Abstract
Phosphatidylinositol, a glycerophospholipid with a myo-inositol head group, can form seven different phosphoinositides (PItds) by phosphorylation at inositol carbons 3, 4 and/or 5. Over 50 kinases and phosphatases participate in PItd metabolism, creating an interconnected PItd network that allows for precise temporal and spatial regulation of PItd levels. We review paradigms of PItd action, including (1) the establishment of subcellular organelle identity by the acquisition of specific PItd signatures, permitting regulation of key processes of cell biology including trafficking (exocytosis, clathrin-dependent and -independent endocytosis, formation and function of membrane contact sites, cytoskeletal remodeling), (2) signaling through phospholipase C cleavage of phosphatidylinositol 4,5-bisphosphate to inositol 1,4,5-trisphosphate and DAG, and (3) roles of PItds in molecular transport at membrane contact sites. To date, variants in 34 genes of PItd metabolism account for at least 41 distinguishable monogenic conditions. Clinical presentations of these disorders produce a broad and often multisystemic spectrum of effects. The nervous system is often involved, and muscular, immunological, skeletal, renal, ophthalmologic and dermatologic features occur in several conditions. Some syndromes involving PItd metabolism can be distinguished clinically, but most diagnoses currently result from broad molecular diagnostic testing performed for the patient's presenting clinical complaint. Genetic disorders of PItd metabolism are a broad, expanding and challenging category of inborn errors. Challenges include improved documentation of the clinical spectra, development of broad biochemical diagnostic methods for these conditions and better understanding of the PItd networks in different cells and subcellular compartments necessary for the development of disease-specific therapies.