Microglial depletion after brain injury prolongs inflammation and impairs brain repair, adult neurogenesis and pro-regenerative signaling.

The adult zebrafish brain, unlike mammals, has a remarkable regenerative capacity. Although inflammation in part hinders regeneration in mammals, it is necessary for zebrafish brain repair. Microglia are resident brain immune cells that regulate the inflammatory response. To explore the microglial role in repair, we used liposomal clodronate or colony stimulating factor-1 receptor (csf1r) inhibitor to suppress microglia after brain injury, and also examined regeneration in two genetic mutant lines that lack microglia. We found that microglial ablation impaired telencephalic regeneration after injury. Microglial suppression attenuated cell proliferation at the intermediate progenitor cell amplification stage of neurogenesis. Notably, the loss of microglia impaired phospho-Stat3 (signal transducer and activator of transcription 3) and ß-Catenin signaling after injury. Furthermore, the ectopic activation of Stat3 and ß-Catenin rescued neurogenesis defects caused by microglial loss. Microglial suppression also prolonged the post-injury inflammatory phase characterized by neutrophil accumulation, likely hindering the resolution of inflammation. These findings reveal specific roles of microglia and inflammatory signaling during zebrafish telencephalic regeneration that should advance strategies to improve mammalian brain repair.

Distinct Roles of SELENOF in Different Human Cancers.

SELENOF, previously known as SEP15, is a selenoprotein that contains selenium in the form of the amino acid selenocysteine. Like other selenoproteins, the role for SELENOF in carcinogenesis has been investigated due to its altered expression compared to the corresponding normal tissue, its molecular function, and the association of genetic variations in the SELENOF gene to cancer risk or outcome. This review summarizes SELENOF's discovery, structure, cellular localization, and expression. SELENOF belongs to a new family of thioredoxin-like proteins. Published data summarized here indicate a likely role for SELENOF in redox protein quality control, and in the regulation of lipids, glucose, and energy metabolism. Current evidence indicates that loss of SELENOF contributes to the development of prostate and breast cancer, while its loss may be protective against colon cancer. Additional investigation into SELENOF's molecular mechanisms and its impact on cancer is warranted.

Selenium and breast cancer - An update of clinical and epidemiological data.

There is an urgent need for new and improved therapeutic strategies in breast cancer, which is the most common malignancy affecting women in the United States and worldwide. Selenium (Se) is an essential trace element of the human diet and plays a critical role in many aspects of human health. Clinical and epidemiological studies summarized here clearly demonstrate that Se status correlates with breast cancer survival. As a result, one way to curb breast cancer mortality would be via Se supplementation, especially in patients with severely deplete Se status. Se manifests its biological activity through incorporation into selenoproteins as selenocysteine. However, a better understanding of tissue-specific mechanisms and roles for selenoproteins in general is required. Additionally, many human selenoproteins harbor single nucleotide polymorphisms, which impact protein expression and activity and have been associated with cancer susceptibility or impacting survival. Increasing evidence indicates that these genetic variations impinge on the interactions between Se and breast cancer. This highlights the importance of integrating the Se status with genetic factors to fully define the benefit of Se in breast cancer. While Se supplementation would clearly benefit a subset of patients, this requires first the identification of at-risk patients and warrants validation through intervention trials.