Met and Cxcr4 cooperate to protect skeletal muscle stem cells against inflammation-induced damage during regeneration.

Acute skeletal muscle injury is followed by an inflammatory response, removal of damaged tissue, and the generation of new muscle fibers by resident muscle stem cells, a process well characterized in murine injury models. Inflammatory cells are needed to remove the debris at the site of injury and provide signals that are beneficial for repair. However, they also release chemokines, reactive oxygen species, as well as enzymes for clearance of damaged cells and fibers, which muscle stem cells have to withstand in order to regenerate the muscle. We show here that MET and CXCR4 cooperate to protect muscle stem cells against the adverse environment encountered during muscle repair. This powerful cyto-protective role was revealed by the genetic ablation of Met and Cxcr4 in muscle stem cells of mice, which resulted in severe apoptosis during early stages of regeneration. TNFα neutralizing antibodies rescued the apoptosis, indicating that TNFα provides crucial cell-death signals during muscle repair that are counteracted by MET and CXCR4. We conclude that muscle stem cells require MET and CXCR4 to protect them against the harsh inflammatory environment encountered in an acute muscle injury.

MiR-1 and miR-206 target different genes to have opposing roles during angiogenesis in zebrafish embryos.

As miR-1 and miR-206 share identical seed sequences, they are commonly speculated to target the same gene. Here, we identify an mRNA encoding seryl-tRNA synthetase (SARS), which is targeted by miR-1, but refractory to miR-206. SARS is increased in miR-1-knockdown embryos, but it remains unchanged in the miR-206 knockdown. Either miR-1 knockdown or sars overexpression results in a failure to develop some blood vessels and a decrease in vascular endothelial growth factor Aa (VegfAa) expression. In contrast, sars knockdown leads to an increase of VegfAa expression and abnormal branching of vessels, similar to the phenotypes of vegfaa-overexpressed embryos, suggesting that miR-1 induces angiogenesis by repressing SARS. Unlike the few endothelial cells observed in the miR-1-knockdown embryos, knockdown of miR-206 leads to abnormal branching of vessels accompanied by an increase in endothelial cells and VegfAa. Therefore, we propose that miR-1 and miR-206 target different genes and thus have opposing roles during embryonic angiogenesis in zebrafish.

MicroRNA-3906 regulates fast muscle differentiation through modulating the target gene homer-1b in zebrafish embryos.

A microRNA, termed miR-In300 or miR-3906, suppresses the transcription of myf5 through silencing dickkopf-related protein 3 (dkk3r/dkk3a) during early development when myf5 is highly transcribed, but not at late stages when myf5 transcription is reduced. Moreover, after 24 hpf, when muscle cells are starting to differentiate, Dkk3a could not be detected in muscle tissue at 20 hpf. To explain these reversals, we collected embryos at 32 hpf, performed assays, and identified homer-1b, which regulates calcium release from sarcoplasmic reticulum, as the target gene of miR-3906. We further found that either miR-3906 knockdown or homer-1b overexpression increased expressions of fmhc4 and atp2a1 of calcium-dependent fast muscle fibrils, but not slow muscle fibrils, and caused a severe disruption of sarcomeric actin and Z-disc structure. Additionally, compared to control embryos, the intracellular calcium concentration ([Ca(2+)]i) of these treated embryos was increased as high as 83.9-97.3% in fast muscle. In contrast, either miR-3906 overexpression or homer-1b knockdown caused decreases of [Ca(2+)]i and, correspondingly, defective phenotypes in fast muscle. These defects could be rescued by inducing homer-1b expression at later stage. These results indicate that miR-3906 controls [Ca(2+)]i homeostasis in fast muscle through fine tuning homer-1b expression during differentiation to maintain normal muscle development.

Blu-ray disk lens as the objective of a miniaturized two-photon fluorescence microscope.

In this paper, we examine the performance of a Blu-ray disk (BD) aspheric lens as the objective of a miniaturized scanning nonlinear optical microscope. By combining a single 2D micro-electro mechanical system (MEMS) mirror as the scanner and with different tube lens pairs, the field of view (FOV) of the studied microscope varies from 59 µm × 93 µm up to 178 µm × 280 µm, while the corresponding lateral resolution varies from 0.6 µm to 2 µm for two-photon fluorescence (2PF) signals. With a 34/s video frame rate, in vivo dynamic observation of zebrafish heartbeat through 2PF of the excited green fluorescence protein (GFP) is demonstrated.