In-vitro Characterization of an L-Kynurenine-Responsive Transcription Regulator of the Oxidative Tryptophan Degradation Pathway in Burkholderia xenovorans

Hall, Richard S.; Martí‐Arbona, Ricardo; Hennelly, Scott P.; Maity, Tuhin; Mu, Fangping; Dunbar, John; Ünkefer, Clifford J.; Unkefer, Pat J.

doi:10.5539/jmbr.v3n1p55

Cited by 3 publications

(2 citation statements)

References 30 publications

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“…Figure 2 presents the graphic user interface (GUI) for Function Discovery V1.0 showing the parameters used for the validation test runs. For nine TRs, including BetI [EMBL: ABE34374] [ 22 ], CatR [EMBL: ABE30799] [ 23 ], CynR [EMBL: ABE29438] [ 24 ], CysB [EMBL: ABE30507] [ 25 ], GlpR [EMBL: ABE32291] [ 26 ], HpaR [EMBL: ABE33958] [ 27 ], KynR [EMBL: ABE32198] [ 28 , 29 ], HutC [EMBL: ABE30031] [ 30 , 31 ] and RcoM [EMBL: ABE30826] [ 32 ], the pathways known to be regulated by the TRs were identified in the first hit in the Over-represented Pathway Summary (Additional files 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 and 10 ); in each case the TR effector molecules are metabolic intermediates in the pathway they regulate. The exception was ModE which required a closer analysis of the Function Discovery V1.0 report (Additional file 11 ).…”

Section: Resultsmentioning

confidence: 99%

“…It does not restrict our investigation to a single organism in which gene clustering around the target TR might not have existed because of rearrangements, insertions or deletions of genetic material or other events. Recently, we reported the characterization of three TRs of unknown function in which we used a manual version of our approach to predict functionality and identify potential effector metabolites [ 29 , 38 , 39 ]. Our automated approach, Function Discovery V1.0 has also been effective in finding conserved genes clustered near our target genes and for ten randomly chosen TRs that have known effectors and functions (Table 1 ).…”

Section: Discussionmentioning

confidence: 99%

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Automated genomic context analysis and experimental validation platform for discovery of prokaryote transcriptional regulator functions

Martí‐Arbona

Nowak‐Lovato

et al. 2014

BMC Genomics

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BackgroundThe clustering of genes in a pathway and the co-location of functionally related genes is widely recognized in prokaryotes. We used these characteristics to predict the metabolic involvement for a Transcriptional Regulator (TR) of unknown function, identified and confirmed its biological activity.ResultsA software tool that identifies the genes encoded within a defined genomic neighborhood for the subject TR and its homologs was developed. The output lists of genes in the genetic neighborhoods, their annotated functions, the reactants/products, and identifies the metabolic pathway in which the encoded-proteins function. When a set of TRs of known function was analyzed, we observed that their homologs frequently had conserved genomic neighborhoods that co-located the metabolically related genes regulated by the subject TR. We postulate that TR effectors are metabolites in the identified pathways; indeed the known effectors were present. We analyzed Bxe_B3018 from Burkholderia xenovorans, a TR of unknown function and predicted that this TR was related to the glycine, threonine and serine degradation. We tested the binding of metabolites in these pathways and for those that bound, their ability to modulate TR binding to its specific DNA operator sequence. Using rtPCR, we confirmed that methylglyoxal was an effector of Bxe_3018.ConclusionThese studies provide the proof of concept and validation of a systematic approach to the discovery of the biological activity for proteins of unknown function, in this case a TR. Bxe_B3018 is a methylglyoxal responsive TR that controls the expression of an operon composed of a putative efflux system.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-1142) contains supplementary material, which is available to authorized users.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Automated genomic context analysis and experimental validation platform for discovery of prokaryote transcriptional regulator functions

Martí‐Arbona

Nowak‐Lovato

et al. 2014

BMC Genomics

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Modulation of FadR Binding Capacity for Acyl-CoA Fatty Acids Through Structure-Guided Mutagenesis

2015

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FadR is a versatile global regulator in Escherichia coli that controls fatty acid metabolism and thereby modulates the ability of this bacterium to grow using fatty acids or acetate as the sole carbon source. FadR regulates fatty acid metabolism in response to intra-cellular concentrations of acyl-CoA lipids. The ability of FadR to bind acyl-CoA fatty acids is thus of significant interest for the engineering of biosynthetic pathways for the production of lipid-based biofuels and commodity chemicals. Based on the available crystal structure of E. coli bound to myristoyl-CoA, we predicted amino acid positions within the effector binding pocket that would alter the ability of FadR to bind acyl-CoA fatty acids without affecting DNA binding. We utilized fluorescence polarization to characterize the in vitro binding properties of wild type and mutant FadR. We found that a Leu102Ala mutant enhanced binding of the effector, likely by increasing the size of the binding pocket for the acyl moiety of the molecule. Conversely, the elimination of the guanidine side chain (Arg213Ala and Arg213Met mutants) of the CoA moiety binding site severely diminished the ability of FadR to bind the acyl-CoA effector. These results demonstrate the ability to fine tune FadR binding capacity. The validation of an efficient method to fully characterize all the binding events involved in the specific activity (effector and DNA operator binding) of FadR has allowed us to increase our understanding of the role of specific amino acids in the binding and recognition of acyl-CoA fatty acids and will greatly facilitate efforts aimed at engineering tunable FadR regulators for synthetic biology.

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Discovery of a Choline-Responsive Transcriptional Regulator in Burkholderia xenovorans

Martí‐Arbona

Maity²,

Dunbar³

et al. 2013

JMBR

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In-vitro Characterization of an L-Kynurenine-Responsive Transcription Regulator of the Oxidative Tryptophan Degradation Pathway in Burkholderia xenovorans

Cited by 3 publications

References 30 publications

Automated genomic context analysis and experimental validation platform for discovery of prokaryote transcriptional regulator functions

Automated genomic context analysis and experimental validation platform for discovery of prokaryote transcriptional regulator functions

Modulation of FadR Binding Capacity for Acyl-CoA Fatty Acids Through Structure-Guided Mutagenesis

Discovery of a Choline-Responsive Transcriptional Regulator in Burkholderia xenovorans

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