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Background Early leaf senescence influences yield and yield quality by affecting plant growth and development. A series of leaf senescence-associated molecular mechanisms have been reported in rice. However, the complex genetic regulatory networks that control leaf senescence need to be elucidated. Results In this study, an early senescence 2 ( es2 ) mutant was obtained from ethyl methanesulfonate mutagenesis (EMS)-induced mutational library for the Japonica rice cultivar Wuyugeng 7 (WYG7). Leaves of es2 showed early senescence at the seedling stage and became severe at the tillering stage. The contents of reactive oxygen species (ROS) significantly increased, while chlorophyll content, photosynthetic rate, catalase (CAT) activity significantly decreased in the es2 mutant. Moreover, genes which related to senescence, ROS and chlorophyll degradation were up-regulated, while those associated with photosynthesis and chlorophyll synthesis were down-regulated in es2 mutant compared to WYG7. The ES2 gene, which encodes an inositol polyphosphate kinase (OsIPK2), was fine mapped to a 116.73-kb region on chromosome 2. DNA sequencing of ES2 in the mutant revealed a missense mutation, ES2 was localized to nucleus and plasma membrane of cells, and expressed in various tissues of rice. Complementation test and overexpression experiment confirmed that ES2 completely restored the normal phenotype, with chlorophyll contents and photosynthetic rate increased comparable with the wild type. These results reveal the new role of OsIPK2 in regulating leaf senescence in rice and therefore will provide additional genetic evidence on the molecular mechanisms controlling early leaf senescence. Conclusions The ES2 gene, encoding an inositol polyphosphate kinase localized in the nucleus and plasma membrane of cells, is essential for leaf senescence in rice. Further study of ES2 will facilitate the dissection of the genetic mechanisms underlying early leaf senescence and plant growth.

Inositol polyphosphates (IPs) is an important family of signaling molecules that regulate multiple cellular processes, such as chromatin remodeling, transcription and mRNA export. Inositol polyphosphate kinases, as the critical enzymes for production and transformation of IPs, directly determine the intracellular levels of IPs and therefore are involved in many cellular processes. However, its roles in Candida albicans, the leading fungal pathogen in human beings, remain to be investigated. In this study, we identified the inositol polyphosphate kinase Ipk1 in C. albicans and found that it localizes in the nucleus. Moreover, in the ipk1Δ/Δ mutant, the activity of mitochondrial respiratory chain complexes and the mitochondrial function was severely impaired, which were associated with down-regulation of mitochondrial function-related genes revealed by transcription profiling analysis. The ipk1Δ/Δ mutant also displayed hypersensitivity to a series of environmental stresses, such as antifungal drugs, oxidants, cell wall perturbing agents and macrophage attacks, followed by attenuation of virulence in a mouse systematic infection model. These findings firstly reported the importance of inositol polyphosphate kinase Ipk1 in C. albicans, especially its role in mitochondrial function maintenance and pathogenicity.

Polyphosphate kinase 1 (Ppk1) catalyzes reverse transfer of the terminal phosphate from ATP to form polyphosphate (polyP) and from polyP to form ATP, and is responsible for the synthesis of most of cellular polyPs. When Ppk1 from Myxococcus xanthus was incubated with 0.2 mM polyP60−70 and 1 mM ATP or ADP, the rate of ATP synthesis was approximately 1.5-fold higher than that of polyP synthesis. If in the same reaction the proportion of ADP in the ATP/ADP mixture exceeded one-third, the equilibrium shifted to ATP synthesis, suggesting that M. xanthus Ppk1 preferentially catalyzed ATP formation. At the same time, GTP and GDP were not recognized as substrates by Ppk1. In the absence of polyP, Ppk1 generated ATP and AMP from ADP, and ADP from ATP and AMP, suggesting that the enzyme catalyzed the transfer of a phosphate group between ADP molecules yielding ATP and AMP, thus exhibiting adenylate kinase activity.

New antifungals with unique modes of action are urgently needed to treat the increasing global burden of invasive fungal infections. The fungal inositol polyphosphate kinase (IPK) pathway, comprised of IPKs that convert IP3 to IP8, provides a promising new target due to its impact on multiple, critical cellular functions and, unlike in mammalian cells, its lack of redundancy. Nearly all IPKs in the fungal pathway are essential for virulence, with IP3-4 kinase (IP3-4K) the most critical. The dibenzylaminopurine compound, N2-(m-trifluorobenzylamino)-N6-(p-nitrobenzylamino)purine (TNP), is a commercially available inhibitor of mammalian IPKs. The ability of TNP to be adapted as an inhibitor of fungal IP3-4K has not been investigated. We purified IP3-4K from the human pathogens, Cryptococcus neoformans and Candida albicans, and optimised enzyme and surface plasmon resonance (SPR) assays to determine the half inhibitory concentration (IC50) and binding affinity (KD), respectively, of TNP and 38 analogues. A novel chemical route was developed to efficiently prepare TNP analogues. TNP and its analogues demonstrated inhibition of recombinant IP3-4K from C. neoformans (CnArg1) at low µM IC50s, but not IP3-4K from C. albicans (CaIpk2) and many analogues exhibited selectivity for CnArg1 over the human equivalent, HsIPMK. Our results provide a foundation for improving potency and selectivity of the TNP series for fungal IP3-4K.

It is widely believed that deep-sea ecosystems operate independently of light, relying primarily on chemical energy. However, the discovery of non-photosynthetic bacteria in various deep-sea environments that can sense and utilize light has challenged this assumption. In a recent study, we found that blue light significantly promotes the production of zero-valent sulfur (ZVS) in the deep-sea bacterium Erythrobacter flavus 21-3. Given that long-wavelength light is more prevalent in deep-sea environments, we investigated whether infrared light also plays a role in regulating ZVS production in E. flavus 21-3. Our results indicate that infrared light does promote ZVS formation in this bacterium. We identified PPK2 as a negative regulator, maintaining intracellular ZVS at safe levels to prevent toxicity due to excessive accumulation. Overall, our study offers a valuable model for exploring how light is utilized and its interaction with microbial sulfur cycling in the extreme conditions of the deep sea.

Compared with low-yield extraction from plants and environmentally unfriendly chemical synthesis, biocatalysis by asparagine synthetase (AS) for preparation of L-asparagine (L-Asn) has become a potential synthetic method. However, low enzyme activity of AS and high cost of ATP in this reaction restricts the large-scale preparation of L-Asn by biocatalysis. In this study, gene mining strategy was used to search for novel AS with high enzyme activity by expressing them in Escherichia coli BL21 (DE3) or Bacillus subtilis WB600. The obtained Lsa AS-A was determined for its enzymatic properties and used for subsequent preparation of L-Asn. In order to reduce the use of ATP, a class III polyphosphate kinase 2 from Deinococcus ficus ( Dfi PPK2-Ⅲ) was cloned and expressed in E . coli BL21 (DE3), Rosetta (DE3) or RosettagamiB (DE3) for ATP regeneration. A coupling reaction system including whole cells expressing Lsa AS-A and Dfi PPK2-Ⅲ was constructed to prepare L-Asn from L-aspartic acid (L-Asp). Batch catalytic experiments showed that sodium hexametaphosphate (>60 mmol L −1 ) and L-Asp (>100 mmol L −1 ) could inhibit the synthesis of L-Asn. Under fed-batch mode, L-Asn yield reached 90.15% with twice feeding of sodium hexametaphosphate. A final concentration of 218.26 mmol L −1 L-Asn with a yield of 64.19% was obtained when L-Asp and sodium hexametaphosphate were fed simultaneously.

Glucose 6-phosphate is the phosphorylated form of glucose and is used as a reagent in enzymatic assays. Current production occurs via a multi-step chemical synthesis. In this study we established a fully enzymatic route for the synthesis of glucose 6-phosphate from cellulose. As the enzymatic phosphorylation requires ATP as phosphoryl donor, the use of a cofactor regeneration system is required. We evaluated Escherichia coli glucokinase and Saccharomyces cerevisiae hexokinase (HK) for the phosphorylation reaction and Pseudomonas aeruginosa polyphosphate kinase 2 (PPK2) for ATP regeneration. All three enzymes were characterized in terms of temperature and pH optimum and the effects of substrates and products concentrations on enzymatic activities. After optimization of the conditions, we achieved a 85% conversion of glucose into glucose 6-phosphate using the HK/PPK2 activities within a 24 h reaction resulting in 12.56 g/l of glucose 6-phosphate. Finally, we demonstrated the glucose 6-phosphate formation from microcrystalline cellulose in a one-pot reaction comprising Aspergillus niger cellulase for glucose release and HK/PPK2 activities. We achieved a 77% conversion of released glucose into glucose 6-phosphate, however at the expense of a lower glucose 6-phosphate yield of 1.17 g/l. Overall, our study shows an alternative approach for synthesis of glucose 6-phosphate that can be used to valorize biomass derived cellulose.

Gibberellic acid (GA) is an important plant hormone mediating plant growth and development throughout the life span. Although many GA biosynthesis genes and signaling components have been revealed, the signal transduction mechanisms from GA perception to physiological actions are still largely unclear. In this study, we investigated the functions of a rice (Oryza sativa) inositol polyphosphate kinase gene (OsIPK2) in rice growth and development, showing that OsIPK2 is a putative new player in GA signaling. OsIPK2 is widely expressed in rice with high accumulation in tender and rapidly dividing tissues. The OsIPK2 protein is mainly localized in the nucleus and plasma membrane. To study the biological roles of OsIPK2 in rice, RNA interference and overexpression transgenic plants were generated. OsIPK2 antisense plants exhibited taller seedling height and lower fertility rate than the wild type, while overexpression lines showed reduced plant height. Microarray and qRT-PCR assays showed that expression levels of several GA-related genes were altered in transgenic plants. Besides, down-regulation of OsIPK2 resulted in hypersensitivity to paclobutrazol (PAC), a GA biosynthesis inhibitor. We also described that the expression of OsIPK2 could be either induced by GA or repressed by PAC. Taken together, these findings suggested that OsIPK2 is likely a negative regulator of GA signaling and involves in modulating shoot elongation and fertility.

Polyphosphate kinase 1 (PPK1), encoded by the ppk1 gene, is one of the major enzymes to reversibly catalyze the synthesis of polyphosphate (poly P) from the terminal phosphate of ATP. Poly P confers resistance to stress in a number of bacterial species but its role in the virulence of meningitic bacterial pathogens is unknown. The aim of this study was to determine the role of PPK1 in the pathogenesis of Escherichia coli meningitis. An isogenic in-frame ppk1 deletion mutant (PD44) of E. coli K1 strain E44 was constructed and characterized. Human brain microvascular endothelial cells and neonatal rats were used as the in vitro and in vivo models, respectively, to evaluate bacterial adhesion/invasion and the abilities of bacteria crossing the blood-brain barrier (BBB) to cause meningitis. The survival of PD44 and E44 under osmotic and acid stress conditions were also examined. Poly P levels in E44 were clearly higher than those in PD44, especially at the stationary phase (SP). The ppk1 deletion mutant PD44 also showed poor survival rates during osmotic shock and acidic challenge, which the bacteria would face during pathogenesis. In vitro and in vivo assays revealed that PD44 was defective in bacterial adhesion and translocation across the BBB. By using the Evans blue method, we found that E44-induced permeability of the BBB in neonatal rats was significantly higher than that of the animals infected with PD44. Cytokine ELISA results showed that the TNF-α and IL-1β levels in the serum and brain tissues of the neonatal rats infected with PD44 were lower than that of the E44 group. A more obvious meningeal inflammation could be observed in the brain tissues of the rats infected with E44 when compared with that of the PD44 group by histopathological examination. Furthermore, the mRNA expression of IbeR, which is an RpoS-like regulator contributing to the SP regulation in E44, was found to be decreased in PD44 when compared with the parent strain. PD44 was also deficient in mRNA expression of the invasin IbeA, the adhesin FimH and the outer member protein A, which contributes to E44 penetration across BBB and resistance to the stimulations of low pH and high osmolarity. These results indicate that ppk1 plays an important role in stress adaption and virulence in meningitic E. coli K1 strain E44, and controls the relevant phenotypes by modulating the expression of the SP regulatory gene ibeR and the virulence genes ibeA, fimH and ompA.

Abstract Polyphosphate kinase 1 (Ppk1) generates polyphosphates (polyPs) by catalyzing phosphate transfer from ATP. In the presence of ATP, Myxococcus xanthus Ppk1 showed the highest activity with polyP60–70 but also showed high activity with orthophosphate and pyrophosphate. Ppk1 synthesizes long-chain polyPs with >1 000 phosphate residues from orthophosphate or pyrophosphate present in high concentrations, suggesting that in M. xanthus, Ppk1 uses intracellular ortho/pyrophosphate as an initial primer for polyP production. During M. xanthus starvation-induced development, the specific activity of Ppk1 peaked at 12 h (300–800 nmol/min/mg) and then gradually decreased. The polyP concentration was highest during mound formation (45 nmol phosphate/mg protein); then, the level of long-chain polyPs decreased and that of short-chain polyPs increased during fruiting body and spore formation. Myxococcus xanthus expresses two exopolyphosphatases, Ppx1 and Ppx2, which mainly degrade short- and long-chain polyPs, respectively, both of which were highest in vegetative cells and were detected during starvation, which may account for the degradation of polyPs. Thus, polyPs synthesized by Ppk1 early in starvation-induced development could be degraded by exopolyphosphatases and may also be used as substrates by polyP:AMP phosphotransferases and polyphosphate/ATP-NAD kinases to generate ADP and NADP+, respectively. Myxococcus xanthus synthesizes polyphosphate from phosphate/pyrophosphate during starvation-induced sporulation.