A recombineering pipeline for functional genomics applied to Caenorhabditis elegans

Sarov, Mihail

19 February 2007

Genome sequencing and annotation projects define the complete sets of RNA and protein components for living systems. They also present the challenge to generate functional information for thousands of previously uncharacterized genes. Protein tagging with fluorescent or affinity tags provides a generic way to describe protein expression and localization patterns and protein-protein interactions. The genome wide application of this approach in Saccharomyces cerevisiae has resulted in a comprehensive picture of the core proteome of a simple, well-studied model system. Extending these studies to more complex, multicellular model organisms, would allow us to place protein function onto a 4 dimensional space-time map, and will improve our understanding of the complex processes of development and differentiation. This will require efficient protein tagging methods and new high performance tags. Here we present a generic protein tagging approach for the model nematode Caenorhabditis elegans. The method is based on recombination mediated DNA engineering of genomic BAC clones into tagged transgenes for integrative transformation. C.elegans offers unique advantages for function discovery through protein tagging: compact and a well annotated genome, combined with a simple and well-understood anatomy and pattern of development. However, the methods for protein tagging in C.elegans have so far been inefficient and largely dependent on artificial cDNA based constructs, which can lack important regulatory elements. In contrast, our approach combines the advantages of authentic regulation with a new application of recombineering, which is simple, fast and efficient. For the first time we apply liquid culture cloning for multiple recombineering steps. This is particularly important when high throughput applications are considered, as it offers significant advantages in scale up and automation. We show that the BAC derived transgenes can be used for stable, integrative transformation in C. elegans. We show that the tagged transgene can take over the function of its endogenous counterpart. Using florescent reporter, we reproduce known and document new expression patterns. The second part of the thesis describes a project that we undertook to develop improved double affinity cassettes for protein purification. We evaluated the performance of 5 new double tag combinations in vitro and in mammalian culture cells. All of the new cassettes performed well and present a valuable tool for protein interaction studies in higher model systems.

functional genomics

recombineering

high throughput

DNA engineering

protein tagging

funktionale Genomik

recombineering

Hochdurchsatz

DNS manipulation

Proteinmarkierung

ddc:570

rvk:WD 5360

Genomik

DNS

Rekombination

Proteine

Markierung

Caenorhabditis elegans

A recombineering pipeline for functional genomics applied to Caenorhabditis elegans

Sarov, Mihail

11 December 2006

Genome sequencing and annotation projects define the complete sets of RNA and protein components for living systems. They also present the challenge to generate functional information for thousands of previously uncharacterized genes. Protein tagging with fluorescent or affinity tags provides a generic way to describe protein expression and localization patterns and protein-protein interactions. The genome wide application of this approach in Saccharomyces cerevisiae has resulted in a comprehensive picture of the core proteome of a simple, well-studied model system. Extending these studies to more complex, multicellular model organisms, would allow us to place protein function onto a 4 dimensional space-time map, and will improve our understanding of the complex processes of development and differentiation. This will require efficient protein tagging methods and new high performance tags. Here we present a generic protein tagging approach for the model nematode Caenorhabditis elegans. The method is based on recombination mediated DNA engineering of genomic BAC clones into tagged transgenes for integrative transformation. C.elegans offers unique advantages for function discovery through protein tagging: compact and a well annotated genome, combined with a simple and well-understood anatomy and pattern of development. However, the methods for protein tagging in C.elegans have so far been inefficient and largely dependent on artificial cDNA based constructs, which can lack important regulatory elements. In contrast, our approach combines the advantages of authentic regulation with a new application of recombineering, which is simple, fast and efficient. For the first time we apply liquid culture cloning for multiple recombineering steps. This is particularly important when high throughput applications are considered, as it offers significant advantages in scale up and automation. We show that the BAC derived transgenes can be used for stable, integrative transformation in C. elegans. We show that the tagged transgene can take over the function of its endogenous counterpart. Using florescent reporter, we reproduce known and document new expression patterns. The second part of the thesis describes a project that we undertook to develop improved double affinity cassettes for protein purification. We evaluated the performance of 5 new double tag combinations in vitro and in mammalian culture cells. All of the new cassettes performed well and present a valuable tool for protein interaction studies in higher model systems.

info:eu-repo/classification/ddc/570

ddc:570