Abstract
Gene promoter activity can be studied in vivo by molecular imaging methods using reporter gene technology. Transcription of the reporter and the reported genes occurs simultaneously. However, imaging depends on reporter protein translation, stability, and cellular fate that may differ among the various proteins. A double transgenic mouse strain expressing the firefly luciferase (lucF) and fluorescent mPlum protein under the transcriptional control of the thermo-inducible heat-shock protein (Hspa1b) promoter was generated allowing to follow up the reporter proteins by different and complementary in vivo imaging technologies. These mice were used for in vivo imaging by bioluminescence and epi fluorescence reflectance imaging (BLI & FRI) and as a source of embryonic fibroblast (MEF) for in vitro approaches. LucF, mPlum and endogenous Hsp70 mRNAs were transcribed simultaneously. The increase in mRNA was transient, peaking at 3 h and then returning to the basal level about 6 h after the thermal stimulations. The bioluminescent signal was transient and initiated with a 3 h delay versus mRNA expression. The onset of mPlum fluorescence was more delayed, increasing slowly up to 30 h after heat-shock and remaining for several days. This mouse allows for both bioluminescence imaging (BLI) and fluorescence reflectance imaging (FRI) of Hsp70 promoter activation showing an early and transient lucF activity and a retrospective and persistent mPlum fluorescence. This transgenic mouse will allow following the transient local induction of Hsp-70 promoter beyond its induction time-frame and relate into subsequent dynamic biological effects of the heat-shock response.
Highlights
Molecular imaging enables in vivo visualization of cellular processes in living animals including proteomic, metabolic, cellular biologic and genetic events
Mouse Embryonic Fibroblasts (MEF) were isolated from transgenic embryos (E.14) obtained by crossing Hspa1b-lucF (+/+)
heat-shock protein 70 (HSP70) mRNA refers to the two mRNA transcripts resulting from transcription of both Hspa1a and Hspa1b inducible promoter’s activities
Summary
Molecular imaging enables in vivo visualization of cellular processes in living animals including proteomic, metabolic, cellular biologic and genetic events. Molecular genetic imaging is essential for the follow up of gene therapies [3]. The reporter proteins induce accumulation of a specific imaging signal that reflects the genetic process. Each reporter imaging protein exhibits its own maturation process, stability and cellular fate. Short maturation time reduces the delay between transcriptional induction and imaging detection. Stability limits application in studies that require rapid reporter turnover, including transcriptional induction studies [4]. Half-life of reporter protein in vivo is difficult to determine and quite often unavailable in the current literature the choice for the reporter gene should be adapted to the imaging strategy and the biological question
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