Genomic and proteomic analysis of lignin degrading and polyhydroxyalkanoate accumulating β-proteobacterium Pandoraea sp. ISTKB

Kumar, Madan; Verma, Sandhya; Gazara, Rajesh Kumar; Kumar, Manish; Pandey, Ashok; Verma, Praveen Kumar; Thakur, Indu Shekhar

doi:10.1186/s13068-018-1148-2

Cited by 89 publications

(31 citation statements)

References 60 publications

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“…Peroxdiases have also been shown to play a role in oxidative damage formed during metabolism of lignin and other aromatic compounds as well as being differentially expressed by Pandorawa sp. ISTKB in the presence of lignin-derived aromatics [14]. The proteomic analysis of the secretome of C. lapagei presented here represents an excellent starting point for identifying and characterizing enzymes that could be developed for applications in the bioenergy, wood and pulping, textiles and chemical production industries requiring lignocellulose degradation and depolymerization enzymes.…”

Section: Discussionmentioning

confidence: 99%

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Public questions spur the discovery of new bacterial species associated with lignin bioconversion of industrial waste

et al. 2019

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A citizen science project found that the greenhouse camel cricket ( Diestrammena asynamora ) is common in North American homes. Public response was to wonder ‘what good are they anyway?’ and ecology and evolution guided the search for potential benefit. We predicted that camel crickets and similar household species would likely host bacteria with the ability to degrade recalcitrant carbon compounds. Lignocellulose is particularly relevant as it is difficult to degrade yet is an important feedstock for pulp and paper, chemical and biofuel industries. We screened gut bacteria of greenhouse camel crickets and another household insect, the hide beetle ( Dermestes maculatus ) for the ability to grow on and degrade lignocellulose components as well as the lignocellulose-derived industrial waste product black liquor. From three greenhouse camel crickets and three hide beetles, 14 bacterial strains were identified that were capable of growth on lignocellulosic components, including lignin. Cedecea lapagei was selected for further study due to growth on most lignocellulose components. The C. lapagei secretome was identified using LC/MS/MS analysis. This work demonstrates a novel source of lignocellulose-degrading bacteria and introduces an effective workflow to identify bacterial enzymes for transforming industrial waste into value-added products. More generally, our research suggests the value of ecologically guided discovery of novel organisms.

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Section: Discussionmentioning

confidence: 99%

“…Proteomic analysis has been conducted on some lignin degrading strains including Pandoraea sp. ISTKB [14]. Lignin-degrading bacteria have also been analysed for use in product generation from black liquor [15].…”

Section: Introductionmentioning

confidence: 99%

Public questions spur the discovery of new bacterial species associated with lignin bioconversion of industrial waste

et al. 2019

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“…To illustrate the details and metabolic pathways of lignin bioconver- and its presence could also increase the energy production efficiency. 139 With kraft lignin and vanillic acid as substrates, respectively, Kumar et al 140 analyzed the proteome and identified the differently expressed proteins between kraft lignin and vanillic acid as substrates.…”

Section: System Analysis To Investigate Lignin Degradation Mechanismsmentioning

confidence: 99%

Biotransformation of lignin: Mechanisms, applications and future work

Zheng

2019

Biotechnology Progress

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As one of the most abundant polymers in biosphere, lignin has attracted extensive attention as a kind of promising feedstock for biofuel and bio-based products. However, the utilization of lignin presents various challenges in that its complex composition and structure and high resistance to degradation. Lignin conversion through biological platform harnesses the catalytic power of microorganisms to decompose complex lignin molecules and obtain value-added products through biosynthesis.Given the heterogeneity of lignin, various microbial metabolic pathways are involved in lignin bioconversion processes, which has been characterized in extensive research work. With different types of lignin substrates (e.g., model compounds, technical lignin, and lignocellulosic biomass), several bacterial and fungal species have been proved to own lignin-degrading abilities and accumulate microbial products (e.g., lipid

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“…ISTKB was identified during screening of rhizospheric soil samples taken from the coastal region and was found to be able to use kraft lignin as a sole carbon source for growth. This bacterium possesses lignin peroxidase and MnP enzymes showing both intracellular and extracellular laccase activities . It showed about 21–60% PHA accumulation, while growing on various lignin and related substrates.…”

Section: Lignin and Its Derivatives For Phasmentioning

confidence: 99%

“…Although such screening is helpful and used widely, one major challenge is our inability to culture the un‐culturable in laboratory conditions. Moreover, high‐throughput sequencing and related techniques have helped to pinpoint the untapped genome and potential enzymes that can have significant industrial applications . Besides this, the complex compounds released after deconstruction (by any method) are not naturally preferred substrate to the bacteria.…”

Section: Challenges Associated With Lignin Bioconversionmentioning

confidence: 99%

Bioconversion of lignin and its derivatives into polyhydroxyalkanoates: Challenges and opportunities

Kumar

Maharjan

Park

et al. 2018

Biotech and App Biochem

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Renewable energy resources are considered to be promising for the development of a sustainable circular economy. Among various alternatives, the microbial route for various biofuels production is quite lucrative. Use of cellulose and lignocellulose for methane, H 2 , organic acids, ethanol, and cellulase has been explored a lot in the past few decades. The major leftover or a coproduct of these processes belongs to lignin-an aromatic cross-link polymer and one of the most abundant complex compounds on earth. A successful bioconversion route of lignin into high-value products is highly desirable for biorefinery perspective. It requires a complex set of enzymes/catalysts to decompose lignin through depolymerization and oxygen removal leading to its monomers that can be metabolized by engineered organisms to synthesize muconic acids, polyhydroxyalkanoates (PHAs), methane, and other high-value products. This article will focus on the opportunities and challenges in the bioconversion of lignin and its derivatives into PHAs.

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Genomic and proteomic analysis of lignin degrading and polyhydroxyalkanoate accumulating β-proteobacterium Pandoraea sp. ISTKB

Cited by 89 publications

References 60 publications

Public questions spur the discovery of new bacterial species associated with lignin bioconversion of industrial waste

Public questions spur the discovery of new bacterial species associated with lignin bioconversion of industrial waste

Biotransformation of lignin: Mechanisms, applications and future work

Bioconversion of lignin and its derivatives into polyhydroxyalkanoates: Challenges and opportunities

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