Biocompatible photoresistant far-red emitting, fluorescent polymer probes, with near-infrared two-photon absorption, for living cell and zebrafish embryo imaging.

Exogenous probes with far-red or near-infrared (NIR) two-photon absorption and fluorescence emission are highly desirable for deep tissue imaging while limiting autofluorescence. However, molecular probes exhibiting such properties are often hydrophobic. As an attractive alternative, we synthesized water-soluble polymer probes carrying multiple far-red fluorophores and demonstrated here their potential for live cell and zebrafish embryo imaging. First, at concentrations up to 10 µm, these polymer probes were not cytotoxic. They could efficiently label living HeLa cells, T lymphocytes and neurons at an optimal concentration of 0.5 µm. Moreover, they exhibited a high resistance to photobleaching in usual microscopy conditions. In addition, these polymer probes could be successfully used for in toto labeling and in vivo two-photon microscopy imaging of developing zebrafish embryos, with remarkable properties in terms of biocompatibility, internalization, diffusion, stability and wavelength emission range. The near-infrared two-photon absorption peak at 910 nm is particularly interesting since it does not excite the zebrafish endogenous fluorescence and is likely to enable long-term time-lapse imaging with limited photodamage.

Reduced immunoglobulin class switch recombination in the absence of Artemis.

Nonhomologous end-joining DNA repair factors, including Artemis, are all required for the repair of DNA double-strand breaks, which occur during the assembly of the variable antigen recognition domain of B-cell receptors and T-cell receptors through the V(D)J recombination. Mature B cells further shape their immunoglobulin repertoire on antigen recognition notably through the class switch recombination (CSR) process. To analyze the role of Artemis during CSR, we developed a mature B-cell-specific Artemis conditional knockout mouse to bypass the absence of B cells caused by its early deficit. Although CSR is not overwhelmingly affected in these mice, class switching to certain isotypes is clearly reduced both in vitro on B-cell activation and in vivo after keyhole limpet hemocyanin immunization. The reduced CSR in Artemis-deficient B cells is accompanied by the increase in DNA microhomology usage at CSR junctions, the imprint of an alternative DNA end-joining pathway. Likewise, significant increase in DNA microhomology usage is the signature of CSR junctions obtained from human RS-SCID patients harboring hypomorphic Artemis mutations. Altogether, this indicates that Artemis participates in the repair of a subset of DNA breaks generated during CSR.

Efficient in toto targeted recombination in mouse liver by meganuclease-induced double-strand break.

BACKGROUND: Sequence-specific endonucleases with large recognition sites can cleave DNA in living cells, and, as a consequence, stimulate homologous recombination (HR) up to 10 000-fold. The recent development of artificial meganucleases with chosen specificities has provided the potential to target any chromosomal locus. Thus, they may represent a universal genome engineering tool and seem to be very promising for acute gene therapy. However, in toto applications depend on the ability to target somatic tissues as well as the proficiency of somatic cells to perform double-strand break (DSB)-induced HR. METHODS: In order to investigate DSB-induced HR in toto, we have designed transgenic mouse lines carrying a LagoZ gene interrupted by one I-SceI cleavage site surrounded by two direct repeats. The LagoZ gene can be rescued upon cleavage by I-SceI and HR between the two repeats in a process called single-strand annealing. beta-Galactosidase activity is monitored in liver after tail vein injection of adenovirus expressing the meganuclease I-SceI. RESULTS: In toto staining revealed a strong dotted pattern in all animals injected with adenovirus expressing I-SceI. In contrast, no staining could be detected in the control. beta-Galactosidase activity in liver extract, tissue section staining, and PCR analysis confirmed the presence of the recombined LagoZ gene. CONCLUSIONS: We demonstrate for the first time that meganucleases can be successfully delivered in animal and induce targeted genomic recombination in mice liver in toto. These results are an essential step towards the use of designed meganucleases and show the high potential of this technology in the field of gene therapy.