Abstract
Modulation of gene activity by creating mutations has contributed significantly to the understanding of protein functions. Oftentimes, however, mutational analyses use overexpression studies, in which proteins are taken out of their normal contexts and stoichiometries. In the present work, we sought to develop an approach to simultaneously use the CRISPR/Cas9 and Cre-Lox techniques to modify the endogenous SAT1 gene to introduce mutant forms of the protein while still under the control of its natural gene promoter. We cloned the C-terminal portion of wild type (WT) SAT1, through the transcriptional stop elements, and flanked by LoxP sites in front of an identical version of SAT1 containing point mutations in critical binding sites. The construct was inserted into the endogenous SAT1 locus by Non-Homologous End Joining (NHEJ) after a CRISPR/Cas9 induced DNA double strand break. After validating that normal function of SAT1 was not altered by the insertional event, we were then able to assess the impact of point mutations by introduction of Cre recombinase. The system thus enables generation of cells in which endogenous WT SAT1 can be conditionally modified, and allow investigation of the functional consequences of site specific mutations in the context of the normal promoter and chromatin regulation.
Highlights
Genetic manipulation techniques, such as Cre-LoxP, flp-FRT, and Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/CRISPR-associated protein 9 (Cas9), are extremely powerful tools to modify the genome as desired to decipher the functions of genes or genetic elements
In order to test the effect of specific SAT1 mutants in the biology of polyamine metabolism, common approaches of shRNA or even CRISPR/Cas9 knockout followed by re-expression of mutant constructs are inadequate due to the challenge of replicating endogenous levels of expression
The SAT1 locus, as indicated in Fig 1A was used to design a knock-in scheme whereby exons 4–6 would be duplicated with the wild type exons flanked by loxP sites, and immediately followed by mutant exons 4–6
Summary
Genetic manipulation techniques, such as Cre-LoxP, flp-FRT, and CRISPR/Cas, are extremely powerful tools to modify the genome as desired to decipher the functions of genes or genetic elements. The technique was developed in 1980s and is based on the ability of cyclization recombinase gene (cre) obtained from P1 bacteriophage to effect recombination between pairs of loxP (ATAAC TTCGTATAatgtatgcTATACGAAGTTAT) sites [1,2]. Such recombination can lead to the deletion of DNA present between two loxP sites if they are orientated in same direction, or flip the orientation of a DNA segment between two loxP sites if oriented in opposite directions. The technique can be used to alter the genome as temporally desired by recombining segments of DNA.
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