In Vitro Cell Dev Biol Anim
January 2015
Generating male germ cells in vitro from multipotent stem cells is still a challenge for stem cell biologists. The difficulty is caused by the lack of knowledge about spermatogenesis molecular-controlling mechanisms. In vivo, PGCs differentiate into male germ cells in a very complicated environment through many middle steps.
View Article and Find Full Text PDFObjective: To observe the relative activity of sperm mitochondria and the proportion of ROS-positive sperm before and after capacitation and progesterone (Pg)-induced hyperactivation, and investigate the functional characteristics of sperm mitochondria.
Methods: We collected 20 samples of normal human spermatozoa that met the criteria of WHO Laboratory Manual for the Examination and Processing of Human Semen (5th ed) and cultured them with the swim-up method in a CO2 incubator at 37 degrees C for 1 hour. We divided the sperm into a pre-capacitation and a capacitated group, and further incubated the capacitated sperm in an upright tube with (Pg-induced group) or without (control group) slow-releasing Pg at 37 degrees C for another hour.
Background: It has been proven that c-kit is crucial for proliferation, migration, survival and maturation of spermatogenic cells. A periodic expression of c-kit is observed from primordial germ cells (PGCs) to spermatogenetic stem cells (SSCs), However, the expression profile of c-kit during the entire spermatogenesis process is still unclear. This study aims to reveal and compare c-kit expression profiles in the SSCs before and after the anticipated differentiation, as well as to examine its relationship with retinoic acid (RA) stimulation.
View Article and Find Full Text PDFSpermatogenesis is the process of production of male gametes from SSCs. The SSCs are the stem cells that differentiate into male gametes in the testis. in the mean time, the Spg are remarkable for their potential multiple trans-differentiations, which make them greatly invaluable for clinical applications.
View Article and Find Full Text PDFMultiple genetic modifications in pigs can essentially benefit research on agriculture, human disease and xenotransplantation. Most multi-transgenic pigs have been produced by complex and time-consuming breeding programs using multiple single-transgenic pigs. This study explored the feasibility of producing multi-transgenic pigs using the viral 2A peptide in the light of previous research indicating that it can be utilized for multi-gene transfer in gene therapy and somatic cell reprogramming.
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