The objective of this study was to identify the proteins actively involved in the protection and repair of damaged cells, secreted by canine adipose derived mesenchymal stem cells (AT-MSCs) into the conditioned media. For this purpose, conditioned media (CM) was recovered from passage three stage canine AT-MSCs and skin fibroblasts cultured in serum free media after 24, 48 and 72 h. The extraction of exosomes was performed from 10-20 ml of CM using total exosome isolation kit. The isolated exosomes were then subjected to western analysis for the identification of annexin-I, annexin-II, histone H3 and dysferlin proteins. Results demonstrated the expression of proteins in the conditioned media isolated from canine AT-MSCs reflecting their potential in reducing the extent of damage at cellular levels. In conclusion, the conditioned media derived from canine AT-MSCs can be helpful in restoring the normal structure of cells both in vivo and in vitro conditions.

In the last several decades, cell therapy research has increased worldwide. Many studies have been conducted on cell therapy, and have revealed that transplanted cells did not survive for long, and implanted cells remained inactive causing immune rejection depending on the patient’s condition. Therefore, studies on cell-free therapy need to be conducted. To overcome these limitations, an alternative is the use of supernatant from cells, called “conditioned media (CM).” During in vitro cell culture, culture media supply nutrients to maintain cell characteristics and viability. In the culture, cells not only consume nutrients but also release beneficial proteins and substances, which are called “secretome.” CM from cells can be stored for a long time and is easy to handle. Moreover, secretome in CM can also be measured; exact amount of secretome is important to set the standard value for disease treatment. Here, we reviewed studies on CM and confirmed that various secretomes from CM were identified in these studies. Moreover, these findings could benefit cell and animal studies in future. In conclusion, CM could be a potential candidate for an alternative to cell therapy.

Cementum is a hard connective tissue, produced by cementoblasts during tooth root formation, which provides for the attachment of the periodontal ligament to the roots and surrounding alveolar bone. Establishment of this attachment is an important event in the regeneration of lost periodontal tissues. We examined whether or not odontoblast conditioned media(CM) have a regulatory influence on the differentiation and mineralization of cementoblasts(murine cementoblastic cell line, OCCM-30) in vitro. To identify the effect of odontoblast conditioned media and dentin non collagenous proteins (dNCPs) on cementoblast differentiation and mineralization, we treated CM and dNCPs to cementoblast then differentiated the cells for 14 days. To evaluate the formation of mineralized nodules alizarin-red S staining was performed at 0,4,7 and 14 days. Expression of cementum matrix genes was measured by RT-PCR. Mineralization of cementoblasts was accelerated with CM from odontoblastic MDPC-23 and OD-11. The expression of BSP, ALP, and OC mRNA in cementoblastic OCCM-30 cells was facilitated by the MDPC-23 and OD-11 cells. The extracted dNCPs had little influence on the proliferation, cell cycle modification, and chemotaxis of OCCM-30 cells. Although the dNCPs did not exhibit chemotactic activities for cementoblasts, the dNCPs promoted the differentiation and mineralization of cementoblasts. In conclusion, the dentin matrix protein, or the secreted products of odontoblast, facilitates cementoblast differentiation and mineralization. This represents a new approach and suggests another avenue for cementum regeneration.

Spatiotemporal expressions of microRNAs (miRNAs) are altered by the physiological states of cells which could be influenced by microenvironment. Function of miRNAs has been focused as a new regulator of gene expressions and cell differentiation in human health and diseases. We found and identified the several miRNAs, which were related to developmental competence of preimplantation and implantation process of mouse blastocysts and outgrowth embryos by microarray-based bioinformatical studies. In this study, we evaluated three miRNAs expressions related to third cleavage event in conditioned media (CM) and blastocysts. Mouse 2-cell stage embryos were collected and monitored for 9 hours. The embryos were divided two groups as early third cleavage before 9 hours of collection and late third cleavage after 9 hours of collection. They were cultured to blastocyst stage up to day-5 after hCG injection. The total number of cells and the number of cells with fragmented DNA were assessed in blastocysts by terminal dUTP nick-end labelling (TUNEL) staining and DAPI staining. Mean cell number of early third cleavage group was significantly higher than that of late third cleavage group (105.3±8.0 vs 81.8±7.0, p<0.05), but apoptotic index was not different. The miRNAs of CM and blastocysts from early and late group were prepared, and quantified by qRT-PCR with TaqMan probes. The expression levels of three miRNAs (mmu-let-7b, mmu-miR-183, and mmu-miR-429) in CM and blastocysts were slightly upregulated in late third cleavage group. Our study suggested that the expression level of miRNAs could be altered with embryo quality, and miRNAs in CM may be used to predict miRNAs expression of embryos and developmental competence.