Team:HNU China/Project

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<b>Reference</b> <br/>
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<b>Reference</b> <br/><br/>
1.Photoexcited CRY2 Interacts with CIB1 to Regulate Transcription and Floral Initiation in Arabidopsis, Hongtao Liu, Xuhong Yu, Kunwu Li, John Klejnot, Hongyun Yang, Dominique Lisiero, Chentao Lin*, SCIENCE VOL 322 5 DECEMBER 2008  <br/>
1.Photoexcited CRY2 Interacts with CIB1 to Regulate Transcription and Floral Initiation in Arabidopsis, Hongtao Liu, Xuhong Yu, Kunwu Li, John Klejnot, Hongyun Yang, Dominique Lisiero, Chentao Lin*, SCIENCE VOL 322 5 DECEMBER 2008  <br/>
2.Optical control of mammalian endogenous transcription and epigenetic states, Silvana Konermann1,2*, Mark D. Brigham1,2,3*, Alexandro Trevino1,2, Patrick D. Hsu1,2,4, Matthias Heidenreich1,2, Le Cong1,2,5, Randall J. Platt1,2, David A. Scott1,2, George M. Church1,6 & Feng Zhang1,2, doi:10.1038/nature12466  <br/>
2.Optical control of mammalian endogenous transcription and epigenetic states, Silvana Konermann1,2*, Mark D. Brigham1,2,3*, Alexandro Trevino1,2, Patrick D. Hsu1,2,4, Matthias Heidenreich1,2, Le Cong1,2,5, Randall J. Platt1,2, David A. Scott1,2, George M. Church1,6 & Feng Zhang1,2, doi:10.1038/nature12466  <br/>
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3.ProQuest Two-Hybrid System user manual.  <br/>
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3.ProQuest Two-Hybrid System user manual.  <br/><br/>
     <img src="https://static.igem.org/mediawiki/2014/7/73/July.png" width="98" height="45" /> <br/>
     <img src="https://static.igem.org/mediawiki/2014/7/73/July.png" width="98" height="45" /> <br/>

Revision as of 06:02, 24 September 2014




Background
As far as the bronze age, our ancestors began to extract valuable metal from the mineral, with the combined process of chemical reaction and high temperature treatment, using quite a lot energy. When this ancient industry comes to the modern time, piles of problems emerge, then hinder the road to a more industrialized life, both more comfortable and material-consuming, some of which show as below:
  1. Due to the long history of mineral exploitation, people look for high purity reserves deep underneath the surface, DANGEROUS, making it to the miners.
  2. HIGH UTILIZATION RATIO is what we are appealing to the mineral waste slag as well the abandoned mines, which abound with reserves, however is not cost-effective under the treatment of traditional way.
  3. Besides of the slag, metal reserves shall also exist in the CIVIL WASTE. since electronic device used and threw in our daily life. Trash leachate is another object we resort to collect the valuable metal.
Microorganism, the core of novel field microbialmetallurgy, contains several aspects of benefits distinguished from the old way. The major species selected in recent research are existed in certain natural environment with special metabolism and ion uptake systems, taking Thiobacillus species, Acidithiobacillus species as illustration. With the technique of synthetic biology, create an artificial life, based on baker’s yeast, with expected strong capacity of iron absorbing, is what other scientist never tried and what we aim to achieve.



Description
Our microbial miner briefly consists of two systems, iron sensitive absorbing system and optogenetic apoptosis system, the last of which is designed for the biosafety reason.
  1. Iron sensitive absorbing system:
    1. IRE: part of the upstream none-coding sequence of human ADH1 RNA, which will form a hairpin structure with human protein IREBP, inhibiting the process of translation.
    2. IREBP: human protein.
    3. FET3: baker’s yeast protein, plays a substaintial role in the iron uptake.
  2. optogenetic apoptosis system
    1. Cry2-CIB1: both of these transcription factors are cloned from the genome of Arabidopsis, which will react under the blue light, then initiate the expression of the gene downstream.
    2. Casp3: human protein, plays a core role in the cellular apoptosis.




Experimentation

Preliminary construction of the Cry2-CIB1 system

I.Background

Photoactivation mechanism of Arabidopsis cryptochrome 2(CRY2), in mediating light regulation of cell elongation and photoperiodic flowering, has been revealed as a blue light-specific manner cooperating with cryptochrome-interacting basic helix-loop-helix protein(CIB1), which is screened by yeast two-hybrid assay.[1] This system is recently engineered in a light-inducible transcriptional effectors (LITEs), applying in mice neuron or the brain in vivo to mediate reversible gene expression.[2] Reasonably, we would like to utilize them to serve for our project, which in detail is an optogenetic apoptosis system for the biosafety reason.

II.Cloning of the Cry2 & CIB1 gene

According to the sequences from NCBI, we designed two pairs of primers respectively, and cloned them based on the cDNA library of Arabidopsis.[fig.1]

Primer for Cry2:
Fwd 5’→3’   ATGAATGGAGCTATAGGA
Rev 5’→3’   TCAAACTCCTAAATTGCC

Primer for CIB1:
Fwd 5’→3’   ATGAAGATGGACAAAAAGA
Rev 5’→3’   TCATTTGCAACCATTTTT

III.Optogenetic yeast-two-hybrid

Two-hybrid or interaction trap systems exploit the fact that transcription factors are comprised of two domains, a DNA binding domain (DBD) and an activation domain (AD). Two separate hybrid proteins are constructed in two-hybrid screens. The first hybrid protein is the DBD/protein X, while the second hybrid protein is the AD/protein Y.These two hybrids are encoded on separate yeast expression plasmids, with independent selectable markers.[3] Based on the principle of yeast-two-hybrid, there are several pairs of plasmids designed for the screening of interacting protein library, commercially accessible.
What we chose is the pDEST32 and pDEST22[fig.2], where the DBD and AD is actually Gal4 BD and Gal4 AD respectively, and the Gal4 AD shall specifically bind to the upstream activating sequence(UAS), locating in the promoters of several reporter genes in the yeast strain genome like lacZ, HIS3 as well URA3.

Fig.2


Since we have obtained CRY2 and CIB1, what we do next is to induce both of them into their vectors with the technology named Gateway, constructing two new plasmids,
pDEST22-CIB1 and pDEST32-32 as below[fig.3]:

Fig.3


Then we transform the plasmids above into the baker’s yeast strain, AH109, screening by Leu and Trp auxotroph. To test the effect of light switchable gene expression system, blue-white selection is induced when the blue light in special incubator[fig.4] shall initiate the expression of LacZ, which combined with the IPTG and X-gal in solid medium, makes the colony into blue, contrarily, colony in dark remains white.[fig.5]

Fig.4


Reference

1.Photoexcited CRY2 Interacts with CIB1 to Regulate Transcription and Floral Initiation in Arabidopsis, Hongtao Liu, Xuhong Yu, Kunwu Li, John Klejnot, Hongyun Yang, Dominique Lisiero, Chentao Lin*, SCIENCE VOL 322 5 DECEMBER 2008
2.Optical control of mammalian endogenous transcription and epigenetic states, Silvana Konermann1,2*, Mark D. Brigham1,2,3*, Alexandro Trevino1,2, Patrick D. Hsu1,2,4, Matthias Heidenreich1,2, Le Cong1,2,5, Randall J. Platt1,2, David A. Scott1,2, George M. Church1,6 & Feng Zhang1,2, doi:10.1038/nature12466
3.ProQuest Two-Hybrid System user manual.


Cloning of the genes we need and Construction of T-vector

I.IRE-IRP

The regulation of the synthesis of ferritin in mammalian cells is mediated by the interaction of the Iron regulatory protein (IRP) with a specific recognition site, the iron responsive element (IRE), In the 5' untransiated regions (UTRs) of the respective mRNAs. [1]

1.IRP

We decide to clone the IRP from human cDNA library.

Primers for IRP[fig.1]:
Fwd 5’→3’   GCGAAGCTTTCAGTAATCATGAGCAAC
               HindIII
Rev 5’→3’   GCGGAGCTCTTGAGCAGAGCGTAAGA
               SacI

Fig.1


2.IRE

Since IRE is a quite short sequence, counting 40 bp at all. A pair of single-stranded DNA are synthesized as the primers, and annealing shall create double-stranded DNA.

Pair of single-stranded DNAs
Fwd 5’→3’   GCGAAGCTTGTTCTTGCTTCAACAGTGTTTGGACGGAACACTAGTGCG
    HindIII              SpeI
Rev 5’→3’   CGCACTAGTGTTCCGTCCAAACACTGTTGAAGCAAGAACAAGCTTCGC
   SpeI                HindIII

II.FET3

S. cerevisiae accumulate iron by a process requiring a ferrireductase and a ferrous transporter. [2] FET3 is an oxidase which depends on the Cu2+ in yeast membrance, and forms the complex for iron absorption with FTR1, which is the main part of the high absorption system[3]. Here we hope FET3 could active the function of high absorption system to make the system more efficient in absorption of iron.

1.Prepare for the genome of baker’s yeast

Due to the lack of existing yeast genome as the PCR template, we order a yeast genome extraction kit to prepare the source.[fig.2]

Fig.2


2.Cloning of FET3

Primers for FET3[fig.3]
Fwd 5’→3’   GCGAAGCTTATGACTAACGCTTTGCTCTCTATAG
      HindIII
Rev 5’→3’   GCGGAGCTCTGGAACCCTTGACCGA
       SacI

Fig.3


III.CASP3

Caspase-3 normally exists in the cytosolic fraction of cells as an inactive precursor that is activated proteolytically when cells are signaled to undergo apoptosis.[4] So in the project, we want to make the modified yeast commit suicide through overexpress caspase-3 protein to protect natural environment.

The template for PCR is also the human cDNA library.

Primers for CASP3[fig.4]
Fwd 5’→3’   GCGACTAGTGCTCTGGTTTTCGGTGGG
     Spe1
Rev 5’→3’   GCGGAGCTCTGGAACCCTTGACCGA
           SacI

Fig.4


IV.Construction of the T-vector

To make sure the PCR-cloned sequences are expected, we ligate them into the pMD18-T vector, then sequence all together. On the other hand, objective sequence in circular plasmids makes it convenient and stable for storage for quite long time.

Reference

1.Translational repression by the human iron-regulatory factor (IRF) in Saccharomyces cerevisiae, Carla C.Oliveira, Britta Goossen1, Nilson l.T.Zanchin, John E.G.McCarthy*, Matthias W.Hentze1 and Renata Stripecke1, Nucleic Acids Research, 1993, Vol. 21, No. 23
2.The FET3 gene of S. cerevisiae encodes a multicopperoxidase required for ferrous iron uptake, Askwith, C., Eide, D., Van Ho, A., Bernard, P.S., Li, L., Davis-Kaplan, S., Sipe, D.M., Kaplan, J. Cell(1994)
3.Stearman R, Yuan D S, Yamaguchi-Jwai Y et al. Science, 1996, 271(15): 1552~1557
4.Activation of cyclin A-dependent protein kinases during apoptosis. Proc. Natl. Acad. Sci. USA, 91 (1994), pp. 3754–3758
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