Jasmonic acid perception by COI1 involves inositol polyphosphates in Arabidopsis thaliana

Plant responses to wounding are part of their defense responses against insects, and are tightly regulated. The isoleucin conjugate of jasmonic acid (JA‐Ile) is a major regulatory molecule. We have previously shown that inositol polyphosphate signals are required for defense responses in Arabidopsis; however, the way in which inositol polyphosphates contribute to plant responses to wounding has so far remained unclear. Arabidopsis F‐box proteins involved in the perception of JA‐Ile (COI1) and auxin (TIR1) are structurally similar. Because TIR1 has recently been shown to contain inositol hexakisphosphate (InsP₆) as a co‐factor of unknown function, here we explored the possibility that InsP₆ or another inositol polyphosphate is required for COI1 function. In support of this hypothesis, COI1 variants with changes in putative inositol polyphosphate coordinating residues exhibited a reduced interaction with the COI1 target, JAZ9, in yeast two‐hybrid tests. The equivalent COI1 variants displayed a reduced capability to rescue jasmonate‐mediated root growth inhibition or silique development in Arabidopsis coi1 mutants. Yeast two‐hybrid tests using wild‐type COI1 in an ipk1Δ yeast strain exhibiting increased levels of inositol pentakisphosphate (InsP₅) and reduced levels of InsP₆ indicate an enhanced COI1/JAZ9 interaction. Consistent with these findings, Arabidopsis ipk1‐1 mutants, also with increased InsP₅ and reduced InsP₆ levels, showed increased defensive capabilities via COI1‐mediated processes, including wound‐induced gene expression, defense against caterpillars or root growth inhibition by jasmonate. The combined data from experiments using mutated COI1 variants, as well as yeast and Arabidopsis backgrounds altered in inositol polyphosphate metabolism, indicate that an inositol polyphosphate, and probably InsP₅, contributes to COI1 function.     

Two inositol hexakisphosphate kinases drive inositol pyrophosphate synthesis in plants

Inositol pyrophosphates are unique cellular signaling molecules with recently discovered roles in energy sensing and metabolism. Studies in eukaryotes have revealed that these compounds have a rapid turnover, and thus only small amounts accumulate. Inositol pyrophosphates have not been the subject of investigation in plants even though seeds produce large amounts of their precursor, myo‐inositol hexakisphosphate (InsP₆). Here, we report that Arabidopsis and maize InsP₆ transporter mutants have elevated levels of inositol pyrophosphates in their seed, providing unequivocal identification of their presence in plant tissues. We also show that plant seeds store a little over 1% of their inositol phosphate pool as InsP₇ and InsP₈. Many tissues, including, seed, seedlings, roots and leaves accumulate InsP₇ and InsP₈, thus synthesis is not confined to tissues with high InsP₆. We have identified two highly similar Arabidopsis genes, AtVip1 and AtVip2, which are orthologous to the yeast and mammalian VIP kinases. Both AtVip1 and AtVip2 encode proteins capable of restoring InsP₇ synthesis in yeast mutants, thus AtVip1 and AtVip2 can function as bonafide InsP₆ kinases. AtVip1 and AtVip2 are differentially expressed in plant tissues, suggesting non‐redundant or non‐overlapping functions in plants. These results contribute to our knowledge of inositol phosphate metabolism and will lay a foundation for understanding the role of InsP₇ and InsP₈ in plants.     

Structural analysis and detection of biological inositol pyrophosphates reveal that the family of VIP/diphosphoinositol pentakisphosphate kinases are 1/3-kinases

We have characterized the positional specificity of the mammalian and yeast VIP/diphosphoinositol pentakisphosphate kinase (PPIP5K) family of inositol phosphate kinases. We deployed a microscale metal dye detection protocol coupled to a high performance liquid chromatography system that was calibrated with synthetic and biologically synthesized standards of inositol pyrophosphates. In addition, we have directly analyzed the structures of biological inositol pyrophosphates using two-dimensional 1H-1H and 1H-31P nuclear magnetic resonance spectroscopy. Using these tools, we have determined that the mammalian and yeast VIP/PPIP5K family phosphorylates the 1/3-position of the inositol ring in vitro and in vivo. For example, the VIP/PPIP5K enzymes convert inositol hexakisphosphate to 1/3-diphosphoinositol pentakisphosphate. The latter compound has not previously been identified in any organism. We have also unequivocally determined that 1/3,5-(PP)2-IP4 is the isomeric structure of the bis-diphosphoinositol tetrakisphosphate that is synthesized by yeasts and mammals, through a collaboration between the inositol hexakisphosphate kinase and VIP/PPIP5K enzymes. These data uncover phylogenetic variability within the crown taxa in the structures of inositol pyrophosphates. For example, in the Dictyostelids, the major bis-diphosphoinositol tetrakisphosphate is 5,6-(PP)2-IP4 ( Laussmann, T., Eujen, R., Weisshuhn, C. M., Thiel, U., Falck, J. R., and Vogel, G. (1996) Biochem. J. 315, 715-725 ). Our study brings us closer to the goal of understanding the structure/function relationships that control specificity in the synthesis and biological actions of inositol pyrophosphates.     

Inositol Pyrophosphates Modulate S Phase Progression after Pheromone-induced Arrest in Saccharomyces cerevisiae

Several studies have demonstrated the activation of phosphoinositide-specific phospholipase C (Plc) in nuclei of mammalian cells during synchronous progression through the cell cycle, but the downstream targets of Plc-generated inositol 1,4,5-trisphosphate are poorly described. Phospholipid signaling in the budding yeast Saccharomyces cerevisiae shares similarities with endonuclear phospholipid signaling in mammals, and many recent studies point to a role for inositol phosphates, including InsP₅, InsP₆, and inositol pyrophosphates, in mediating the action of Plc. In this study, we investigated the changes in inositol phosphate levels in α-factor-treated S. cerevisiae, which allows cells to progress synchronously through the cell cycle after release from a G₁ block. We found an increase in the activity of Plc1 early after release from the block with a concomitant increase in the levels of InsP₇ and InsP₈. Treatment of cells with the Plc inhibitor {"type":"entrez-nucleotide","attrs":{"text":"U73122","term_id":"4098075","term_text":"U73122"}}U73122 prevented increases in inositol phosphate levels and blocked progression of cells through S phase after pheromone arrest. The enzymatic activity of Kcs1 in vitro and HPLC analysis of [³H]inositol-labeled kcs1Δ cells confirmed that Kcs1 is the principal kinase responsible for generation of pyrophosphates in synchronously progressing cells. Analysis of plc1Δ, kcs1Δ, and ddp1Δ yeast mutants further confirmed the role that a Plc1- and Kcs1-mediated increase in pyrophosphates may have in progression through S phase. Our data provide genetic, metabolic, and biochemical evidence that synthesis of inositol pyrophosphates through activation of Plc1 and Kcs1 plays an important role in the signaling response required for cell cycle progression after mating pheromone arrest.     

Understanding inositol pyrophosphate metabolism and function: Kinetic characterization of the DIPPs

We illuminate the metabolism and the cell-signaling activities of inositol pyrophosphates, by showing that regulation of yeast cyclin-kinase by 1-InsP₇ is not conserved for mammalian CDK5, and by kinetically characterizing Ddp1p/DIPP-mediated dephosphorylation of 1-InsP₇, 5-InsP₇ and InsP₈. Each phosphatase exhibited similar K_m values for every substrate (range: 35–148 nM). The rank order of k_cat values (1-InsP₇ > 5-InsP₇ = InsP₈) was identical for each enzyme, although DIPP1 was 10- to 60-fold more active than DIPP2α/β and DIPP3α/β. We demonstrate InsP₈ dephosphorylation preferentially progresses through 1-InsP₇. Conversely, we conclude that the more metabolically and functionally significant steady-state route of InsP₈ synthesis proceeds via 5-InsP₇.     

The kinetic properties of a human PPIP5K reveal that its kinase activities are protected against the consequences of a deteriorating cellular bioenergetic environment

We obtained detailed kinetic characteristics–stoichiometry, reaction rates, substrate affinities and equilibrium conditions–of human PPIP5K2 (diphosphoinositol pentakisphosphate kinase 2). This enzyme synthesizes ‘high-energy’ PP-InsPs (diphosphoinositol polyphosphates) by metabolizing InsP₆ (inositol hexakisphosphate) and 5-InsP₇ (5-diphosphoinositol 1,2,3,4,6-pentakisphosphate) to 1-InsP₇ (1-diphosphoinositol 2,3,4,5,6-pentakisphosphate) and InsP₈ (1,5-bis-diphosphoinositol 2,3,4,6-tetrakisphosphate), respectively. These data increase our insight into the PPIP5K2 reaction mechanism and clarify the interface between PPIP5K catalytic activities and cellular bioenergetic status. For example, stochiometric analysis uncovered non-productive, substrate-stimulated ATPase activity (thus, approximately 2 and 1.2 ATP molecules are utilized to synthesize each molecule of 1-InsP₇ and InsP₈, respectively). Impaired ATPase activity of a PPIP5K2-K248A mutant increased atomic-level insight into the enzyme''s reaction mechanism. We found PPIP5K2 to be fully reversible as an ATP-synthase in vitro, but our new data contradict previous perceptions that significant ‘reversibility’ occurs in vivo. PPIP5K2 was insensitive to physiological changes in either [AMP] or [ATP]/[ADP] ratios. Those data, together with adenine nucleotide kinetics (ATP K_m=20–40 μM), reveal how insulated PPIP5K2 is from cellular bioenergetic challenges. Finally, the specificity constants for PPIP5K2 revise upwards by one-to-two orders of magnitude the inherent catalytic activities of this enzyme, and we show its equilibrium point favours 80–90% depletion of InsP₆/5-InsP₇.     

Analysis of Dictyostelium discoideum Inositol Pyrophosphate Metabolism by Gel Electrophoresis

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.     

Arabidopsis inositol phosphate kinases IPK1 and ITPK1 constitute a metabolic pathway in maintaining phosphate homeostasis

Emerging studies have suggested that there is a close link between inositol phosphate (InsP) metabolism and cellular phosphate (P_i) homeostasis in eukaryotes; however, whether a common InsP species is deployed as an evolutionarily conserved metabolic messenger to mediate P_i signaling remains unknown. Here, using genetics and InsP profiling combined with P_i‐starvation response (PSR) analysis in Arabidopsis thaliana, we showed that the kinase activity of inositol pentakisphosphate 2‐kinase (IPK1), an enzyme required for phytate (inositol hexakisphosphate; InsP₆) synthesis, is indispensable for maintaining P_i homeostasis under P_i‐replete conditions, and inositol 1,3,4‐trisphosphate 5/6‐kinase 1 (ITPK1) plays an equivalent role. Although both ipk1‐1 and itpk1 mutants exhibited decreased levels of InsP₆ and diphosphoinositol pentakisphosphate (PP‐InsP₅; InsP₇), disruption of another ITPK family enzyme, ITPK4, which correspondingly caused depletion of InsP₆ and InsP₇, did not display similar P_i‐related phenotypes, which precludes these InsP species from being effectors. Notably, the level of d /l ‐Ins(3,4,5,6)P₄ was concurrently elevated in both ipk1‐1 and itpk1 mutants, which showed a specific correlation with the misregulated P_i phenotypes. However, the level of d /l ‐Ins(3,4,5,6)P₄ is not responsive to P_i starvation that instead manifests a shoot‐specific increase in the InsP₇ level. This study demonstrates a more nuanced picture of the intersection of InsP metabolism and P_i homeostasis and PSRs than has previously been elaborated, and additionally establishes intermediate steps to phytate biosynthesis in plant vegetative tissues.     

Structural basis for an inositol pyrophosphate kinase surmounting phosphate crowding

Inositol pyrophosphates (such as IP7 and IP8) are multifunctional signaling molecules that regulate diverse cellular activities. Inositol pyrophosphates have 'high-energy' phosphoanhydride bonds, so their enzymatic synthesis requires that a substantial energy barrier to the transition state be overcome. Additionally, inositol pyrophosphate kinases can show stringent ligand specificity, despite the need to accommodate the steric bulk and intense electronegativity of nature's most concentrated three-dimensional array of phosphate groups. Here we examine how these catalytic challenges are met by describing the structure and reaction cycle of an inositol pyrophosphate kinase at the atomic level. We obtained crystal structures of the kinase domain of human PPIP5K2 complexed with nucleotide cofactors and either substrates, product or a MgF(3)(-) transition-state mimic. We describe the enzyme's conformational dynamics, its unprecedented topological presentation of nucleotide and inositol phosphate, and the charge balance that facilitates partly associative in-line phosphoryl transfer.     

Inositol pyrophosphates as multifaceted metabolites in the regulation of mammalian signaling networks

Inositol pyrophosphates (PP-IPs) such as 5-diphosphoinositol pentakisphosphate (5-IP₇) are inositol metabolites with high-energy phosphoanhydride bonds. The formation of PP-IPs is catalyzed by two groups of enzymes, the IP6 kinases and the PPIP5 kinases, which both phosphorylate inositol hexakisphosphate (IP₆). In mammals, PP-IPs are implicated in diverse biological phenomena including cellular growth, vesicular trafficking, apoptosis, and metabolic homeostasis. Mechanistically, all the diverse actions of PP-IPs proceed in one of two ways: the PP-IPs modulate the activity of their target proteins either through allosteric binding or protein pyrophosphorylation. In this review, we highlight recent advances in our understanding of the pleiotropic functions of the mammalian PP-IPs and the metabolic enzymes that produce them. We also discuss some future challenges in the exploration of areas where PP-IPs play important but unknown roles in physiology and disease.     

Metabolism of inositol 1,4,5-trisphosphate in squid photoreceptors

Summary Inositol 1,4,5-trisphosphate (InsP₃) is rapidly formed in squid photoreceptors in response to light, where it is converted sequenctially into inositol bisphosphate (InsP₂) and inositol monophosphate (InsP₁). All of the InsP₃ appears to be degraded to inositol 1,4-bisphosphate via an InsP₃-phosphatase, which is characterized in this study. The enzyme is water-soluble and present in the light-transducing distal segments of squid photoreceptors. It has a K_m of 50 M for InsP₃, requires Mg⁺⁺ for its activity, is maximally active at neutral pH, specifically hydrolyses the 5-phosphate and is inhibited by 2,3-diphosphoglycerate. In these respects, InsP₃-phosphatase of squid is very similar to the enzymes of other cells. Since no InsP₄ or more highly phosphorylated inositols are found in squid photoreceptors, the InsP₃-phosphatase may be important in the regulation of InsP₃ concentration within these cells.Abbreviations InsP ₁ , InsP ₂ , InsP ₃ , InsP ₄ , InsP ₆ inositol monobis-, tris-, tetrakis-, hexakisphosphate, respectively - 2,3-DPG 2,3-diphosphoglycerate - EDTA ethylene diamine tetraacetic acid - DTT dithiothreitol - Hepes 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid - PMSF phenylmethylsulfonyl fluoride     

The type of thermal feed treatment influences the inositol phosphate composition

The content and composition of inositol phosphate phosphorus (InsP-P) in maize, wheat, barley and heat treated soybean meal, rapeseed meal and sunflower meal was determined by high-performance ion chromatography (HPIC). Approximately 0.88–0.96 of the InsP-P in the feedstuffs was present in the inositol hexaphosphate (InsP₆) form, whereas the rest was in the inositol pentaphosphate (InsP₅) form and for oilseeds a very small amount was present as inositol tetraphosphate (InsP₄). Rapeseed differed from this pattern by having as much as 300 and 60 g InsP₄-P/kg of the total InsP-P pool. The effect of pelleting (90 °C) and extrusion cooking (130–140 °C, 6.5 MPa) on the composition of InsP-P was investigated. Neither treatment had any major effect on the total content of InsP-P in the feedstuffs. However, as indicated by the statistically significant effects on the proportion of the inositol phosphates, extrusion cooking shifted the inositol phosphates from InsP₆-P towards InsP₅-P both in cereals (P=0.002) and in oilseeds (P<0.001), which show a slight degradation of phytate during this treatment. The degradation of InsP₆ to InsP₅ appeared to be unspecific with regard to isomers in all feedstuffs, indicating that the degradation was non-enzymatic, i.e. a result of the high temperature and pressure during the extrusion cooking. The degradation of InsP₆ in the feedstuffs during extrusion is too limited to have any nutritional effect on the availability of phosphorous and minerals.     

The Arabidopsis F-Box Protein CORONATINE INSENSITIVE1 Is Stabilized by SCFCOI1 and Degraded via the 26S Proteasome Pathway

Jasmonate regulates critical aspects of plant development and defense. The F-box protein CORONATINE INSENSITIVE1 (COI1) functions as a jasmonate receptor and forms Skp1/Cullin1/F-box protein COI1 (SCF^COI1) complexes with Arabidopsis thaliana Cullin1 and Arabidopsis Skp1-like1 (ASK1) to recruit its substrate jasmonate ZIM-domain proteins for ubiquitination and degradation. Here, we reveal a mechanism regulating COI1 protein levels in Arabidopsis. Genetic and biochemical analysis and in vitro degradation assays demonstrated that the COI1 protein was initially stabilized by interacting with ASK1 and further secured by assembly into SCF^COI1 complexes, suggesting a function for SCF^COI1 in the stabilization of COI1 in Arabidopsis. Furthermore, we show that dissociated COI1 is degraded through the 26S proteasome pathway, and we identified the 297th Lys residue as an active ubiquitination site in COI1. Our data suggest that the COI1 protein is strictly regulated by a dynamic balance of SCF^COI1-mediated stabilization and 26S proteasome–mediated degradation and thus maintained at a protein level essential for proper biological functions in Arabidopsis development and defense responses.     

A novel method for the purification of inositol phosphates from biological samples reveals that no phytate is present in human plasma or urine

Inositol phosphates are a large and diverse family of signalling molecules. While genetic studies have discovered important functions for them, the biochemistry behind these roles is often not fully characterized. A key obstacle in inositol phosphate research in mammalian cells has been the lack of straightforward techniques for their purification and analysis. Here we describe the ability of titanium dioxide (TiO₂) beads to bind inositol phosphates. This discovery allowed the development of a new purification protocol that, coupled with gel analysis, permitted easy identification and quantification of InsP₆ (phytate), its pyrophosphate derivatives InsP₇ and InsP₈, and the nucleotides ATP and GTP from cell or tissue extracts. Using this approach, InsP₆, InsP₇ and InsP₈ were visualized in Dictyostelium extracts and a variety of mammalian cell lines and tissues, and the effects of metabolic perturbation on these were explored. TiO₂ bead purification also enabled us to quantify InsP₆ in human plasma and urine, which led to two distinct but related observations. Firstly, there is an active InsP₆ phosphatase in human plasma, and secondly, InsP₆ is undetectable in either fluid. These observations seriously question reports that InsP₆ is present in human biofluids and the advisability of using InsP₆ as a dietary supplement.