Abstract
The social amoeba Dictyostelium discoideum was instrumental in the discovery and early characterization of inositol pyrophosphates, a class of molecules possessing highly-energetic pyrophosphate bonds. Inositol pyrophosphates regulate diverse biological processes and are attracting attention due to their ability to control energy metabolism and insulin signalling. However, inositol pyrophosphate research has been hampered by the lack of simple experimental procedures to study them. The recent development of polyacrylamide gel electrophoresis (PAGE) and simple staining to resolve and detect inositol pyrophosphate species has opened new investigative possibilities. This technology is now commonly applied to study in vitro enzymatic reactions. Here we employ PAGE technology to characterize the D. discoideum inositol pyrophosphate metabolism. Surprisingly, only three major bands are detectable after resolving acidic extract on PAGE. We have demonstrated that these three bands correspond to inositol hexakisphosphate (IP6 or Phytic acid) and its derivative inositol pyrophosphates, IP7 and IP8. Biochemical analyses and genetic evidence were used to establish the genuine inositol phosphate nature of these bands. We also identified IP9 in D. discoideum cells, a molecule so far detected only from in vitro biochemical reactions. Furthermore, we discovered that this amoeba possesses three different inositol pentakisphosphates (IP5) isomers, which are largely metabolised to inositol pyrophosphates. Comparison of PAGE with traditional Sax-HPLC revealed an underestimation of the cellular abundance of inositol pyrophosphates by traditional methods. In fact our study revealed much higher levels of inositol pyrophosphates in D. discoideum in the vegetative state than previously detected. A three-fold increase in IP8 was observed during development of D. discoideum a value lower that previously reported. Analysis of inositol pyrophosphate metabolism using ip6k null amoeba revealed the absence of developmentally-induced synthesis of inositol pyrophosphates, suggesting that the alternative class of enzyme responsible for pyrophosphate synthesis, PP-IP5K, doesn’t’ play a major role in the IP8 developmental increase.
Highlights
The model organism Dictyostelium discoideum, originally developed to study the transition to multicellularity, has subsequently been utilised in several areas of biology from chemotaxis [1] to transcriptional control [2]
Extract from vegetative Wild Type AX2 (WT) D. discoideum cells reveals the presence of three major bands by Toluidine staining
We show the huge potential of this technology to study inositol pyrophosphate metabolism in D. discoideum
Summary
The model organism Dictyostelium discoideum, originally developed to study the transition to multicellularity, has subsequently been utilised in several areas of biology from chemotaxis [1] to transcriptional control [2]. The Dictyosteliidae slime moulds are able to aggregate into multicellular forms, a process regulated by cAMP signaling [3]. In the late 1980s this model organism began to offer insight into the metabolism of inositol phosphates [4]. It was in D. discoideum that the synthesis of inositol hexakisphosphates (IP6) through direct phosphorylation of inositol was discovered [5]
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