Abstract
Retinoic acid (RA) exerts biological effects through RA receptors (RARs) to regulate transcription. RA also elicits rapid, RAR-independent (noncanonical) activities mediated by Cellular RA Binding Protein 1 (CRABP1) to modulate cytosolic signaling. CRABP1 functions by forming protein complexes, named CRABP1 signalosomes, to modulate signal propagation in a cell type-specific manner. This review summarizes multiple CRABP1 signalosomes and their physiological functions. CRABP1 knockout (CKO) mice develop multiple phenotypes progressively throughout the lifespan. These include altered brain function, obesity, and insulin resistance starting at young adult stages, increased vulnerability to heart failure and altered serum exosome profiles in midlife, and motor deterioration and thyroid dysfunction (hypothyroidism) in later life. The mouse Crabp1 gene is tightly regulated by multiple epigenetic mechanisms, whereas human CRABP1 gene dysregulation is associated with multiple human diseases in which age is an important factor. Further, CRABP1 expression in human and mouse thyroid glands gradually increases with aging. This underscores the clinical relevance of CRABP1 signalosomes in maintaining health and the functions of certain cells/organ systems, especially in the thyroid and during the aging process. The CRABP1 sequence is highly conserved, likely due to its functional constraint in forming various signalosomes; its tight regulation ensures proper expression of CRABP1 required for the forming of various signalosomes critical to the health and functions of multiple cell types/organ systems. Finally, CRABP1-specific (without activating RARs) signaling pathway-selective compounds have been designed. It may be an attractive therapeutic strategy to exploit these CRABP1-specific compounds to modulate selective signaling pathways in certain disease conditions, such as thyroid dysfunction, to maximize efficacy while minimizing retinoid toxicity.