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Revision as of 18:46, 25 September 2013
[Psal1] J61051 pSB1A2 Bca9015 Salicylate promoter
(Edited by Zheng Pu, Peking iGEM 2013)
(Please visit: http://2013.igem.org/Team:Peking/Project/BioSensors/NahR for more details)
Improved part from Peking iGEM 2013: https://parts.igem.org/Part:BBa_K1031610
Introduction
The nahR gene was mined from the 83 kb naphthalene degradation plasmid NAH7 of Pseudomonas putida, encoding a 34 kDa protein which binds to nah and sal promoters to activate transcription in response to the inducer salicylate. This plasmid encodes enzymes for the metabolism of naphthalene or salicylate as the sole carbon and energy source (Fig. 1a) [1]. The 14 genes encoding the enzymes for this metabolism are organized in two operons: nah (nahA-F), encoding six enzymes required for metabolizing naphthalene into salicylate and pyruvate, and sal (nahG-M), encoding eight enzymes which metabolize salicylate into intermediates of TCA cycle (Fig. 1b) [2].
We also did adaptor for this biosensor to improve its performance. (for more detail:http://2013.igem.org/Team:Peking/Project/Plugins)
Figure.1 Degradation pathway of naphthalene and the corresponding gene cluster in Pseudomonas putida. (a) Gene cluster on the NAH7 plasmid that degrades naphthalene: Naphthalene is degraded into salicylate by enzymes encoded by the "upper operon"; salicylate is further degraded to enter TCA cycle via the gene products of the "lower operon". Both of the operons are regulated by the transcription factor NahR in response to salicylate, the metabolite intermediate in the pathway. (b) Degradation pathway of naphthalene: Naphthalene is degraded by a series of enzymatic reactions, each catalyzed by a specific nah gene product represented by a capital letter. A through M: A, Naphthalene dioxygenase; B, cis-dihydroxy-naphthalene dioxygenase; D, 2-hydroxychromene-2-carboxylate isomerase; E, 2-hydroxybenzalpyruvate aldolase; F, salicylaldehyde dehydrogenase; G, salicylate hydroxylase; H, catechol 2,3-dioxygenase; I, 2-hydroxymuconate semialdehyde dehydrogenase; J, 2-hydroxymuconate tautomerase; K, 4-oxalcrotonate decarboxylase; L, 2-oxo-4-pentenoate hydratase; M, 2-oxo-4-hydroxypentanoate aldolase.
Protein Domain Structure
Figure.2 The organization of NahR protein domains. The domain marked by green near the N terminal accounts for DNA binding, which contains a typical helix-turn-helix motif; red domains function to bind inducer, while the orange domain is putatively involved in multimerization of NahR during the transcription activation.
Promoter Structure
Figure.3 Schematic diagram for the NahR-regulated promoters, nah and sal. Alignment of sal and nah promoter is shown and the consensus sequence motifs are highlighted in color. NahR binding sequence and RNAP binding sequence are boxed in green and yellow, respectively.
Mechanism
Several experiments conformed that NahR tightly binds to DNA in vivo in the presence or absence of salicylate. Either the amount or the affinity of NahR binding to DNA will be affected by salicylate in both E. coli and its native host Pseudomonas putida[3]. This along with the evidence from methylation protection experiments suggested a conformational change in the NahR•DNA complex before transcription activation (Fig. 4)[4].
Figure.4 Schematic diagram for the transcription activation at sal (or nah) promoter by NahR in the presence of inducer salicylate. 1. The DNA structure of sal promoter: A, B, C and D represent the binding sites for the tetramer of NahR; the yellow arrow shows the direction of sal promoter. 2. RNAP and σ70 bind to the sal promoter by recognizing -35 and -10 boxes; 3. Transcription factor NahR tightly binds to sal promoter and forms a tetramer no matter whether there is salicylate or not; 4. When salicylate is present, NahR•DNA complex undergoes a conformational change. After the hydrolysis of ATP, DNA is opened and transcription is activated.
Circuit Construction
We placed the Standard Biological Part BBa_J61051 which contains the constitutively expressed NahR and sal promoter in front of the reporter gene sfGFP (Fig.5) via standard assembly. The plasmid verified by Beijing Genomics Institute was transformed into E. coli (TOP10, TransGen Biotech). Single clone of bacteria was picked and grown in rich LB medium added chloromycetin (170 μg/ml) overnight and stored at -80℃ in 20% glycerol, waiting for induction test.
Figure.5 Schematic diagram for the NahR biosensor circuit. The Standard Biologicla Part BBa_J61051 was placed preceding reporter sfGFP in the backbone pSB1C3. Promoters are presented in orange, RBS in light green, coding sequence in dark blue and terminators in red.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21INCOMPATIBLE WITH RFC[21]Illegal BglII site found at 786
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal NgoMIV site found at 77
Illegal NgoMIV site found at 618 - 1000COMPATIBLE WITH RFC[1000]
Construction and Test
On-Off Tests
Fig.6. Response of sensor NahR biosensor to various aromatic species. (For the full name of the compounds, CLICK HERE). (a) The induction ratio of various aromatic species in the ON-OFF test. NahR could respond to 18 out of 78 aromatics with the induction ratio over 20. (b) The aromatics-sensing profile of NahR biosensor.The aromatic species that can elicit strong responses of NahR biosensor are highlighted in green in the aromatics spectrum. The structure formula of typical inducer is also listed around the spectrum. Induction ratio is calculated by dividing the fluorescence intensity of biosensor exposed to inducers by the basal fluorescence intensity of the biosensor.
Dose-response Curve
Fig.7 Dose response curves of NahR biosensor. (a) Dose response curves for salicylate, its homologs and derivatives; (b) Dose response curves for benzoate, its derivatives and special inducers like 5-ClSaD and 2,4,6-TClPhl. Induction ratio is calculated by dividing the fluorescence intensity of biosensor exposed to inducers by the basal fluorescence intensity of the biosensor.For the full name of the compounds, CLICK HERE).
Orthogonality
Sensor | Host | Main Inducers |
---|---|---|
XylS | Pseudomonas putida | BzO 2-MeBzO 3-MeBzO 2,3-MeBzO 3,4-MeBzO |
NahR | Pseudomonas putida | 4-MeSaA 4-C1SaA 5-C1SaA SaA Aspirin |
DmpR | Pseudomonas sp.600 | Phl 2-MePhl 3-MePhl 4-MePhl 2-ClPhl |
HbpR | Pseudomonas azelaica | o-Phenylphenol 2,6'-DiHydroxybiphenol |
we have confirmed the orthogonality among inducers of different biosensors, which is one of the main features we expect for our aromatics-sensing toolkit. Our sensors are well suited to multicomponent analysis.
Related Parts:
XylS: https://parts.igem.org/Part:BBa_K1031911 Wiki: http://2013.igem.org/Team:Peking/Project/BioSensors/XylS
NahR: https://parts.igem.org/Part:BBa_K1031610 Wiki: http://2013.igem.org/Team:Peking/Project/BioSensors/NahR
HbpR: https://parts.igem.org/Part:BBa_K1031300 Wiki: http://2013.igem.org/Team:Peking/Project/BioSensors/HbpR
DmpR: http://2013.igem.org/Team:Peking/Project/BioSensors/DmpR
Orthoganaility between inducer A (originally detected by biosensor I) and B (originally detected by biosensor II) were tested in the following manner (Fig.1). To test the effect of inducer B upon the dose-response curve of inducer A obtained by biosensor I:
(1) Fluorescence intensity of biosensor I elicited by inducer A of concentration gradient was measured as standard results (Fig.1a, Lane 1);
(2) And fluorescence intensity of biosensor I induced by inducer A of concentration gradient in the presence of a certain concentration of inducer B was measured (Fig.1a, Lane 2 and 3) and compared with the standard results.
The effect of inducer A upon the dose-response curve of inducer B obtained by biosensor II was tested vice versa (Fig.1b).
Fig.1. Orthogonality test assay for inducer A (detected by biosensor I) and inducer B (detected by biosensor II). (a) Biosensor I was added into the test assay. Different mixtures of inducers were added into lane 1, 2, and 3 respectively as listed above. Effect of inducer B upon the dose-response curve of inducer A was tested by comparing the fluorescence intensity of biosensor I among lane 1 ,2, and 3. (b) Biosensor II was added into the test assay. Different mixtures of inducers were added into lane 1, 2, and 3 respectively as listed above. Effect of inducer A upon the dose-response curve of inducer B was tested by comparing the fluorescence intensity of biosensor II among lane 1 ,2, and 3.
We managed to demonstrate the orthogonality among inducers of different biosensors in a more quantitative and visible way. If inducer A and B were orthogonal, the fluorescence intensity should be identical no matter with or without the irrelevant inducer B. That is to say, the ideal experimental points should be aligned in a line whose slope is one.
The orithogonality of inducers of XylS, NahR, HbpR and DmpR biosensors have been carefully confirmed using the test assay introduced above (Fig.2). The experimental points were processed by linear fitting and the slopes of the fitting curves were compared with 1. The closer the slope was to 1, the more orthogonal the inducers were. The results showed that inducers of biosensor XylS and NahR (Fig.2a, b), XylS and HbpR (Fig.2c, d), NahR and HbpR (Fig.2e, f), XylS and DmpR (Fig.2g, h), NahR and DmpR (Fig.2i, j), and HbpR and DmpR (Fig.2k, l) are all highly orthogonal, which is summarized in Fig.2.
Fig.2. Experimental points and the linear fitting curves of the orthogonality test. The black dashed lines are with the slopes of 1, showing as the reference line. The slopes of the experimental fitting curves were showed in the upside portion of the figure, all of them were around 1. These data showed the orthogonality among inducers of biosensors(a, b) XylS and NahR; (c, d) XylS and HbpR; (e, f) NahR and HbpR, (g, h) XylS and DmpR, (i, j) NahR and DmpR, and (k, l) HbpR and DmpR. The experimental points and linear fitting curves of biosensor and its inducers are marked in different colors: XylS in red, NahR in green, HbpR in orange and DmpR in dark cyan.
Reference
[1] Dunn, N. W., and I. C. Gunsalus.(1973) Transmissible plasmid encoding early enzymes of naphthalene oxidation in Pseudomonas putida. J. Bacteriol. 114:974-979 [2] M. A. Schell.(1983) Cloning and expression in Escherichia coli of the naphthalene degradation genes from plasmid NAH7. J. Bacteriol. 153(2):822 [3] M. A. Schell, and P. E. Wender.(1986) Identification of the nahR gene product and nucleotide sequences required for its activation of the sal operon. J. Bacteriol. 116(1):9 [4] Woojun Park, Che Ok Jeon, Eugene L. Madsen.(2002) Interaction of NahR, a LysR-type transcriptional regulator, with the K subunit of RNA polymerase in the naphthalene degrading bacterium, Pseudomonas putida NCIB 9816-4. FEMS Microbiology Letters. 213:159-165 [5] Mark A. Schell, Pamela H. Brown, and Satanaryana Raju.(1990) Use of Saturation Mutagenesis to Localize Probable Functional domains in the NahR protein, a LysR-type Transcription Activator. The Journal of Biological Chemistry. 265(7): 3384-3850. [6] Angel Cebolla, Carolina Sousa, and Vı´ctor de Lorenzo.(1997) Effector Specificity Mutants of the Transcriptional Activator NahR of Naphthalene Degrading Pseudomonas Define Protein Sites Involved in Binding of Aromatic Inducers. The Journal of Biological Chemistry. 272(7):3986-3992 [7] M. A. Schell, and E. F. Poser.(1989) Demonstration, characterization, and mutational analysis of NahR protein binding to nah and sal promoters. J. Bacteriol. 171(2):837 [8] Jianzhong Huang and Mark A. Schell.(1991) In vivo interaction of the NahR Transcriptional Activator with its target sequences. The Journal of Biological Chemistry. 266(17):10830-10838 [9] Hoo Hwi Park, Hae Yong Lee, Woon Ki Lim, Hae Ja Shin. (2005) NahR: Effects of replacements at Asn 169 and Arg 248 on promoter binding and inducer recognition. Archives of Biochemistry and Biophysics. 434:67-74