Team:CBNU-Korea/Project

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무제 문서

The CBNU 2009 iGEM team, our team's goal was to manage and retrieve required data and explore informations through mapping essential genes into orthologs of interesting genomes and through statistical analyses of gene order and direction, so on.

Previous iGEM teams have planned about making synthetic gemone for synthetic cell and programe to design the minimal genome.

We managed and retrieved required data and explored informations through mapping essential gens into orthologs of interesting genomes and through statistical analyses of gene order and direction, so on.

 

Now we are trying putting the plan in practice. Our final main purpose is synthesis a synthetic cell. If you want synthesis a synthetic cell, you need a minimal genome.

The minimal genome is the smallest possible group of genes that would be sufficient to sustain a cellular life form under the most favorable conditions imaginable. There are two ways to synthesize a minimal genome, which are top-down and bottom-up approaches. We are interested in the bottom-up approach, in which the major hurdle is how to degine the minimal genome. We don't know the principle of the organization of the genome. Moreover to verify the design experimentally, we should to deal with some 200 or more essential genes. So, we use the divide-and-conquer strategy to solve the problems in designing the minimal genome.

We will make E.coli having two chromosomes. One is a normal chromosome and the other is a normal chromosome and the other is a model minimal chromosomes, in which the replication and segregation processes and their regulation are occurred independently. Studies on the minimal chromosome will provide us useful information about designing the minimal genome.

This project's purpose is design and making of Minimal Synthetic Chromosome(MSC). Then we need this step for successful process.

(1) Methodical classification of bacterial chromosome copy and division

(2) Development of oriC-finder program for finding Replication Origin of Chromosome(oriC)

(3) Making Bacterial chromosome copy and Division database

(4) Stepwise production and investigation of Minimal Synthetic Chromosome(MSC)

 

 

 

 

ABSTRACT
Most of all bacteria have single circular chromosome. But some bacteria have two or more circular chromosomes. In Vibrio cholerae O1 biovar eltor str. N16961, there are two circular chromosomes, chromosome I and chromosome II, and each perfectly works as a chromosome.

We’ve been motivated by V.cholerae two chromosome system. So we employed some essential genes, parA, parB, parS, dif, rctA, rctB and origin of chromosome II and constructed a tiny miniature of V.cholerae two chromosome system in E.coli, using BioBrick assembly method.

Also, we built software and database of essential genes for designing of minimal synthetic chromosome and genome. Essential gene information was gathered from some databases, DEG, NCBI and java language was used.

PROJECT

Introduction
Synthetic minimal genome is the smallest possible group of genes that would be sufficient to sustain a cellular life form under the most favorable conditions imaginable that working like natural chromosome, bacteria have. For synthesizing minimal genome, there are many things that we have to consider such as kind of genes, gene arrangement, direction of genes, codon usage, genome structure, stability and so on. Therefore it is very difficult to synthesize minimal genome considering ALL of these. So we synthesize simple minimal chromosome employing V.cholerae O1 biovar eltor str. N16961chromosome II replication and partition system as the first step of synthetic minimal genome. Also, we re-build essential gene database from DEG and NCBI. And using this database, we build genome designer easy to design, too.

Approach 1: Replication and Partition system of V. cholerae
In Vibrio cholerae, there are two circular chromosomes, chromosome I(2.96Mb) and chromosome II(1.07Mb), and each perfectly works as a chromosome. Because chromosome II has different replication protein from main chromosome (chromosome I), RctA and RctB. Also chromosome replication origin structure is different each other. Replication origin of chrI( chromosome I ), oriC1vc is similar in sequence to the origin of replication of the Escherichia coli chromosome, oriC. oriC2vc has very little similarity to oriC1vc. oriC2vc has plasmid-like feature(sequences resembling iterons)(Egan and Waldor 2003 and Vendoka-Canova et al 2006).

Fig. 1. Vibrio cholerae O1 biovar eltor str. N16961 structure of oriC2vc

 

The two genes rctA and rctB flanking oriC2vc are so far known unique to replication in the Vibrio family( Egan et al, 2006). The rctA gene is not actually protein coding gene. It codes of an untranslated RNA and acts as a DNA to inhibit oriC2vc function by binding RctB. RctA is not conserved in other vibrio(Venkova-Canova et al 2006). RctB is initiator protein of V.cholerae chrII replication. The RctB protein binds to disparate specific DNA sequences, which gives RctB multiple functions. Also this initiator protein regulates the transcription of rctA and rctB. RctB acts an autorepressor repressing its own transcription as well as rctA. RctB promoter activity is autoregulated by RctB.
Partition of V.cholerae chrII is accomplished by parA, parB and parB binding site parS. Partitioning genes(par genes) have been known to play an essential role in the stable inheritance of certain plasmids. ParB proteins bind to their cognate pars sites and form ParB-parS nucleoprotein complex. Then, ParA protein interacts with the ParB-parS complex and their ATPase activity is essential for partitioning. Still, the molecular mechanism by which the interaction of ParA with the ParB-parS mediates localization and partitioning are not well understood.
Termination of replication is accomplished at the dif DNA site.

Fig. 2. Structure of partitioning system of V.cholerae chromosome II.