BMP-SMAD-ID promotes reprogramming to pluripotency by inhibiting p16/INK4A-dependent senescence.

Fibrodysplasia ossificans progressiva (FOP) patients carry a missense mutation in ACVR1 [617G > A (R206H)] that leads to hyperactivation of BMP-SMAD signaling. Contrary to a previous study, here we show that FOP fibroblasts showed an increased efficiency of induced pluripotent stem cell (iPSC) generation. This positive effect was attenuated by inhibitors of BMP-SMAD signaling (Dorsomorphin or LDN1931890) or transducing inhibitory SMADs (SMAD6 or SMAD7). In normal fibroblasts, the efficiency of iPSC generation was enhanced by transducing mutant ACVR1 (617G > A) or SMAD1 or adding BMP4 protein at early times during the reprogramming. In contrast, adding BMP4 at later times decreased iPSC generation. ID genes, transcriptional targets of BMP-SMAD signaling, were critical for iPSC generation. The BMP-SMAD-ID signaling axis suppressed p16/INK4A-mediated cell senescence, a major barrier to reprogramming. These results using patient cells carrying the ACVR1 R206H mutation reveal how cellular signaling and gene expression change during the reprogramming processes.

Development of a recombinant adenovirus vector production system free of replication-competent adenovirus by utilizing a packaging size limit of the viral genome.

In a conventional adenovirus (Ad) vector production method using 293 cells, homologous recombination between Ad vector DNA and 293 cell-derived Ad E1 DNA occurs with low efficiency, resulting in the generation of replication-competent adenovirus (RCA). RCA can induce the spread of replication-incompetent Ad vectors, leading to unexpected tissue damage. In order to overcome this problem, we developed an Ad vector production system free of RCA generation by utilizing the Ad packaging size limit of the viral genome. It is well known that up to approximately 105% (37.7 kb) of the wild-type genome (35.9 kb) can be packaged in the Ad virion. We designed the Ad vector genome by insertion of a transgene expression cassette into the E3 region, such that homologous recombination between the Ad vector DNA and 293 cell-derived Ad E1 DNA would produce an Ad vector genome that exceeds in the size of the packaging limit. In accord with our strategy, no RCA generation was observed during the passages when we used the E1 (3.2kb)-deleted Ad vectors containing a more than 3.0-kb transgene expression cassette in the E3 region. In contrast, the E1 (3.2kb)-deleted Ad vectors, which retain 37.7 kb of the viral genome and have an insertion of a 2.1-kb transgene expression cassette in the E3 region, generated RCA, although RCA derived from this Ad vector exceeded the packaging size limit (105.0%). These results suggest that RCA generation can be avoided when the genome size of RCA is more than 108.3% (38.9 kb) of the wild-type Ad genome. This Ad vector production system generates safe, easy, and efficient Ad vector stock for both basic study as well as clinical research.