The hepatocyte growth factor-expressing character is required for mesenchymal stem cells to protect the lung injured by lipopolysaccharide in vivo

Mesenchymal stem cells (MSCs) are one of a few stem cell types to be applied in clinical practice as therapeutic agents for immunomodulation and ischemic tissue repair. In addition to their multipotent differentiation potential, a strong paracrine capacity has been proposed as the principal mechanism that contributes to tissue repair. Apart from cytokine/chemokine secretion, MSCs also display a strong capacity for mitochondrial transfer and microvesicle (exosomes) secretion in response to injury with subsequent promotion of tissue regeneration. These unique properties of MSCs make them an invaluable cell type to repair damaged tissues/organs. Although MSCs offer great promise in the treatment of degenerative diseases and inflammatory disorders, there are still many challenges to overcome prior to their widespread clinical application. Particularly, their in-depth paracrine mechanisms remain a matter for debate and exploration. This review will highlight the discovery of the paracrine mechanism of MSCs, regulation of the paracrine biology of MSCs, important paracrine factors of MSCs in modulation of tissue repair, exosome and mitochondrial transfer for tissue repair, and the future perspective for MSC-based therapy.

Several experimental studies have suggested that mesenchymal stem cells may have value for the treatment of clinical disorders, including myocardial infarction, diabetes, acute renal failure, sepsis, and acute lung injury. In preclinical studies, mesenchymal stem cells have been effective in reducing lung injury from endotoxin, live bacteria, bleomycin, and hyperoxia. In some studies, the cultured medium from mesenchymal stem cells has been as effective as the mesenchymal stem cells themselves. Several paracrine mediators that can mediate the effect of mesenchymal stem cells have been identified, including interleukin-10, interleukin-1ra, keratinocyte growth factor, and prostaglandin E2. Further preclinical studies are needed, as is planning for clinical trials for acute lung injury.

To better characterize lentiviral vector supernatants, we compared three methods of titer assessment. These titer methods include assessment of vector RNA sequences in supernatants, DNA sequences in transduced cells, and vector expression in transduced cells (using a vector which expressed the green fluorescence protein, GFP). For analysis of RNA and DNA, we developed a real-time PCR method for detecting the lentiviral packaging sequence and used this methodology to quantitate the number of vector sequences. Vector expression was assessed by flow cytometric analysis for GFP. As functional titers (DNA and GFP expression titers) are dependent on transduction efficiency, we calculated the titer of a lentiviral vector, RRL-CMV-GFP, after transduction of 293, HeLa, or Mus dunni cells. Genomic DNA was extracted at 4 and 14 days after transduction and the number of vector DNA molecules was determined against a plasmid standard. Of the three cell lines tested, 293 cells provided the highest rate of transduction (PCR estimated DNA titer for RRL-CMV-GFP vector was 2.52 +/- 0.25 x 10(6) molecules/ml at 14 days, and 2.31 +/- 0.15 x 10(6) molecules/ml at 4 days). When titer was calculated based on GFP expression, the highest titer was also obtained on 293 cells (0.26 +/- 0.04 x 10(6) TU/ml at 14 days, and 0.24 +/- 0.03 +/- 10(6) TU/ml at 4 days). The titers obtained by GFP expression assay were approximately one log lower than those obtained by DNA analysis suggesting that variability in vector expression may underestimate titer. Measurement of RNA titers directly from vector supernatants against a plasmid standard indicated that the RNA titers are substantially higher than the DNA (approximately 10(3)-fold) and GFP titers (approximately 10(4)-fold). To show that the lentiviral probe and primers could be used for titering a variety of lentiviral vectors, we have also used the real-time PCR method to determine the DNA titers of two other HIV1 derived vectors, RRL-PGK-GFP (6.1 +/- 1.4 x 10(5) molecules/ml), and SMPU-RRE-BN (1.26 +/- 0.2 x 10(6) molecules/ml). We conclude that of the three methods tested, titers assessed by DNA analysis of transduced cells provide the most reliable estimate of functional titers as these are least likely to be influenced by factors, such as defective interfering particles and vector expression levels. The real-time PCR method described offers a reproducible method for lentiviral titering and can be applied to a wide variety of vectors, regardless of transgene.