Proteomic Insights into Metabolic Adaptations in<i>Alcanivorax borkumensis</i>Induced by Alkane Utilization

Sabirova, Julia; Ferrer, Manuel; Regenhardt, Daniela; Timmis, Kenneth N.; Golyshin, Peter N.

doi:10.1128/jb.00072-06

Cited by 134 publications

(151 citation statements)

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“…Since the cultivation of Alcanivorax borkumensis [88], functional genomic, biochemical and physiological analyses have revealed the underlying basis of its success [52,[89][90][91]. While it lacks catabolic versatility, utilising alkanes almost exclusively as carbon and energy sources, it has multiple alkane-catabolism pathways, with key enzymes including alkane hydoxylases (a non-haem diiron monooxygenase; AlkB1 and AlkB2) and three cytochrome P450-dependent alkane monooxygenases [89].…”

Section: Marine Ecosystemmentioning

confidence: 99%

Aerobic Degradation of Petroleum Components by Microbial Consortia

Aa¹,

Essien²

2014

J Pet Environ Biotechnol

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This article is a state-of-the-art review on the aerobic degradation of petroleum components that are commonly found in the environment. Numerous microorganisms have been isolated and their phylogeny and metabolic capacity to degrade a variety of aliphatic and aromatic hydrocarbons have been demonstrated. This review focuses on recent progress on how microbes degrade hydrocarbons and heteroaromatic components of petroleum contaminants directed towards better understanding of the aerobic degradation processes and their exploitation for bioremediation. The phylogenetic diversity of the oil-degrading microbes was also discussed.

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Section: Marine Ecosystemmentioning

confidence: 99%

Aerobic Degradation of Petroleum Components by Microbial Consortia

Aa¹,

Essien²

2014

J Pet Environ Biotechnol

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“…Varying levels of light intensity iTRAQ and LC-M/MS [43] Heterotrophy/photoautotrophy 2-D PAGE, MALDI-MS and LC-MS/MS [50] Nutrient availability/different C-and energy sources [68,74,75] Growth phase/cell cycle…”

Section: Proteome Signatures In Response To Changing Environmental Comentioning

confidence: 99%

“…While A. borkumensis is hardly detectable in clean water, it can be one of the most abundant microorganisms found in oil-polluted waters [72,73]. Details of alkane degradation pathways used by A. borkumensis could recently be elucidated in a comprehensive proteomic study [74]. Comparing protein patterns from cells grown on pyruvate and hexadecane, respectively, a number of cytoplasmic as well as many membrane-associated proteins could be identified that are specifically induced during growth on alkanes.…”

Section: Highly Specialized Marine Bacteriamentioning

confidence: 99%

Proteomics of marine bacteria

2008

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Little is known about the life of marine microorganisms under their particular environmental conditions. Genome sequencing combined with the techniques of functional genomics, especially proteome analyses, now open up revolutionary insights into the adaptation strategies marine organisms have evolved in response to the challenges of their habitat. This report summarizes the first approaches and state‐of‐the‐art in the field of proteome analysis of marine bacteria. This includes, amongst others, proteomics on culturable, free‐living marine bacteria and on uncultivable bacteria living in symbiosis with higher organisms. Finally, new approaches to determine the metaproteome of uncultured microbial consortia from marine habitats are discussed.

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“…For instance, AlkB-like monooxygenase typically oxidizes liquid alkanes but, lately, few members of this family of enzymes were described to be also induced by propane [66,67]. This underlines the diversity that can exist the proteomic analysis of its cytoplasmic and membrane proteins after the growth on nhexadecane showed the presence of multiple alkane hydroxylase systems belonging to different families [75] involved in the primary oxidation of a broad range of alkanes.A review of the molecular genetics and regulations of the categories of bacterial monooxygenases involved in the n-alkanes metabolism reported in literature is summarized below. …”

mentioning

confidence: 98%

“…The expression of both alkB1 and alkB2 is very low when cells grow using pyruvate as the carbon source, but is strongly induced when C 10 -C 16 alkanes are metabolized; expression decreases considerably upon entry into stationary phase [70,75,213]. A gene coding for a protein showing similarity to the P. …”

Section: Differential Regulation Of Multiple Alkane Hydroxylasesmentioning

confidence: 99%

Monooxygenases involved in the n-alkanes metabolism by Rhodococcus sp. BCP1: molecular characterization and expression of alkB gene

Cappelletti

Fedi

Honda

et al. 2010

Journal of Biotechnology

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Discussion 107 Summary 113Chapter 5 -Analysis of the alkB gene expression Summary 157Chapter 6 -Proteomic analysis of n-alkanes growth of Rhodococcus sp. BCP1 Chapter 1 -General Introduction PrefaceThe quality of life on Earth is tightly related with the overall quality of the environment [1]. During the last century it was commonly believed that the abundance of land and resources were unlimited and it was rarely acknowledged that the production, use, and disposal of hazardous substances had environmental and health effects [1][2][3]. Owing to this, human activity has deliberately or inadvertently released into waters and soil a variety of toxic compounds as refrigerants, paints, solvents, herbicides and pesticides that can cause considerable environmental pollution and human health problems as a result of their persistence, toxicity, and transformation into hazardous metabolites [4,5]. Very soon, however, it became clear how the carelessness and negligence in handling the industrial wastes and gas emissions had caused dramatic effect on the nature and on human health [1].Nowadays, the concern about the global warming and the climate changing induced the government regulatory agencies to establish procedures for assessing the environmental impact and health hazards of chemicals and for controlling/limiting their utilization.International efforts have been applied to remedy many contaminated sites all over the world, either as a response to the risk of adverse health or environmental effects caused by contamination or to enable the site to be redeveloped for use [5]. In response to public and government concern and because of the intriguing research problems presented, environmental scientists, biologists and chemists have been giving increased attention to identifying and determining the behavior and fate of organic compounds in natural ecosystems [5].Bioremediation procedures offer an economical and effective possibility to degrade or render innocuous toxic pollutants using natural biological activity [1]. By definition, bioremediation implies the use of living organisms, primarily microorganisms, to degrade the Since contaminant compounds are transformed by living organisms through reactions that take place as a part of their metabolic processes, environmental biotechnology focuses on the development of techniques to optimize environmental parameters to allow these metabolic pathways to proceed faster and, therefore, to improve the bio-degradation [1]. As a result, the removal of the contaminated soil can be necessary to let the biodegradation proceed in controlled sites (such as bioreactors). These ex situ approaches provide optimal conditions out one single step of the entire bio-degradation process. Hydrocarbons in the environmentHydrocarbons are energy-rich organic compounds consisting of carbon and hydrogen atoms and they can be saturated (only single C-H bounds) or unsaturated (one ore more double or triple C-H bounds). Alkanes are saturated hydrocarbons with the general formula C n H 2n+2 ; they can b...

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Proteomic Insights into Metabolic Adaptations inAlcanivorax borkumensisInduced by Alkane Utilization

Cited by 134 publications

References 50 publications

Aerobic Degradation of Petroleum Components by Microbial Consortia

Aerobic Degradation of Petroleum Components by Microbial Consortia

Proteomics of marine bacteria

Monooxygenases involved in the n-alkanes metabolism by Rhodococcus sp. BCP1: molecular characterization and expression of alkB gene

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