Evaluation of Known Human PDE Inhibitors Against Nematode PDE4s

Abstract

AbstractParasitic nematodes are responsible for more than one and a half billion infections world-wide. The drugs developed against these infections only target a few different proteins. As drug resistance is becoming more common, there is a need to develop new drugs against new targets. Cyclic Nucleotide Phosphodiesterases (PDEs), are enzymes that hydrolyze the cyclic molecules of cyclic AMP and cyclic GMP. Physical properties of mammalian PDEs have led them to become well-established as drug targets. Mammals possess 11 families of PDEs, many of which are the target of selective and potent drugs. Nematodes have 6 PDE genes representing 6 families, which have not been well-studied;C. elegans, is a model organism nematode that would allow people to assess the therapeutic benefit of targeting PDEs. The Hoffman Lab has developed a platform for discovering PDE inhibitors and has carried out high-throughput screens (HTS) to help identify inhibitors of mammalian PDE4, PDE7, PDE8, and PDE11 families. The PDE4 family inC. elegansis of particular interest as work inC. eleganssuggests that it may be involved in neuronal function. However, research has shown that two compounds developed against mammalian PDE4s generally do not work onC. elegansPDE4. Therefore, the goal of this project is to screen a collection of compounds discovered by the Hoffman Lab to identify the compounds that will affectC. elegansor parasitic nematode PDE4s to find compounds that could then be tested for their effect onC. elegansand parasitic nematodes. This research could then identify an effective new target for drug development to treat infections by parasitic nematodes.SummaryParasitic nematodes are the soil worms responsible for more than one and a half billion infections around the world. While drugs are being developed against them, these drugs are designed against relatively few proteins, which is a problem as drug resistance becomes more common. Therefore, there is a need for new drugs. PDEs are enzymes that hydrolyze the signaling molecules cAMP and cGMP. Mammalian PDEs have been well-established as drug targets. In nematodes, there are 6 PDE genes representing 6 families of the 11 families found in mammals. Additionally, a free-living model organism nematode,Caenorhabditis elegans(C. elegans) can be used to assess the impact of PDE inhibition on nematode biology. In the Hoffman Lab, they have developed a platform for discovering PDE inhibitors and have used these in high throughput screens to identify inhibitors of mammalian PDE4, PDE7, PDE8, and PDE11 families. The PDE4 family inC. elegansis of particular interest as work inC. eleganssuggests that it may be involved in neuronal function. However, research has shown that compounds developed against mammalian PDE4s generally do not work onC. elegansPDE4. Therefore, by the end of this project we hope to identify the compounds that do work on nematode PDE4s that could be used to test whether they have the potential to treat these infections.