FAM19A5 is a secretory protein that is predominantly expressed in the brain. Although the FAM19A5 gene has been found to be associated with neurological and/or psychiatric diseases, only limited information is available on its function in the brain. Using FAM19A5-LacZ knock-in mice, we determined the expression pattern of FAM19A5 in developing and adult brains and identified cell types that express FAM19A5 in naïve and traumatic brain injury (TBI)–induced brains. According to X-gal staining results, FAM19A5 is expressed in the ventricular zone and ganglionic eminence at a very early stage of brain development, suggesting its functions are related to the generation of neural stem cells and oligodendrocyte precursor cells (OPCs). In the later stages of developing embryos and in adult mice, FAM19A5 expression expanded broadly to particular regions of the brain, including layers 2/3 and 5 of the cortex, cornu amonis (CA) region of the hippocampus, and the corpus callosum. X-gal staining combined with immunostaining for a variety of cell-type markers revealed that FAM19A5 is expressed in many different cell types, including neurons, OPCs, astrocytes, and microglia; however, only some populations of these cell types produce FAM19A5. In a subpopulation of neuronal cells, TBI led to increased X-gal staining that extended to the nucleus, marked by slightly condensed content and increased heterochromatin formation along the nuclear border. Similarly, nuclear extension of X-gal staining occurred in a subpopulation of OPCs in the corpus callosum of the TBI-induced brain. Together, these results suggest that FAM19A5 plays a role in nervous system development from an early stage and increases its expression in response to pathological conditions in subsets of neurons and OPCs of the adult brain.
FAM19A5 (also called TAFA5) is a novel secretory protein that is primarily expressed in the brain. However, a recent study reported that FAM19A5 is an adipocyte-derived adipokine that regulates vascular smooth muscle function. Furthermore, genome-wide association study (GWAS) and RNA-seq analyses revealed that the FAM19A5 was associated with a variety of diseases and tumorigenesis in peripheral tissues. We investigated FAM19A5 transcript and protein levels in the FAM19A5 peripheral expression 2 peripheral tissues, including adipose tissues from wild-type, FAM19A5 knock-out, and LacZ knock-in mice. In general, total FAM19A5 transcript levels in the central and peripheral nervous systems were higher than levels in any of the peripheral tissues including adipose tissues. Brain tissues expressed similar levels of the FAM19A5 transcript isoforms 1 and 2, whereas expression in the peripheral tissues predominantly expressed isoform 2. In the peripheral tissues, but not the brain, FAM19A5 protein levels in adipose and reproductive tissues were below detectable limits for analysis by Western blot. Additionally, we found that FAM19A5 protein did not interact with the S1PR2 receptor for G-protein-mediated signal transduction, β-arrestin recruitment, and ligandmediated internalization. Instead, FAM19A5 was internalized into HEK293 cells in an extracellular matrix protein-dependent manner. Taken together, the present study determined basal levels of FAM19A5 transcripts and proteins in peripheral tissues, which provides compelling evidence to further investigate the function of FAM19A5 in peripheral tissues under pathological conditions, including metabolic diseases and/or tumorigenesis.
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