%

“…A recent study suggested that an exo-inulinase enzyme holds key roles in the PEFA production via a mannitol biosynthesis pathway using the polysaccharide inulin as the carbon source [ 23 ]. Hence, we used the recently identified protein sequence of exo-inulinase enzyme from R. paludigena P4R5 [ 23 ] to detect enzymes in the marine R. mucilaginosa 50-3-19/20B genome aided by BLAST suite [ 22 ]. Herein, we report the existence of an exo-inulinase gene (as g1629.t1) and its genomic locus including its flanking genes deduced from the marine R. mucilaginosa 50-3-19/20B genome ( Table S2 ).…”

Section: Resultsmentioning

confidence: 99%

“…This result demonstrates that the exo-inulinase enzyme (g1629.t1) has orthologs in several fungi with annotation as either GH32 protein or β -fructofuranosidase ( Table S3 ). This putative exo-inulinase harbors known conserved motifs of exo-inulinases [ 23 , 24 , 25 ] as 189 FMNDPNGC 189 , 209 Q, 250 FS 251 , 315 RDP 317 , and 366 ECP 368 ( Figure 3 , marked by stars, numbering according to amino acid numbering of exo-inulinase enzyme of marine R. mucilaginosa ). Out of these residues, three amino acids 192 D- 316 D- 366 E form the conserved catalytic triad (marked by red stars in Figure 3 ) with 192 D serving as the nucleophile, 316 D as a stabiliser of the transient state and 366 E as the acid-base catalyst.…”

Section: Resultsmentioning

confidence: 99%

“…It also possesses a disordered region in the N-terminal region (1-159 residues). (B) Protein sequence alignment of exo-inulinase enzymes of marine R. mucilaginosa (g1629.t1) and R. paludigena strain P4R5 (Genbank: AZR37516.1,[23]) illustrating the presence of conserved motifs of exo-inulinases as 189 FMNDPNGC 189 ,209…”

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confidence: 99%

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Genomics- and Metabolomics-Based Investigation of the Deep-Sea Sediment-Derived Yeast, Rhodotorula mucilaginosa 50-3-19/20B

et al. 2020

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Red yeasts of the genus Rhodotorula are of great interest to the biotechnological industry due to their ability to produce valuable natural products, such as lipids and carotenoids with potential applications as surfactants, food additives, and pharmaceuticals. Herein, we explored the biosynthetic potential of R. mucilaginosa 50-3-19/20B collected from the Mid-Atlantic Ridge using modern genomics and untargeted metabolomics tools. R. mucilaginosa 50-3-19/20B exhibited anticancer activity when grown on PDA medium, while antimicrobial activity was observed when cultured on WSP-30 medium. Applying the bioactive molecular networking approach, the anticancer activity was linked to glycolipids, namely polyol esters of fatty acid (PEFA) derivatives. We purified four PEFAs (1–4) and the known methyl-2-hydroxy-3-(1H-indol-2-yl)propanoate (5). Their structures were deduced from NMR and HR-MS/MS spectra, but 1–5 showed no anticancer activity in their pure form. Illumina-based genome sequencing, de novo assembly and standard biosynthetic gene cluster (BGC) analyses were used to illustrate key components of the PEFA biosynthetic pathway. The fatty acid producing BGC3 was identified to be capable of producing precursors of PEFAs. Some Rhodotorula strains are able to convert inulin into high-yielding PEFA and cell lipid using a native exo-inulinase enzyme. The genomic locus for an exo-inulinase enzyme (g1629.t1), which plays an instrumental role in the PEFA production via the mannitol biosynthesis pathway, was identified. This is the first untargeted metabolomics study on R. mucilaginosa providing new genomic insights into PEFA biosynthesis.

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Section: Biosynthetic Potential Of the Deep-sea R Mucilaginosa 50-3-supporting

confidence: 74%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

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Genomics- and Metabolomics-Based Investigation of the Deep-Sea Sediment-Derived Yeast, Rhodotorula mucilaginosa 50-3-19/20B

et al. 2020

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Fungal biosurfactants, from nature to biotechnological product: bioprospection, production and potential applications

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Giachini

et al. 2021

Bioprocess Biosyst Eng

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Biosurfactants are in demand by the global market as natural commodities that can be added to commercial products or use in environmental applications. These biomolecules reduce the surface/interfacial tension between fluid phases and exhibit superior stability to chemical surfactants under different physico-chemical conditions. Biotechnological production of biosurfactants is still emerging. Fungi are promising producers of these molecules with unique chemical structures, such as sophorolipids, mannosylerythritol lipids, cellobiose lipids, xylolipids, polyol lipids and hydrophobins. In this review, we aimed to contextualize concepts related to fungal biosurfactant production and its application in industry and the environment. Concepts related to the thermodynamic and physico-chemical properties of biosurfactants are presented, which allows detailed analysis of their structural and application. Promising niches for isolating biosurfactant-producing fungi are presented, as well as screening methodologies are discussed. Finally, strategies related to process parameters and variables, simultaneous production, process optimization through statistical and genetic tools, downstream processing and some aspects of commercial products formulations are presented.

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Fungal bioproducts for petroleum hydrocarbons and toxic metals remediation: recent advances and emerging technologies

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Banat

Robl

et al. 2022

Bioprocess Biosyst Eng

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Petroleum hydrocarbons and toxic metals are sources of environmental contamination and are harmful to all ecosystems. Fungi have metabolic and morphological plasticity that turn them into potential prototypes for technological development in biological remediation of these contaminants due to their ability to interact with a specific contaminant and/or produced metabolites. Although fungal bioinoculants producing enzymes, biosurfactants, polymers, pigments and organic acids have potential to be protagonists in mycoremediation of hydrocarbons and toxic metals, they can still be only adjuvants together with bacteria, microalgae, plants or animals in such processes. However, the sudden accelerated development of emerging technologies related to the use of potential fungal bioproducts such as bioinoculants, enzymes and biosurfactants in the remediation of these contaminants, has boosted fungal bioprocesses to achieve higher performance and possible real applications. In this review, we explore scientific and technological advances in bioprocesses related to the production and/or application of these potential fungal bioproducts when used in remediation of hydrocarbons and toxic metals from an integral perspective of biotechnological process development. In turn, it sheds light to overcome existing technological limitations or enable new experimental designs in the remediation of these and other emerging contaminants.

show abstract

Efficient simultaneous production of extracellular polyol esters of fatty acids and intracellular lipids from inulin by a deep-sea yeast Rhodotorula paludigena P4R5

Cited by 16 publications

References 37 publications

Genomics- and Metabolomics-Based Investigation of the Deep-Sea Sediment-Derived Yeast, Rhodotorula mucilaginosa 50-3-19/20B

Genomics- and Metabolomics-Based Investigation of the Deep-Sea Sediment-Derived Yeast, Rhodotorula mucilaginosa 50-3-19/20B

Fungal biosurfactants, from nature to biotechnological product: bioprospection, production and potential applications

Fungal bioproducts for petroleum hydrocarbons and toxic metals remediation: recent advances and emerging technologies

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