Phosphate Metabolism Research Articles

Multi-omics analysis of sea urchin (Strongylocentrotus intermedius) adaptation to salt stress reveals epigenetic regulatory mechanisms

Increased precipitation and surface runoff due to global warming has reduced surface seawater and nearshore water salinity, affecting marine organism survival. Nevertheless, the epigenetic mechanisms underlying the adaptation of sea urchins (Strongylocentrotus intermedius) to low-salinity stress remains unknown. This study utilized response surface methodology to formulate growth models for S. intermedius at different salinity levels and shell diameters. Whole genome bisulphite sequencing, RNA-sequencing, and metabolome analysis were performed on low-salinity stressed sea urchins, and a total of 3006 differential methylated regions, 945 differential methylated genes, 886 differentially expressed genes, and 271 differential metabolites were identified. Multi-omics analysis revealed significant alterations in the gene expression and DNA methylation of key genes (e.g., SPHK2, Arpc1a, and SLC23A1) in S. intermedius under low-salinity stress conditions. These changes subsequently influenced the metabolism of substances, including sphingosine-1-phosphate, ethanolamine phosphate, vitamin C, taurine, and choline. These alterations impacted functions related to immunity, osmoregulation, and energy metabolism in the organism. This study was to comprehensively elucidate the epigenetic mechanisms of S. intermedius under low-salinity stress from the perspective of DNA-RNA-metabolites, providing new insights into salinity adaptation of marine invertebrates.

Modulation of fungal phosphate homeostasis by the plant hormone strigolactone

Inter-kingdom communication through small molecules is essential to the coexistence of organisms in an ecosystem. In soil communities, the plant root is a nexus of interactions for a remarkable number of fungi and is a source of small-molecule plant hormones that shape fungal compositions. Although hormone signaling pathways are established in plants, how fungi perceive and respond to molecules is unclear because many plant-associated fungi are recalcitrant to experimentation. Here, we develop an approach using the model fungus, Saccharomyces cerevisiae, to elucidate mechanisms of fungal response to plant hormones. Two plant hormones, strigolactone and methyl jasmonate, produce unique transcript profiles in yeast, affecting phosphate and sugar metabolism, respectively. Genetic analysis in combination with structural studies suggests that SLs require the high-affinity transporter Pho84 to modulate phosphate homeostasis. The ability to study small-molecule plant hormones in a tractable genetic system should have utility in understanding fungal-plant interactions.

Lessons from Klotho mouse models to understand mineral homeostasis.

Klotho, a key component of the endocrine fibroblast growth factor receptor-fibroblast growth factor axis, is a multi-functional protein that impacts renal electrolyte handling. The physiological significance of Klotho will be highlighted in the regulation of calcium, phosphate, and potassium metabolism. In this review, we compare several murine models with different renal targeted deletions of Klotho and the insights into the molecular and physiological function that these models offer. In vivo, Klotho deficiency is associated with severely impaired mineral metabolism, with consequences on growth, longevity and disease development. Additionally, we explore the perspectives of Klotho in renal pathology and vascular events, as well as potential Klotho treatment options. This comprehensive review emphasizes the use of Klotho to shed light on deciphering the renal molecular invivo mechanisms in electrolyte handling, as well as novel therapeutic interventions.

Bone Sialoprotein Regulates Phosphate Metabolism and Reduces Hyperparathyroidism in Mice with CKD

Bone Sialoprotein Regulates Phosphate Metabolism and Reduces Hyperparathyroidism in Mice with CKD

Study on Action and Mechanism of Potentilla discolor Bunge using Patch-Clamp to Explore the Effect of the Main Components of Potentilla discolor Bunge on Myocardial Cell Membranes

Background Potentilla discolor Bunge (PDB) is a plant of the Rosaceae family. A wide range of pharmacological activities, such as antibacterial, hypoglycemic, and others, can be achieved through its chemical components, which include terpenes, steroids, polyphenols, and flavonoids. However, the effects of the herb on the heart are unclear. Purpose To explore the effect of the main components of PDB on myocardial cell membranes. Materials and Methods We investigated the role of different concentrations of PDB in cardiomyocytes by evaluating myocardial electrical activity. We used high-performance liquid chromatography to analyze the components. Patch-clamp experiments were conducted to detect the drugs’ impact on the ion channels of cardiomyocytes. Results PDB regulated 14 potential metabolites in mice. Interestingly, quercetin exerts certain effects on the heart by acting on the inositol phosphate metabolism pathway. Quercetin is a monomer compound that can enhance the activity of IK1 on the myocardium membrane. Conclusion This study showed that monomeric compounds of PDB can significantly enhance IK1 activity and influence ion channels in a concentration-dependent manner.

Progressive bone pain caused by a phosphaturic mesenchymal tumor in the left femur: a case report and literature review.

Phosphaturic mesenchymal tumors (PMTs) are extremely rare mesenchymal tumors of soft tissue and bone that cause tumor-induced osteomalacia (TIO). Some of these tumors are completely asymptomatic and may grow undetected unless they become large enough to cause pain or discomfort. This type of tumor is crucial to diagnose in patients being treated for phosphate metabolism disorders and are a rare reason why patients seek medical help owing to pain. Here, we report the details of a patient with progressive bone pain caused by a PMT originating in the left femur.

Interface/Dipole Polarized Antibiotics-Loaded Fe3O4/PB Nanoparticles for Non-Invasive Therapy of Osteomyelitis Under Medical Microwave Irradiation.

Due to their poor light penetration, photothermal therapy and photodynamic therapy are ineffective in treating deep tissue infections, such as osteomyelitis caused by Staphylococcus aureus (S. aureus). Here, a microwave (MW)-responsive magnetic targeting composite system consisting of ferric oxide (Fe3O4)/Prussian blue (PB) nanoparticles, gentamicin (Gent), and biodegradable poly(lactic-co-glycolic acid) (PLGA) is reported. The PLGA/Fe3O4/PB/Gent complex is used in combination with MW thermal therapy (MTT), MW dynamic therapy (MDT), and chemotherapy (CT) to treat acute osteomyelitis infected with S. aureus-infected. The powerful antibacterial effect of the PLGA/Fe3O4/PB/Gent is determined by the synergistic effects of heat and reactive oxygen species (ROS) generation by the Fe3O4/PB nanoparticles under MW irradiation and the effective release of Gent at the infection site via magnetic targeting. The antibacterial mechanism of the PLGA/Fe3O4/PB/Gent under MW irradiation is analyzed using bacterial transcriptome RNA sequencing. The MW heat and ROS reduce the activity of the protein transporters on the bacterial membrane, along with the transport of various ions and the acceleration of phosphate metabolism, which can lead to increased permeability of the bacterial membrane, damage the ribosome and DNA, and accompany the internal protein efflux of the bacteria, thus effectively killing the bacteria.

Comparison of the quality of life in peritoneal dialysis and hemodialysis patients

Chronic kidney disease (CKD) has a profound impact on patients' health-related quality of life (QoL). Particular problems are caused by the end-stage disease, which leads to the need for renal replacement therapy (RRT). Physicians and patients face the challenge of choosing a type of RRT. In this case, it is necessary to take into account not only survival rates but also the quality of life of patients who undergo the therapy, because the ability to function and maintain well-being is one of the treatment goals recommended by the World Health Organization. Therefore, assessing QoL and identifying factors influencing it becomes increasingly important in terms of therapy effectiveness and measures aimed at improving outcomes. The purpose of this work was to review recent scientific studies assessing the quality of life among peritoneal dialysis (PD) and hemodialysis (HD) patients, as well as identifying the better RRT type and risk factors that affect the quality of life. In order to identify the most relevant RRT type, the general questionnaires SF-36 and EQ-5D were used. A search for scientific studies was carried out in the international PubMed/MEDLINE database in April 2024 using the keywords: chronic kidney disease, quality of life, SF-36, EQ-5D, hemodialysis, and peritoneal dialysis. We selected papers published from 2018 to 2024 where the quality of life of patients with CKD receiving such RRT types as hemodialysis and peritoneal dialysis was studied. The results showed that PD is more preferable than HD. To achieve a high quality of life, it is also necessary to carefully treat disorders of calcium and phosphate metabolism and anemia, adequately manage concomitant diseases, assist patients with medical care provided at home, organize educational programs to increase patients’ self-efficacy and self-management, and provide psychological assistance if necessary.

Vitamin D status and intermediate vascular and bone outcomes in chronic kidney disease: a secondary post hoc analysis of IMPROVE-CKD.

Cardiovascular disease is the leading cause of death in patients with chronic kidney disease (CKD) and has been associated with abnormalities of mineral metabolism and vascular calcification. Vitamin D influences parathyroid hormone values and calcium and phosphate metabolism, and may play a role in vascular function and bone health. We aimed to test our hypothesis that vitamin D deficiency is associated with arterial stiffness, aortic calcification and lower bone mineral density (BMD) in patients with CKD. A cross-sectional analysis was performed using baseline data from the IMpact of Phosphate Reduction On Vascular Endpoints in CKD (IMPROVE-CKD) study cohort. Clinical and laboratory parameters were compared between those with and without vitamin D deficiency, defined as 25-hydroxyvitamin D (25(OH)D) <50 nmol/L. Univariable and multivariable linear regression analyses were performed to assess associations between serum 25(OH)D levels and pulse wave velocity (PWV), augmentation index (AIx), abdominal aortic calcification (measured by the Agatston score) and lumbar spine BMD. Baseline 25(OHD) values were available in 208 out of 278 IMPROVE-CKD study participants, with a mean value of 70.1 ± 30.7 nmol/L. Of these, 57 (27%) patients had vitamin D deficiency. Those with 25(OH)D deficiency were more likely to have diabetes (56% vs 38%), cardiovascular disease (54% vs 36%) and lower serum calcium (2.29 ± 0.13 vs 2.34 ± 0.13 mmol/L). On univariable and multivariable regression analyses, baseline 25(OH)D values were not associated with PWV, the AIx, Agatston score or BMD. Baseline 25(OH)D levels were not associated with intermediate markers of vascular function and BMD in patients with CKD stages 3b and 4.

Human genetic diseases of phosphate and pyrophosphate metabolism

In humans, physiological bone and tooth mineralization is a complex cell-mediated process. Prerequisites for proper mineralization include sufficient amounts of minerals (calcium and phosphate [Pi]) to initiate the formation and the growth of apatite crystals and adequate amounts of mineralization inhibitors, such as pyrophosphate (PPi), to prevent uncontrolled extraskeletal mineralization.In this review, we provide an overview of the genetics of human disorders of mineralization, focusing on Pi and PPi metabolism and transport diseases, as the Pi/PPi ratio is an important determinant of crystal production in vivo. Variants in genes implicated in the homeostasis of this ratio may lead to a systemic or local increased Pi/PPi ratio, either by increasing the Pi concentration or by decreasing the PPi concentration, resulting in ectopic calcifications; conversely, variants may lead to a decreased Pi/PPi ratio, resulting in defective mineralization.Owing to the implication of common pathways and, occasionally, to some extent of clinical overlap, an accurate diagnosis and understanding of the pathophysiology of these disorders may be challenging. However, precise molecular characterization of these conditions not only facilitates their diagnosis, but also helps to gather evidence regarding the pathophysiology and phenotype–genotype correlation to improve medical care and develop innovative therapeutics.

Physiological and Proteomic Analysis of Various Priming on Rice Seed under Chilling Stress.

Rice (Oryza sativa L.) cultivation using direct seeding is susceptible to chilling stress, particularly during seed germination and early seedling growth in the early season of a double cropping system. Alternatively, seed priming with various plant growth-promoting hormones is an effective technique to promote rapid and uniform emergence under chilling stress. Therefore, we evaluated the impact of gibberellin A3 (GA3) and brassinolide (BR) priming on rice seed emergence, examining their proteomic responses under low-temperature conditions. Results indicated that GA3 and BR increased the seed germination rate by 22.67% and 7.33% at 72 h and 35% and 15% at 96 h compared to the control (CK), respectively. Furthermore, proteomic analysis identified 2551, 2614, and 2592 differentially expressed proteins (DEPs) in GA, BR, and CK, respectively. Among them, GA exhibited 84 upregulated and 260 downregulated DEPs, while BR showed 112 upregulated and 102 downregulated DEPs, and CK had 123 upregulated and 81 downregulated DEPs. Notably, under chilling stress, both GA3 and BR are involved in peroxide metabolism, phenylpropanoid biosynthesis, and inositol phosphate metabolism, enhancing antioxidant capacity and providing energy substances for germination. In addition, GA3 triggers the specific regulation of stress responsive protein activation, GTP activation, and ascorbic acid biosynthesis and promotes the stability and integrity of cell membranes, as well as the synthesis of cell walls, providing physical defense for seeds to resist low temperatures. At the same time, BR triggers specific involvement in ribosome synthesis and amino acid synthesis, promoting biosynthetic ability and metabolic regulation to maintain plant life activities under low-temperature stress. Furthermore, the various genes' expression (OsJ_16716, OsPAL1, RINO1) confirmed GA3 and BR involved in peroxide metabolism, phenylpropanoid biosynthesis, and inositol phosphate metabolism, enhancing antioxidant capacity and providing energy substances for germination. This study provides valuable insights into how rice seed embryo responds to and tolerates chilling stress with GA3 seed priming.

Metabolism of isodecyl diphenyl phosphate in rice and microbiome system: Differential metabolic pathways and underlying mechanisms

Isodecyl diphenyl phosphate (IDDP) is among the emerging aromatic organophosphate esters (aryl-OPEs) that pose risks to both human beings and other organisms. This study aims to investigate the translocation and biotransformation behavior of IDDP in rice and the rhizosphere microbiome through hydroponic exposure (the duration of hydroponic exposure was 10 days). The rhizosphere microbiome 9-FY was found to efficiently eliminate IDDP, thereby reducing its uptake in rice tissues and mitigating the negative impact of IDDP on rice growth. Furthermore, this study proposed the first-ever transformation pathways of IDDP, identifying hydrolysis, hydroxylation, methylation, methoxylation, carboxylation, and glucuronidation products. Notably, the methylation and glycosylation pathways were exclusively observed in rice, indicating that the transformation of IDDP in rice may be more complex than in microbiome 9-FY. Additionally, the presence of the product COOH-IDDP in rice suggested that there might be an exchange of degradation products between rice and rhizobacteria, implying their potential interaction. This finding highlights the significance of rhizobacteria's role which cannot be overlooked in the accumulation and transformation of organic pollutants in grain crops. The study revealed active members in 9-FY during IDDP degradation, and metagenomic analysis indicated that most of the active populations contained IDDP-degrading genes. Moreover, transcriptome sequencing showed that cytochrome P450, acid phosphatase, glucosyltransferase, and methyltransferases genes in rice were up-regulated, which was further confirmed by RT-qPCR. This provides insight into the intermediate products identified in rice, such as hydrolysis, hydroxylated, glycosylated, and methylated products. These results significantly contribute to our understanding of the translocation and transformation of organophosphate esters (OPEs) in plants and the rhizosphere microbiome, and reveal the fate of OPEs in rice and microbiome system to ensure the paddy yield and rice safety.

Transcriptome, histology, and enzyme activities analysis of liver in Phoxinus lagowskii to the low temperature stress and recovery

Assessing the response and resilience of fish to low temperatures over different time scales can provide valuable insights into their mechanisms of adaptation to cold conditions. Farmed Amur minnows (Phoxinus lagowskii) frequently encounter low temperatures, especially during winter. However, the specific responses of P. lagowskii to low-temperature stress remain largely unexplored. In this study, we examined serum glucose and cortisol levels, histological changes, enzymes associated with phosphate and carbohydrate metabolism, triglyceride levels, and liver transcriptomics under various conditions: control (CK), short-term cold exposure (6 days, SC), prolonged cold exposure (14 days, PC), and recovery (RY) from cold exposure at 2 °C. Liver vacuolation was observed during short-term cold exposure. Additionally, we analyzed the enzymatic activity related to carbohydrate and lipid metabolism in serum and liver. Liver transcriptomic data revealed that the PPAR signaling pathway and autophagy-related genes were enriched during short-term cold exposure. Carbohydrate metabolism-related pathways, including the AMPK and MAPK signaling pathways, were significantly enriched after prolonged cold exposure. Metabolic pathways such as fat digestion and absorption, glycine, serine, and threonine metabolism, and arginine and proline metabolism were significantly enriched in the recovery group. Rapid warming after prolonged cold stress allowed P. lagowskii to recover quickly. These findings suggest that P. lagowskii has a strong adaptive capacity for energy metabolism during prolonged cold exposure and the ability to recover rapidly from cold stress. A comprehensive examination of the histological, physiological, biochemical, and molecular responses of P. lagowskii to low temperatures is crucial for developing effective strategies for cultivating this species in challenging environments.

Effect of Ca2+ signal on the activity of key enzymes of carbon metabolism and related gene expression in yeast under high sugar fermentation.

Saccharomyces cerevisiae is a fungus widely used in the food industry and biofuel industry, whereas it is usually exposed to high sugar stress during the fermentation process. Ca2+ is a key second messenger of the cell, it can regulate cell metabolism. The present study investigated the effect of the Ca2+ signal on the activity of key enzymes of carbon metabolism and related gene expression in yeast under high sugar fermentation. The expression of genes encoding hexokinase was up-regulated in the high sugar environment, the activity of hexokinase was increased, glucose transmembrane transport capacity was enhanced, the ability of glucose to enter into glycolytic metabolism was increased, and the expression of genes related to pentose phosphate metabolism, glycerol metabolism and trehalose metabolism was up-regulated in the high glucose with Ca2+ group. Ca2+ signal regulates the cellular metabolism of glycerol and trehalose and optimizes the allocation of carbon flow by regulating the key enzymes and related gene expression to enhance the resistance of yeast to high sugar stress. © 2024 Society of Chemical Industry.

Characterization of Digestive Manifestations in Patients with Impaired PTH/PTHrP Signaling Disorder/Pseudohypoparathyroidism.

Pseudohypoparathyroidism, newly classified as inactivating PTH/PTHrP signaling disorder (iPPSD) type 2 or type 3, is a rare disease caused by defects in the GNAS imprinted gene that encodes Gsα. The most common phenotype comprises resistance to hormones binding to G protein-coupled receptors such as PTH, PTHrP, or TSH, subcutaneous ossifications, short stature, brachydactyly, and early onset obesity. Uncommon features have been described including sleep apnea, asthma, and resistance to calcitonin. At the national French reference center for rare calcium and phosphate metabolism diseases, a large cohort of patients with iPPSD type 2 and type 3 is followed. Interestingly, digestive manifestations and in particular intractable constipation were regularly reported by families of children with iPPSD type 2 or type 3. The aim of our study was therefore to specify the frequency and characteristics of digestive manifestations in children followed up for iPPSD2 or iPPSD3 in our reference center. Thirty-six patients aged between 2 and 18 years (32 followed up for iPPSD2 and 4 for iPPSD3) were included. Parents completed a specific questionnaire to assess any digestive disorders in their child. The diagnosis of constipation was established using the Bristol visual scale in the event of a score of less than 2 according to stool appearance. Parents reported constipation through the questionnaires in 22/36 (over 60%) of the children. It was the most frequently reported digestive disorder. Among these 22 children, 19 (87%) had a Bristol score for stool shape and texture between 1 and 2 on a scale of 7, confirming constipation. Dedicated treatment had been initiated for 10 (55%) of them, yet only 3 families (16%) considered this treatment effective. Neonatal vomiting and eating disorders, such as lack of satiety or food selectivity, were also noted in 18 (50%) of patients, as was gastroesophageal reflux present in the neonatal period in 14 (40%) of children. There were no significant differences according to the type of iPPSD or patient age. Our work shows for the first time that digestive manifestations, including constipation, occur frequently in children followed for iPPSD, suggesting a potential role of Gsα and G protein receptors in the digestive tract. It is well known that constipation and digestive symptoms alter quality of life. Early management is therefore essential to improve the quality of life of children followed for iPPSD. Our data need to be confirmed on a larger cohort.

Identification of YigL as a PLP/PNP phosphatase in Escherichia coli.

In various organisms, the coenzyme form of vitamin B6, pyridoxal phosphate (PLP), is synthesized from pyridoxine phosphate (PNP). Control of PNP levels is crucial for metabolic homeostasis because PNP has the potential to inhibit PLP-dependent enzymes and proteins. Although the only known pathway for PNP metabolism in Escherichia coli involves oxidation by PNP oxidase, we detected a strong PNP phosphatase activity in E. coli cell lysate. To identify the unknown PNP phosphatase(s), we performed a multicopy suppressor screening using the E. coli serA pdxH strain, which displays PNP-dependent conditional lethality. The results showed that overexpression of the yigL gene, encoding a putative sugar phosphatase, effectively alleviated the PNP toxicity. Biochemical analysis revealed that YigL has strong phosphatase activity against PNP. A yigL mutant exhibited decreased PNP phosphatase activity, elevated intracellular PNP concentrations, and increased PNP sensitivity, highlighting the important role of YigL in PNP homeostasis. YigL also shows reactivity with PLP. The phosphatase activity of PLP in E. coli cell lysate was significantly reduced by mutation of yigL and nearly abolished by additional mutation of ybhA, which encodes putative PLP phosphatase. These results underscore the important contribution of YigL, in combination with YbhA, as a primary enzyme in the dephosphorylation of both PNP and PLP in E. coli.IMPORTANCEPyridoxine phosphate (PNP) metabolism is critical for both vitamin B6 homeostasis and cellular metabolism. In Escherichia coli, oxidation of PNP was the only known mechanism for controlling PNP levels. This study uncovered a novel phosphatase-mediated mechanism for PNP homeostasis. Multicopy suppressor screening, kinetic analysis of the enzyme, and knockout/overexpression studies identified YigL as a key PNP phosphatase that contributes to PNP homeostasis when facing elevated PNP concentrations in E. coli. This study also revealed a significant contribution of YigL, in combination with YbhA, to PLP metabolism, shedding light on the mechanisms of vitamin B6 regulation in bacteria.

Insight into the differences in meat quality among three breeds of sheep on the Qinghai-Tibetan plateau from the perspective of metabolomics and rumen microbiota

Mutton is one of the most popular meats among the general public due to its high nutritional value. This study evaluated the differences in meat quality among Chaka (CK), Black Tibetan (BT) and Oula (OL) sheep and investigated the metabolic mechanisms affecting meat quality using targeted and untargeted metabolomics and 16S rRNA. The results showed that the meat quality of CK sheep was superior to that of BT and OL sheep in terms of meat color, muscle fiber characteristics and nutritional quality. Pseudobutyrivibrio, Alloprevotella, Methanobrevibacter, unidentified_Christensenellaceae, and unidentified_Bacteroidales were key microbes involved in regulating meat color, muscle fiber characteristics, amino acid and fatty acid content. Protein digestion/absorption, pentose phosphate metabolism, carbon metabolism, and glyoxylate and dicarboxylate metabolism were important metabolic pathways involved in meat quality regulation. Our study is important for the development of sheep breeding strategy and sheep meat industry in Qinghai-Tibetan Plateau.

Key genomes, transcriptomes, proteins, and metabolic factors involved in the detoxification/tolerance of TNT and its intermediates by bacteria in anaerobic/aerobic environments

Novel microbial strains capable of efficient degradation of TNT and typical intermediates (2-ADNT and 4-ADNT) in aerobic/anaerobic environment were screened and isolated from ammunition-contaminated sites. The key genomes, transcriptomes, proteins, and metabolic factors for microbial detoxification/tolerance to pollutants in anaerobic and aerobic environments were analyzed for the first time. The bacterial genome, which is rich in metabolism and environmental information-processing functional genes, provides transcriptional and translational-related proteins for detoxifying/tolerating pollutants. At the transcriptional level, bacteria significantly expressed genes related to inositol phosphate metabolism for regulating membrane transport, maintaining the cytoskeleton, and signal transduction. At the protein level, genes involved in antioxidation, fat metabolism, sugar synthesis/degradation, and pyruvate metabolism were significantly expressed. At the metabolic level, riboflavin metabolism, which regulates membrane integrity, protects against oxidative stress, and maintains the sugar–protein–fat balance, showed significant responses. Bacteria simultaneously regulate amino acid metabolism, carbohydrate metabolism, and N/P/S cycles to maintain homeostatic cellular energy supplies. The key pathway for pollutant degradation in bacteria is nitrotoluene degradation. The molecular mechanism of bacterial tolerance to pollutants involves the regulation of oxidative phosphorylation and basic cycle pathways to maintain gene transcription, protein translation, and metabolic cycles.

Transcriptome sequencing analysis of gene expression in phosphate-solubilizing bacterium 'N3' and grafted watermelon plants coping with toxicity induced by cadmium.

Cadmium (Cd) is a harmful metal in soil, and reducing Cd accumulation in plants has become a vital prerequisite for maintaining food safety. Phosphate-solubilizing bacteria (PSB) can not only improve plant growth but also inhibit the transportation of metals to roots. However, data on gene expression in PSB Burkholderia sp. strain 'N3' and grafted watermelon plants dealing with Cd remain to be elucidated. In this study, core genes and metabolic pathways of strain 'N3' and grafted plants were analyzed by Illumina sequencing. Results showed that 356 and 2527 genes were upregulated in 'N3' and grafted watermelon plants, respectively, whereas 514 and 1540 genes were downregulated in 'N3' and grafted watermelon plants, respectively. Gene ontology enrichment analysis showed that signal transduction, inorganic ion transport, cell motility, amino acid transport, and metabolism pathways were marked in 'N3'. However, pathways such as secondary metabolite biosynthesis, oxidation-reduction process, electron transfer activity, and channel regulator activity were marked in the grafted plants. Six genes related to pentose phosphate, glycolysis, and gluconeogenesis metabolism were upregulated in the grafted plants. This study paves the way for developing potential strategies to improve plant growth under Cd toxicity.

Role of Carbon, Nitrogen, Phosphate and Sulfur Metabolism in Secondary Metabolism Precursor Supply in Streptomyces spp.

The natural soil environment of Streptomyces is characterized by variations in the availability of nitrogen, carbon, phosphate and sulfur, leading to complex primary and secondary metabolisms. Their remarkable ability to adapt to fluctuating nutrient conditions is possible through the utilization of a large amount of substrates by diverse intracellular and extracellular enzymes. Thus, Streptomyces fulfill an important ecological role in soil environments, metabolizing the remains of other organisms. In order to survive under changing conditions in their natural habitats, they have the possibility to fall back on specialized enzymes to utilize diverse nutrients and supply compounds from primary metabolism as precursors for secondary metabolite production. We aimed to summarize the knowledge on the C-, N-, P- and S-metabolisms in the genus Streptomyces as a source of building blocks for the production of antibiotics and other relevant compounds.