Proteomic analysis of carbohydrate catabolism and regulation in the marine bacteriumRhodopirellula baltica

Gade, Dörte; Gobom, Johan; Rabus, Ralf

doi:10.1002/pmic.200401200

Cited by 36 publications

(37 citation statements)

References 34 publications

(27 reference statements)

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“…2D-DIGE is capable of quantifying small differences in protein levels, making it a popular approach for large-scale expression profiling in a range of biological systems. In the field of bacterial proteomics, 2D-DIGE has become a standard comparative proteomic approach for the study of gene regulation, stress responses, virulence mechanisms as well as environmental adaptation in both Gram-negative and Gram-positive species (Gade et al, 2005;Al Dahouk et al, 2008;Alteri et al, 2009;Franco et al, 2009). Investigators have previously compared directly the use of 2D-DIGE and colorimetric protein stains to quantify changes in protein expression patterns in E. coli cells treated with benzoic acid (Yan et al, 2002;Han and Lee, 2006).…”

Section: Advancements and Current Status Of 2-dementioning

confidence: 99%

Two-dimensional gel electrophoresis in bacterial proteomics

et al. 2012

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Two-dimensional gel electrophoresis (2-DE) is a gel-based technique widely used for analyzing the protein composition of biological samples. It is capable of resolving complex mixtures containing more than a thousand protein components into individual protein spots through the coupling of two orthogonal biophysical separation techniques: isoelectric focusing (first dimension) and polyacrylamide gel electrophoresis (second dimension). 2-DE is ideally suited for analyzing the entire expressed protein complement of a bacterial cell: its proteome. Its relative simplicity and good reproducibility have led to 2-DE being widely used for exploring proteomics within a wide range of environmental and medically-relevant bacteria. Here we give a broad overview of the basic principles and historical development of gel-based proteomics, and how this powerful approach can be applied for studying bacterial biology and physiology. We highlight specific 2-DE applications that can be used to analyze when, where and how much proteins are expressed. The links between proteomics, genomics and mass spectrometry are discussed. We explore how proteomics involving tandem mass spectrometry can be used to analyze (post-translational) protein modifications or to identify proteins of unknown origin by de novo peptide sequencing. The use of proteome fractionation techniques and non-gel-based proteomic approaches are also discussed. We highlight how the analysis of proteins secreted by bacterial cells (secretomes or exoproteomes) can be used to study infection processes or the immune response. This review is aimed at non-specialists who wish to gain a concise, comprehensive and contemporary overview of the nature and applications of bacterial proteomics.

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Section: Advancements and Current Status Of 2-dementioning

confidence: 99%

Two-dimensional gel electrophoresis in bacterial proteomics

et al. 2012

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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%

“…It undergoes a cell cycle, differentiating between motile swarmer cells and sessile cell aggregates [66]. R. baltica's interesting physiological potential has been subject to several proteomic investigations during the previous years ([ [67][68][69]133]. A first 2-D reference map of cytosolic R. baltica proteins in the pH range of 4-7 was established by PMF in 2005, including 558 distinct proteins [67].…”

Section: Planctomycetesmentioning

confidence: 99%

“…Using a comparative proteomic approach that investigated R. baltica's carbon catabolism, several so-called stimulons, i.e. distinct groups of carbon degradation-related proteins could be identified in cells grown with ribose, N-acetylglucosamine, xylose, maltose, lactose, melibiose and raffinose, respectively [68]. Interestingly, the authors found that coordinately regulated R. baltica proteins are not necessarily coded within the same genomic regions (as are for example all proteins involved in the catabolism of ribose).…”

Section: Planctomycetesmentioning

confidence: 99%

“…Interestingly, the authors found that coordinately regulated R. baltica proteins are not necessarily coded within the same genomic regions (as are for example all proteins involved in the catabolism of ribose). Some functionally related proteins, like the ones involved in xylose degradation, the abundance of which increased in the presence of xylose, are not organized in clusters [68]. In an analogous study, the same authors investigated growth phase-dependent variations in the R. baltica protein pattern using the differential in gel electrophoresis (DIGE) technology [69].…”

Section: Planctomycetesmentioning

confidence: 99%

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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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Rhodopirellula

Schlesner¹

2015

Bergey's Manual of Systematics of Archaea and Bacteria

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Rho.do.pi.rel'lu.la. Gr. neut. n. rhodon a rose; N.L. fem. n. Pirellula name of a bacterial genus; N.L. fem. n. Rhodopirellula a red Pirellula . Planctomycetes / Planctomycetia / Planctomycetales / Planctomycetaceae / Rhodopirellula Cells are ovoid , ellipsoidal , or pear‐shaped , occurring singly or in rosettes by attachment at the smaller cell pole . Cells divide by budding . Buds are produced directly from the broader cell pole of the mother cell. Crateriform structures and fimbriae are found in the upper cell region . Cells have intracytoplasmic membranous structures . Gram‐stain‐variable. Buds may have a single flagellum inserted subpolarly at the proximal pole. Adult cells are immobile. Strictly aerobic. Colonies are pink to red in color . Mesophilic. Requires seawater for growth. Nonsporeforming. PHB is not stored. Chemoheterotrophic. Carbon and energy sources are mainly carbohydrates. C1‐compounds are not used. N ‐acetylglucosamine serves as carbon and nitrogen source. Catalase‐ and cytochrome oxidase‐positive. The proteinaceous cell wall lacks peptidoglycan . The major polyamines are putrescine, cadaverine, and sym ‐homospermidine. The major menaquinone is MK‐6 . The major fatty acids are C 16:1 ω7, C 16:0 , C 17:1 ω8, C 17:0 , C 18:1 ω7, C 18:1 ω9, and C 18:0 . The major phospholipids are phosphatidylcholine and phosphatidylglycerol. DNA G + C content ( mol %): 53–57 (HPLC). Type species : Rhodopirellula baltica Schlesner, Rensmann, Tindall, Gade, Rabus, Pfeiffer and Hirsch 2004, 1577 VP .

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Proteomic analysis of carbohydrate catabolism and regulation in the marine bacteriumRhodopirellula baltica

Cited by 36 publications

References 34 publications

Two-dimensional gel electrophoresis in bacterial proteomics

Two-dimensional gel electrophoresis in bacterial proteomics

Proteomics of marine bacteria

Rhodopirellula

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