Team:Bielefeld-Germany/Project/Riboflavine

From 2013.igem.org

(Difference between revisions)
Line 124: Line 124:
*Protein: bifunctional diaminohydroxyphosphoribosylaminopyrimidine deaminase/5-amino-6-(5-phosphoribosylamino) uracil reductase RibD
*Protein: bifunctional diaminohydroxyphosphoribosylaminopyrimidine deaminase/5-amino-6-(5-phosphoribosylamino) uracil reductase RibD
*Enzyme: (EC: 3.5.4.26)
*Enzyme: (EC: 3.5.4.26)
-
*Molecular weight:  41,257 Da
+
*Molecular weight:  41,257 kDa
<br>
<br>
[[File:IGEM Bielefeld 2013 2_so_3468.png|120px|left|]]
[[File:IGEM Bielefeld 2013 2_so_3468.png|120px|left|]]
Line 130: Line 130:
*Protein: Riboflavin synthase alpha subunit RibC-like protein
*Protein: Riboflavin synthase alpha subunit RibC-like protein
*Enzyme: EC 2.5.1.9
*Enzyme: EC 2.5.1.9
-
*Molecular weight: 23,483 Da
+
*Molecular weight: 23,483 kDa
<br>
<br>
[[File:IGEM Bielefeld 2013 3_ribBA.png|120px|left|]]
[[File:IGEM Bielefeld 2013 3_ribBA.png|120px|left|]]
Line 137: Line 137:
**Protein:     GTP cyclohydrolase-2
**Protein:     GTP cyclohydrolase-2
**Enzyme:  EC 3.5.4.25
**Enzyme:  EC 3.5.4.25
-
**Molekular weight:          22,852 Da
+
**Molekular weight:          22,852 kDa
*''ribB''  
*''ribB''  
**Protein: 3,4-dihydroxy-2-butanone-4-phosphate synthase
**Protein: 3,4-dihydroxy-2-butanone-4-phosphate synthase
**Enzyme:      EC 3.5.4.25
**Enzyme:      EC 3.5.4.25
-
**Molecular weight: 22,956 Da
+
**Molecular weight: 22,956 kDa
<br>
<br>
[[File:IGEM Bielefeld 2013 4_ribE.png|120px|left|]]
[[File:IGEM Bielefeld 2013 4_ribE.png|120px|left|]]
Line 147: Line 147:
*Protein: 6,7-dimethyl-8-ribityllumazine synthase (aka: riboflavin synthase beta subunit RibE)
*Protein: 6,7-dimethyl-8-ribityllumazine synthase (aka: riboflavin synthase beta subunit RibE)
*Enzyme: EC 2.5.1.78
*Enzyme: EC 2.5.1.78
-
*Molecular Weight: 16,689 Da
+
*Molecular Weight: 16,689 kDa
 +
 
 +
 
 +
 
 +
[[File:igem_bielefied2013_ribcluster.png|thumb|400px|left|'''Figure 5:''' Initial ''rib''-gene cluster from ''Shewanella oneidensis MR-1''. Three illegal restriction sites are marked with an asterisk]]
 +
Figure 5 illustrates the initial position we established first: Isolating of the ''rib''-gene cluster from the genome of ''Shewanella oneidensis'' and clone it into pSB1C3.
 +
 
 +
<br>
 +
[[File:igem_bielefied2013_ribcluster_cut3.png|thumb|400px|left|'''Figure 6:''' The strategy for base substitution: we designed three pairs of primers annealing on each illegal restriction site. As a result we amplified three fragments. For primer sequences look up [https://2013.igem.org/Team:Bielefeld-Germany/Labjournal/September Labjournal September]]]<br>
 +
[[File:Igem bielefied2013 ribcluster 2.png|thumb|400px|left|'''Figure 7:''' Ready ''rib''-gene cluster [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172303 BBa_K1172303] Biobrick from ''Shewanella oneidensis MR-1'' without illegal restriction sites.]]
 +
 
===Supplementary Genes===
===Supplementary Genes===
We also separately amplified some other genes that theoretically could be important for riboflavin synthesis or regulation.
We also separately amplified some other genes that theoretically could be important for riboflavin synthesis or regulation.
Line 168: Line 178:
==Results==
==Results==
-
[[File:igem_bielefied2013_ribcluster.png|thumb|400px|left|'''Figure 5:''' Initial ''rib''-gene cluster from ''Shewanella oneidensis MR-1''. Three illegal restriction sites are marked with an asterisk]]<br>
+
 
-
[[File:igem_bielefied2013_ribcluster_cut3.png|thumb|400px|left|'''Figure 6:''' The strategy for base substitution: we designed three pairs of primers annealing on each illegal restriction site. As a result we amplified three fragments. For primer sequences look up [https://2013.igem.org/Team:Bielefeld-Germany/Labjournal/September Labjournal September]]]<br>
+
-
[[File:Igem bielefied2013 ribcluster 2.png|thumb|400px|left|'''Figure 7:''' Ready ''rib''-gene cluster [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172303 BBa_K1172303] Biobrick from ''Shewanella oneidensis MR-1'' without illegal restriction sites.]]
+
[[File:Igem bielefied2013 ribonorm.png|thumb|400px|left|'''Figure 8:''' Initial ''norM'' gene from ''Shewanella Oneidensis MR-1'' with one illegal restriction site]]<br>
[[File:Igem bielefied2013 ribonorm.png|thumb|400px|left|'''Figure 8:''' Initial ''norM'' gene from ''Shewanella Oneidensis MR-1'' with one illegal restriction site]]<br>
[[File:igem_bielefied2013_ribonorm_ohne.png|thumb|400px|left|'''Figure 9:''' A strategy to remove an illegal restriction site: we created primers, that amplified two fragments X and Y. For primer sequences look up [https://2013.igem.org/Team:Bielefeld-Germany/Labjournal/September Labjournal September]]]<br>
[[File:igem_bielefied2013_ribonorm_ohne.png|thumb|400px|left|'''Figure 9:''' A strategy to remove an illegal restriction site: we created primers, that amplified two fragments X and Y. For primer sequences look up [https://2013.igem.org/Team:Bielefeld-Germany/Labjournal/September Labjournal September]]]<br>

Revision as of 21:27, 4 October 2013



Riboflavin


Overview

Figure 1: Visual supernatants comparison of a [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172306 BBa_K1172306] riboflavin-overproducing strain and a Escherichia coli KRX wild type.
Tubes from left to right:
  1. Tube 1: A 72-hour culture of E. coli KRX [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172306 BBa_K1172306]
  2. Tube 2: A 72-hour culture of E. coli KRX [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172306 BBa_K1172306], supernatant
  3. Tube 3: A 72-hour culture of E. coli KRX [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172306 BBa_K1172306], cell lysate
  4. Tube 4: A 72-hour culture of a wild type E. coli KRX, supernatant
  5. Tube 5: A 72-hour culture of a wild type E. coli KRX, cell lysate

[http://de.wikipedia.org/wiki/Riboflavin 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.






Theory

Figure 2: Riboflavin (Vitamin B2) and flavin-coenzymes FMN (flavin mononucleotide) and FAD (flavin adenine dinucleotide).

Since its discovery in 1879 and its first structural characterization in the 1930’s, a lot of properties of riboflavin were elucidated. This substance is a precursor of FMN (flavin mononucleotide) and FAD (flavin adenine dinucleotide), which play an essential role as cofactors in many oxidative processes. The modern name riboflavin, also named lactoflavin, is composed of two parts: «ribo» indicating the presence of the sugar alcohol ribitol, and «flavin» meaning «yellow»; to accentuate the yellow coloring of the oxidized molecule. Chemically this substance consists of two functional subunits, an already mentioned short-chain ribitol and a tricyclic heterosubstituted isoalloxazine ring.

The latter, also known as a riboflavin ring, exists in three redox states and is responsible for the diverse chemical activity of riboflavin. A fully oxidized quinone, a one-electron semiquinone and a fully reduced hydroquinone states are the three stages of riboflavin oxidation. In an aqueous solution, the quinone (fully oxidized) form of riboflavin has a typical yellow coloring. It becomes red in a semi-reduced anionic or blue in a neutral form and is colorless when fully reduced.


Figure 3: Schematic redox reactions of riboflavin.

All these forms are present in different proportions in a living cell, making previous oxidation a necessary step if riboflavin analysis is to be conducted. Flavins have a typical yellow-green fluorescence in the UV light. The peaks of absorbance occur at 223, 266, 373 and 445 nm. The maximum fluorescence emission of the neutral solution is at 535 nm [Charles A. Abbas et al., [http://mmbr.asm.org/content/75/2/321.full#ref-292 2011]]. These fluorimetric properties are widely used in the analysis of riboflavin.

Due to its structure, which allows a transfer of two electrons from hydrogen and hydrid ions, riboflavin can be imagined as a potential electron shuttle. It was previously known, that the electron transfer from the outer membrane-associated proteins to an inorganic electron acceptor is the main limiting growth factor for Fe(III)-reducing prokaryotes, so a few mechanisms that show how this process can be enhanced have been discovered. One of them was a secretion of water-soluble redox mediators. It was proven, that secretion of riboflavin and FMN enhances the rate of insoluble mineral oxides reduction. Indeed, Shewanella oneidensis, a facultative Fe-III respiring bacterium uses secreted riboflavin as its electron transmitter [Harald von Canstein et al., [http://aem.asm.org/content/74/3/615.full 2008]]. Considering this acknowledgement, we decided to overproduce riboflavin in E. coli to improve its efficiency in our MFC.

First of all, we have searched for a suitable microorganism, which has an active riboflavin cluster with known coding sequences. We have already used the remarkable versatility of Shewanella in order to clone the anaerobic respiratory chain (mtrCAB cluster), so now we were able to skip some initial steps, like the whole genome DNA isolation and advanced rapidly to more specific steps.

Before planning the cloning strategy, we checked [http://parts.igem.org/Main_Page the Parts registry] for any parts we could use or enhance. A [http://parts.igem.org/Part:BBa_K769203 ribC part] was listed, but it was neither submitted nor available. We also had a close look on the [http://www.chem.qmul.ac.uk/iubmb/enzyme/reaction/misc/riboflavin2.html riboflavin biosynthesis pathway]. This process is well studied and a lot of appropriate literature is available. There are three types of riboflavin overproducers used in industry: yeast (Candida famate), fungi (Ashbya gossypii), and bacteria (Bacillus subtilis) [Overview, Seong Han Lim et al., [http://www.bbe.or.kr/storage/journal/BBE/6_2/6657/articlefile/article.pdf 2001]], but a prevailing majority of microorganisms also synthesize riboflavins in low concentrations. In E. coli, for instance, genes are scattered through the whole genome and riboflavin is produced constitutively.

The biosynthesis of riboflavin starts with ribulose-5-phosphate and GTP, converted to formate and DHBP (L-3,4-dihydroxybutan-2-one 4-phosphate). The final stage involves forming of the third isoalloxazine ring by an exchange of a 4-carbon part, catalysed by riboflavin synthetase (EC 2.5.1.9). We assumed, that the operon in Shewanella could be similar to a well-studied [http://www.ncbi.nlm.nih.gov/pubmed/8159171 rib-operon] of Bacillus subtilis. The operon is transcribed as a one polycistronic RNA, making a single promoter sufficient. Introduction of multiple copies of a ribA gene (coding for GTP cyclohydrolase II (EC 3.5.4.25)), comprised in the rib-operon, results in riboflavin overproduction in B. subtilis [Hohmann H.P.,Stahmann K.P. 2010. Biotechnology of riboflavin production, p. 115–139.], so we predicted a notable riboflavin synthesis gain following a successful introduction of a multiple-copy plasmid harbouring the rib-operon under an active promoter.

Genetic Approach

Riboflavin Cluster

Figure 4: Riboflavin synthesis gene cluster, cloned from Shewanella oneidensis MR-1, 3697 bp; with non-coding sequences. * The nomenclature was taken from the [http://www.ncbi.nlm.nih.gov/ NCBI site]. Depending on the source there are slight differences in nomenclature. For example, ribE is often referred to as ribH.



Below we shortly describe each functional member of this cluster.

IGEM Bielefeld 2013 1 ribD.png



  • Gene: RibD http://www.ncbi.nlm.nih.gov/gene/1171145 Sequence, 1145 bp
  • Protein: bifunctional diaminohydroxyphosphoribosylaminopyrimidine deaminase/5-amino-6-(5-phosphoribosylamino) uracil reductase RibD
  • Enzyme: (EC: 3.5.4.26)
  • Molecular weight: 41,257 kDa


IGEM Bielefeld 2013 2 so 3468.png


IGEM Bielefeld 2013 3 ribBA.png
  • Gene: RibBAribA & ribB http://www.ncbi.nlm.nih.gov/gene/1171143 Sequence, 1103 bp
  • ribA
    • Protein: GTP cyclohydrolase-2
    • Enzyme: EC 3.5.4.25
    • Molekular weight: 22,852 kDa
  • ribB
    • Protein: 3,4-dihydroxy-2-butanone-4-phosphate synthase
    • Enzyme: EC 3.5.4.25
    • Molecular weight: 22,956 kDa


IGEM Bielefeld 2013 4 ribE.png


Figure 5: Initial rib-gene cluster from Shewanella oneidensis MR-1. Three illegal restriction sites are marked with an asterisk

Figure 5 illustrates the initial position we established first: Isolating of the rib-gene cluster from the genome of Shewanella oneidensis and clone it into pSB1C3.


Figure 6: The strategy for base substitution: we designed three pairs of primers annealing on each illegal restriction site. As a result we amplified three fragments. For primer sequences look up Labjournal September

Figure 7: Ready rib-gene cluster [http://parts.igem.org/wiki/index.php?title=Part:BBa_K1172303 BBa_K1172303] Biobrick from Shewanella oneidensis MR-1 without illegal restriction sites.

Supplementary Genes

We also separately amplified some other genes that theoretically could be important for riboflavin synthesis or regulation.


IGEM Bielefeld 2013 4 ribC.png


IGEM Bielefeld 2013 1 nusB.png
IGEM Bielefeld 2013 3 norM.png

Results

Figure 8: Initial norM gene from Shewanella Oneidensis MR-1 with one illegal restriction site

Figure 9: A strategy to remove an illegal restriction site: we created primers, that amplified two fragments X and Y. For primer sequences look up Labjournal September

  • We received the data from the MALDI-TOF and the subsequent results where positive: The overexpressed protein, had formed a band on a SDS-PAGE at about 15 kDa. We hoped it would turn out to be RibE, with a molecular weight of 16,7 kDa.

Figure X: Screenshot of the BioTools user interface showing the pure results of the MALDI-TOF.

  • The results show that it is indeed “riboflavin synthase beta subunit ribE” from ``Shewanella oneidensis`` MR-1. The mascot score was a slick 906. We want to thank Vera Ortseifen for the execution of our measurements.

Figure X: Exported MALDI-TOF results.


  • For further quantitative analysis of riboflavin in culture supernatants we measured fluorescence with 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] (The week before we had already measured absorbance). Riboflavine absorbes light at 440 nm with a corresponding emission at 535 nm. We again checked riboflavin of known quantities to compute a calibration line. The samples consisted of KRX wild type bacteria (grown for 72 hours) and KRX that carried the rib-cluster with strong Anderson promoter / strong RBS (<bbpart>BBa_K1172306</bbpart>) (grown for 72 hours and for 12 hours respectively). Of course both cultures were nurtured in the good M9-D5.

Table X: Pipetting scheme and measurement results of riboflavin standards and cell samples for fluorescence measurement, emission at 535 nm. Measured 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.


  • Y = 8*10^8 * X - 3193.6
  • This allowed us to evaluate the amount of riboflavin in the supernatant and the cell disruption samples.
  • Supernatant after 12 hours: 308.1 µg / L
  • Supernatant after 72 hours: 3821.5 µg /L




  • We asked the lab of Dr. Heino Büntemeyer if we could use their HPLC detector to verify riboflavin concentrations. We prepared some samples and overviewed the measurement. The HPLC-method itself was friendly carried out by Jana Heinrich. It yielded significant results and allows the quantification of riboflavins in our samples.

Table X: HPLC measurement results for riboflavin concentrations in supernatant (sn) and cell disruption (cd) samples after 72 hours and 12 hours of cultivation respectively.

  • Table X shows the produced amount of Riboflavin. After 72 hours of cultivation in M9-D5 the concentration of riboflavin in supernatant and cell disruption samples of ``E. coli`` KRX+<bbpart>BBa_K1172306</bbpart> was 60fold higher than in ``E. coli`` KRX wild type. Even after 12 hours, the riboflavin producing strain had generated ten times as much riboflavin as the wild type.

Figure X: Results of the HPLC measurement shown as graph. For better clarity only one supernatant sample per strain and cultivation time is shown.

Figure X: Results of the HPLC measurement shown as graph. Figure X was centered on the riboflavin peak for a better view.


  • The wrong M9 medium had been the reason for unsufficient riboflavin production. This fact rendered our first (LC/MS) measurement innocuous. We were able to organize another measurement of some of our samples with liquid chromatography-mass spectrometry (LC/MS). We prepared supernatant samples of a wild type KRX after 72 h, the <bbpart>BBa_K1172306</bbpart> strain after 36 h and 72 h in M9-D5 and after 72 h in wrong M9. In the following we put the samples in the LC-MS-system. The measurement procedure was carried out by Lena Sinkel.


Figure X: LC/MS results presented as list depiction.

Figure X: LC/MS results presented as overlay depiction.


  • It is clear, that the <bbpart>BBa_K1172306</bbpart> carrying strains produce a much higher amount of riboflavin compared to the wild type KRX strain. The LC/MS results do not allow for a statement on how much more riboflavin our strain produces, because from this method we can´t know if the relation between the amount of vitamin B2 and the peak-area is linear. Nevertheless, it is obvious that riboflavin was overexpressed in a remarkable quantity.
    It is although important to notice that the green curve in figures X represents the high concentrated riboflavin standard. A look at figure X and the relative intensities given on the Y-axis, illustrates how much more efficient KRX+<bbpart>BBa_K1172306</bbpart> in M9-D5 produces riboflavin compared to KRX+<bbpart>BBa_K1172306</bbpart> in wrong M9 and especially compared to wild type KRX.


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]








Contents