Serum-Induced Proliferation of Human Cardiac Stem Cells Is Modulated via TGFßRI/II and SMAD2/3.

The ageing phenotype is strongly driven by the exhaustion of adult stem cells (ASCs) and the accumulation of senescent cells. Cardiovascular diseases (CVDs) and heart failure (HF) are strongly linked to the ageing phenotype and are the leading cause of death. As the human heart is considered as an organ with low regenerative capacity, treatments targeting the rejuvenation of human cardiac stem cells (hCSCs) are of great interest. In this study, the beneficial effects of human blood serum on proliferation and senescence of hCSCs have been investigated at the molecular level. We show the induction of a proliferation-related gene expression response by human blood serum at the mRNA level. The concurrent differential expression of the TGFß target and inhibitor genes indicates the participation of TGFß signalling in this context. Surprisingly, the application of TGFß1 as well as the inhibition of TGFß type I and type II receptor (TGFßRI/II) signalling strongly increased the proliferation of hCSCs. Likewise, both human blood serum and TGFß1 reduced the senescence in hCSCs. The protective effect of serum on senescence in hCSCs was enhanced by simultaneous TGFßRI/II inhibition. These results strongly indicate a dual role of TGFß signalling in terms of the serum-mediated effects on hCSCs. Further analysis via RNA sequencing (RNA-Seq) revealed the participation of Ras-inactivating genes wherefore a prevention of hyperproliferation upon serum-treatment in hCSCs via TGFß signalling and Ras-induced senescence is suggested. These insights may improve treatments of heart failure in the future.

The Full Genome Sequences of Pseudomonas sp. Strain MM221 and Pseudoarthrobacter sp. Strain MM222, Isolated from a Meadow in Bielefeld, Germany.

The bacterial strains Pseudomonas sp. strain MM221 and Pseudoarthrobacter sp. strain MM222 were isolated from a sandy soil sample. Here, we report on their complete genome sequences, including a circular plasmid for MM221, which were assembled after sequencing with an Oxford Nanopore Technologies flow cell.