We show here that both SHIP1 (Inpp5d) and its paralog SHIP2 (Inppl1) are expressed at protein level in microglia. To examine whether targeting of SHIP paralogs might influence microglial physiology and function, we tested the capacity of SHIP1-selective, SHIP2-selective and pan-SHIP1/2 inhibitors for their ability to impact on microglia proliferation, lysosomal compartment size and phagocytic function. We find that highly potent pan-SHIP1/2 inhibitors can significantly increase lysosomal compartment size, and phagocytosis of dead neurons and amyloid beta (Aβ) 1−42 by microglia in vitro. We show that one of the more-potent and watersoluble pan-SHIP1/2 inhibitors, K161, can penetrate the blood-brain barrier. Consistent with this, K161 increases the capacity of CNS-resident microglia to phagocytose Aβ and apoptotic neurons following systemic administration. These findings provide the first demonstration that small molecule modulation of microglia function in vivo is feasible, and suggest that dual inhibition of the SHIP1 and 2 paralogs can provide a novel means to enhance basal microglial homeostatic functions for therapeutic purposes in Alzheimer's disease and, possibly, other types of dementia where increased microglial function could be beneficial.
Modulating the activity of the Src Homology 2 (SH2) — containing Inositol 5′-Phosphatase (SHIP) enzyme family with small molecule inhibitors provides a useful and unconventional method of influencing cell signaling in the PI3K pathway. The development of small molecules that selectively target one of the SHIP paralogs (SHIP1 or SHIP2) as well as inhibitors that simultaneously target both enzymes have provided promising data linking the phosphatase activity of the SHIP enzymes to disorders and disease states that are in dire need of new therapeutic targets. These include cancer, immunotherapy, diabetes, obesity, and Alzheimer's disease. In this mini-review, we will provide a brief overview of research in these areas that support targeting SHIP1, SHIP2 or both enzymes for therapeutic purposes.
A new synthesis of the indane based SHIP1 agonist AQX-1125 was developed. Testing of AQX-1125 and some analogs provides information on the pharmacophore and bioactivity.
Previously a small molecule SHIP inhibitor, K118, was shown to reverse high-fat diet induced obesity and improve blood glucose regulation in obese mice. K118 treatment was also found to increase the frequency and number of IL-4 producing eosinophils in the visceral fat as well as two potent immunoregulatory myeloid cell populations: M2-polarized macrophages and myeloid derived suppressor cells (MDSC) suggesting an immune regulatory mechanism. However, the cell(s) or SHIP paralog that should be targeted to improve metabolic regulation were not defined. Here we extend our understanding of how chemical inhibition of SHIP paralogs improves metabolic regulation during excess caloric intake. We compare different SHIP inhibitors in an obesity prevention model and find that selective inhibitors for SHIP1 or SHIP2 lack the ability to prevent weight gain and body fat accumulation during increased caloric intake. Surprisingly, only pan-SHIP1/2 inhibitors could prevent diet-induced obesity. We confirm that both SHIP1 and SHIP2 must be targeted by showing that dual treatment with the SHIP1 and SHIP2 selective inhibitors can reduce adiposity caused by excess caloric consumption. We also show that pan-SHIP1/2 inhibitors of two different chemical classes can control diet-induced obesity and improve blood glucose regulation. Intriguingly, we find that both classes of pan-SHIP1/2 inhibitors require an intact eosinophil compartment to prevent diet-related fat accumulation demonstrating pan-SHIP1/2 inhibitors act via the VAT innate immune compartment to control adiposity However, improved blood glucose regulation by pan-SHIP1/2 inhibition is not dependent upon eosinophils, indicating a separate mechanism of action for diet-related loss of glucose regulation.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.