ANGPTL8

The ANGPTL8 gene lies on mouse chromosome 9 (gene symbol: Gm6484) and on human chromosome 19 (gene symbol: C19orf80). ==Discovery==

The ANGPTL8 gene was discovered in 2012 as Lipasin, RIFL, and ANGPTL8. In 2013 it was suggested by Melton and Yi from Harvard that ANGPTL8 promotes mouse pancreatic islet cell proliferation. These results led the authors to propose an alternative name for ANGPTL8, betatrophin. However, the link between ANGPTL8 and islet proliferation was quickly proven false by other researchers. In fact, in December 2016 the original paper by Melton and Yi was retracted, putting the link between ANGPTL8 and islets cells to rest. Nevertheless, the name betatrophin continues to be used. Given the homology of ANGPTL8 with ANGPTL4 and ANGPTL3, and considering that ANGPTL8 does not promote beta cell proliferation, the name betatrophin should be abandoned in favor of ANGPTL8. == Function ==

The encoded 22 kDa protein contains an N-terminal secretion signal and two coiled-coil domains and is a member of the angiopoietin-like (ANGPTL) protein family. However, in contrast to other ANGPTL proteins, ANGPTL8 lacks the C-terminal fibrinogen-like domain, and therefore it is an atypical member of the ANGPTL family. ANGPTL8 has been shown to form complexes with ANGPTL3 with an apparent stoichiometry of 3:1 of ANGPTL3 to ANGPTL8 respectively. Formation of these complexes appears to require intracellular co-folding as mixing of ANGPTL8 and ANGPTL3 extracellularly does not result in complex formation. ANGPTL8 is expressed in the hepatic tissue and secreted into circulation, in order for the efficient secretion of ANGPTL8 it must form a complex with ANGPTL3. In mice ANGPTL8 is secreted by the liver and by adipose tissue, hepatic overexpression of ANGPTL8 causes elevation of circulating Triglyceride levels. as suggested by the ANGPTL3-4-8 model. Sustained ANGPTL3/8 activity, as seen in APOA5 deficiency, leads to reduced LPL abundance and activity in the heart arterial endothelium. ANGPTL8 was proposed to increase the rate at which beta-cells undergo cell division. Injection of mice with ANGPTL8 cDNA lowered blood sugar (i.e. hypoglycemia), presumably due to action at the pancreas. However, treatment of human islets with ANGPTL8 is unable to increase beta-cell division. Furthermore, studies in ANGPTL8 knock-out mice do not support a role of ANGPTL8 in controlling beta cell growth, yet point to a clear role in regulating plasma triglyceride levels. Based on these studies, it is fairly safe to say that the notion that ANGPTL8 promotes beta cell expansion is dead, which was made official by the retraction of the original paper. Deletion of ANGPTL8 does not seem to impact glucose and insulin tolerance in mice. == Structure ==

Three dimensional structure of none of the members of Angiopoietin like proteins (ANGPTLs) is available up until now. However, the structure of ANGPTL8 was predicted by homology modeling and is also reported in literature. It consists of alpha helices and its sequence show high similarity with the coiled-coil domains of ANGPTL3 and ANGPTL4. == Pathway ==

The ANGPTL8 regulatory pathway has been constructed recently by integrating the information of its known transcription factors which is available at WikiPathways data repository with the pathway id WP3915. == Clinical significance ==

It was hoped that ANGPTL8 or its homolog in humans may provide an effective treatment for type 2 diabetes and perhaps even type I diabetes. In a clinical trial, a human ANGPTL3/8 monoclonal antibody reduced the concentration of triglycerides (-70%), and low-density lipoprotein cholesterol (-32%), while increasing HDL- cholesterol (+27%), representing a promising therapy for multiple lipid disorders. == References ==