Difference between revisions of "Part:BBa K1172303"
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[[Image:iGEM_Bielefeld_2013_absorbancetable_4.10.13.jpg|450px|thumb|center|<p align="justify"> '''Table 1: Pipetting scheme and measurement results of riboflavin standards and cell samples for absorbance measurement at 446 nm in the [http://www.tecan.com/platform/apps/product/index.asp?MenuID=1812&ID=1916&Menu=1&Item=21.2.10.1 Tecan Infinite® M200 platereader]. WT = wild type, And77 = Coli equipped with <bbpart>BBa_K1172306</bbpart>, sn = supernatant, cd = cell disruption.'''</p>]] <br> | [[Image:iGEM_Bielefeld_2013_absorbancetable_4.10.13.jpg|450px|thumb|center|<p align="justify"> '''Table 1: Pipetting scheme and measurement results of riboflavin standards and cell samples for absorbance measurement at 446 nm in the [http://www.tecan.com/platform/apps/product/index.asp?MenuID=1812&ID=1916&Menu=1&Item=21.2.10.1 Tecan Infinite® M200 platereader]. WT = wild type, And77 = Coli equipped with <bbpart>BBa_K1172306</bbpart>, sn = supernatant, cd = cell disruption.'''</p>]] <br> | ||
Riboflavin in known concentrations (5.31 * 10^-5 M) and dilutions was measured to generate a calibration curve. The subsequently computed riboflavin concentrations were 5773.3 µg / L for the supernatant of ''E. coli'' KRX with <bbpart>BBa_K1172306</bbpart> and 6112.63 µg /L for the cell disruption samples of ''E. coli'' KRX with <bbpart>BBa_K1172306</bbpart>. The concentration of putative riboflavin in the wild type strain was not detectable. | Riboflavin in known concentrations (5.31 * 10^-5 M) and dilutions was measured to generate a calibration curve. The subsequently computed riboflavin concentrations were 5773.3 µg / L for the supernatant of ''E. coli'' KRX with <bbpart>BBa_K1172306</bbpart> and 6112.63 µg /L for the cell disruption samples of ''E. coli'' KRX with <bbpart>BBa_K1172306</bbpart>. The concentration of putative riboflavin in the wild type strain was not detectable. | ||
− | :* Absorbance measurement is the least sensitive method used for riboflavin detection. Therefore the slightly higher yields should be taken with a grain of salt. | + | :* Absorbance measurement is the least sensitive method used for riboflavin detection. Therefore the slightly higher yields (compared to fluorescence and HPLC measurement) should be taken with a grain of salt. |
− | + | ||
====Fluorescence measurement==== | ====Fluorescence measurement==== |
Revision as of 16:42, 5 October 2013
Riboflavin synthesis gene cluster from shewanella oneidensis
This gene cluster consists of four different genes that form a single operon.
Usage and Biology
Riboflavin, or Vitamin B2 is a redox-active substance that plays an essential role in living cells. Secreted into the medium, it can be effectively used by some bacteria for electron transfer. Presence of riboflavin in anaerobic cultures leads to higher current flow in a microbial fuel cell, which made riboflavin overproduction a suitable target for optimisation of our MFC.
We have shown that cloning of the riboflavin cluster from a metal-reducing bacterium Shewanella oneidensis MR-1 in E. coli is sufficient to achieve significant riboflavin overproduction detectable both in supernatant and in cells.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21INCOMPATIBLE WITH RFC[21]Illegal XhoI site found at 1114
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Results
Confirming overexpression of the rib-gene cluster
The overexpression of BBa_K1172303 and its derived devices BBa_K1172306,BBa_K1172305 and BBa_K1172304 is assured by verifying the protein Riboflavin synthase beta subunit RibE. The protein RibE is part of the riboflavin synthesis pathway of Shewanella oneidensis. The corresponding gene is ribE. RibE belongs to the rib-gene cluster, which we managed to isolate, removing all the illegal restriction sites and subsequently cloned into pSB1C3.
SDS-PAGE
The performed SDS-PAGE shows a distinct band at ~15 kDa. The exact size of the riboflavin synthase beta subunit RibE is 16.7 kDa. The band was cut out and analyzed by MALDI-TOF.
MALDI-TOF
The spot, described above, was picked and digested with trypsine. Afterwards the sample was spotted on the target and analyzed by MALDI-TOF Measurement of the sample produced valid data: RibE was examined by MALDI-TOF MS/MS with a Mascot Score of 906 against the NCBI database concerning bacterial organisms.
Analysis of riboflavin in supernatants
Absorbance measurement
Riboflavin has an absorption peak at 446 nm. The absorbance was measured in a TECAN infinite plate reader. The samples consisted of supernatant derived from E. coli KRX with BBa_K1172306 and KRX as the "wild type" (both strains were cultivated over 72 hours). Further intracellular measurements of both strains were obtained. Therefore, the cells were disrupted via a ribolisation step, centrifugated and the yielded supernatend was evaluated.
Riboflavin in known concentrations (5.31 * 10^-5 M) and dilutions was measured to generate a calibration curve. The subsequently computed riboflavin concentrations were 5773.3 µg / L for the supernatant of E. coli KRX with BBa_K1172306 and 6112.63 µg /L for the cell disruption samples of E. coli KRX with BBa_K1172306. The concentration of putative riboflavin in the wild type strain was not detectable.
- Absorbance measurement is the least sensitive method used for riboflavin detection. Therefore the slightly higher yields (compared to fluorescence and HPLC measurement) should be taken with a grain of salt.
Fluorescence measurement
Riboflavin absorbs light at 440 nm with a corresponding emission at 535 nm. The fluorescence was measured in a TECAN infinite plate reader. The samples consisted of supernatant samples from E. coli KRX with BBa_K1172306 (grown for 72 hours) , E. coli KRX with BBa_K1172306 (grown for 12 hours) and E. coli KRX wild type bacteria (grown for 72 hours)
Riboflavin in known concentrations and dilutions was measured to generate a calibration line. The subsequently computed riboflavin concentrations were 308.1 µg / L for the supernatant sample after 12 hours and 3821.5 µg /L for the supernatant sample after 72 hours. The concentration of putative riboflavin in the wild type strain was not detectable.
HPLC measurement
Supernatant and cell disruption samples of E. coli KRX with BBa_K1172306 (grown for 72 hours) , E. coli KRX with BBa_K1172306 (grown for 12 hours) and E. coli KRX wild type bacteria (grown for 72 hours) were measured in a HPLC detector.
The BBa_K1172306 carrying strains produced a much higher amount of riboflavin compared to the wild type E. coli KRX strain. The LC/MS results do not allow for a statement on how much more riboflavin E. coli KRX+BBa_K1172306 produces. Nevertheless, it is obvious that riboflavin was overproduced in a remarkable quantity.
Evaluation of the measurements
The quantitative data obtained using absorbance, fluorescence and HPLC measurements shows a distinct trend. All samples generated from E. coli KRX+BBa_K1172306 (grown for 72 h) showed similar values of approx. 4000 µg/ml. This is a considerable increase in riboflavin production compared to the wild type KRX strains.
Conclusion
Riboflavin possesses the ability to be a potent redoxmediator. By turning the rib-gene cluster from Shewanella oneidensis into a BioBrick and subsequently cloning it into the desired chasi Escherichia coli, the iGEM Team Bielefeld was able to raise the amount of riboflavin produced by E. coli significantly. The results indicate that the transformation of E. coli with BBa_K1172303, respectively BBa_K1172306, represents a viable option when considering geneticall< optimization of microorganisms intended for usage in microbial fuel cells (MFC).
Methods for Riboflavin analysis
HPLC-Method
- Procedure:
- Riboflavin was separated from disturbing substances on a C18 column and detected with a fluorescence detector.
- Elution:
- The sample was injected onto a C18-reversed phase column and eluted with a buffer consisting of 99 % 0.01 M sodium acetat pH 7.4 and 1 % tetrahydrofurane. Total flow is set to 1 ml/min
- Detection:
- Excitation wavelength of 436 nm and emission wavelength of 535 nm
- C18 reverse phase column
- Isocratic method: 99 % 0.01 M sodium acetate pH 7.4 + 1 % tetrahydrofurane
- Flow = 1 mL min-1
- UV-detection at 535 nm
- Internal standard: 5.31 x 10^-5 mg L^-1 Riboflavin
- Column:
- Eurospher II 100-5 C18p by Knauer
- Dimensions: 150 x 4.6 mm with precolumn
- Particle size: 5 µm
- Pore size: 100 Å
- Material: silica gel
- Software:
- Clarity (Version 3.0.5.505) by Data Apex
- Autosampler:
- Midas by Spark Holland
- Tray cooling: 10 °C
- Pump:
- L-6200A Intelligent Pump by Hitachi
- UV-Detector:
- Series 1050 by Hewlett Packard
LC-ESI-qTOF-MS(-MS)
- Column: C18 reversed phase (Cogent [http://www.mtc-usa.com/diamond_hydride_specs.asp Diamond Hydride])
- dimension: 150 x 2,1 mm
- Pore size: 100 Å
- Particle size: 4 µm
- Flow: 0.4 mL min-1
- Column temperature: 40 °C
- Injection: 5 µl
- Prerun: 5 min
- Eluent:
- A = 50 % acetonitrile + 50 % H2O + 0,1 % formic acid
- B = 90 % acetonitrile + 10 % H2O + 0,1 % formic acid
- Step gradient:
- 0:00 min: 0 % eluent A
- 8:00 min: 100 % eluent A
- 13:00 min: 100 % eluent A
- 15:30 min: 0 % eluent A
- 18:00 min: 0 % eluent A
- VWR Hitachi LaChrom ULTRA HPLC equipment
- Software: HyStar 3.2, mircrOTOF Control, DataAnalysis 4.0
Ionization method
- Using Bruker Daltonics ESI-QTOF micrOTOFQ
- ESI-QTOF-MS in positive mode
- Mass range: 50 - 1500 m/z
- Source:
- End plate offset: - 500 V, 107 nA
- Capillary: - 3500 V, 4 nA
- Nebulizer: 2 bar
- Dry gas: 8 L min-1
- Dry Temp.: 180 °C
- Transfer:
- Funnel 1 RF: 200 Vpp
- Funnel 2 RF: 300 Vpp
- ISCID Energy: 0 eV
- Heyapole RF: 80 Vpp
- Quadrupole
- Ion energy: 4 eV
- Low mass: 50 m/z
- Collision Cell:
- Collision energy: 8 eV
- Collision RF: 130 Vpp
- Transfer time: 75 µs
- Pre puls storage: 4 µs
MS-MS
- Isolated mass: 243.1 +/- 0.1
- Collision energy: 30 eV
Direct fluorescens measurement of riboflavins
- This method has been used for measurement of intracellular and extracellular riboflavin concentration.
- Protocol:
- Inoculate an overnight culture (30 mL with 1 mL of pre-culture)
- Centrifugate (5 min at 5000 g) of 6-10 mL overnight culture (OD 4-6), adjust volume between different samples for the approximation of the number of cells
- Transfer supernatant in fresh reagent tube until measurement. Wash pellet 3 times with 1 mL of PBS buffer
- Resuspend pellet in 1 mL PBS buffer
- Cell disruption by Ribolysation (3 x 30 sec at 6500 rpm)
- Centrifugation for 10 min at maximum speed
- Store extra- and intracellular fractions at - 20 ° C or direct measurement with [http://www.tecan.com/platform/apps/product/index.asp?MenuID=1812&ID=1916&Menu=1&Item=21.2.10.1 Tecan Infinite® M200 platereader]
- [http://www.tecan.com/platform/apps/product/index.asp?MenuID=1812&ID=1916&Menu=1&Item=21.2.10.1 Tecan Infinite® M200 platereader] parameters:
- Sample volume = 100 μL clear supernatant
- Excitation = 440 nm
- Emission = 535 nm
- Concentration calculation by riboflavin calibration curve
References
C. A. Abbas and A. S. Sibirny. (2011) Genetic control of biosynthesis and transport of riboflavin and flavin nucleotides and construction of robust biotechnological producers. [http://mmbr.asm.org/content/75/2/321.full#ref-292| Microbiology and Molecular Biology Reviews 75(2): 321-360].
Hohmann H. P., Stahmann K. P. (2010). Biotechnology of riboflavin production, p. 115–139. In Mander L., Liu H. W. (ed.), Comprehensive natural products. II. Chemistry and biology, vol. 7. Cofactors. Elsevier, Philadelphia, PA.
von Canstein H., Ogawa J., Shimizu S., Lloyd J. R. (2008). Secretion of flavins by Shewanella species and their role in extracellular electron transfer. [http://aem.asm.org/content/74/3/615.full Appl. Environ. Microbiol. 74:615–623].
Bacher A., et al. (2001). Biosynthesis of riboflavin. [http://www.ncbi.nlm.nih.gov/pubmed/11153262 Vitam. Horm. 61:1–49.]
Tesliar G. E., Shavlovskii G. M. (1983). Localization of the genes coding for GTP cyclohydrolase II and riboflavin synthase on the chromosome of Escherichia coli K-12. Tsitol. Genet. 17:54–56. (In Russian.)
Seong Han Lim, Jong Soo Choi and Enoch Y. (2001). Park Microbial Production of Riboflavin Using Riboflavin Overproducers, Ashbya gossypii, Bacillus subtilis, and Candida famate: An Overview.[http://www.bbe.or.kr/storage/journal/BBE/6_2/6657/articlefile/article.pdf Biotechnol. Bioprocess Eng., 6: 75-88]