Iron Carrier Research Articles

Estimation of magnetorheological fluid constituent’s concentration for efficient finishing process

ABSTRACT Efficacy and outcome of all magnetorheological finishing (MRF) processes depend on rheological properties of the magnetorheological (MR) fluid which consists of carbonyl iron particles (CIPs), abrasives and carrier fluid. Thus it is important to understand particle distribution in MR fluid which affects the rheological properties of the fluid under the influence of the applied magnetic field and hence the finishing process. A hexagonal microstructure model of MR fluid is considered and a modified model of abrasive doped MR fluid is developed for generation of estimation curve based on ratio of size of abrasive particles to CIP. MR fluid was prepared based on these estimated values and was used for finishing of N-BK7 glass on Ball End MRF (BEMRF) machine. MR fluid with four different abrasive size to CIP size ratios were prepared with CIP volume fraction of 32.9% and Cerium Oxide particles volume fraction of 12.5% with 54.6% water. Another experiment with size of cerium oxide particles to size of CIP ratio of 0.761 is taken for four different concentrations of abrasives and CIPs. Best results with 79.85% improvement in roughness and 0.672 µg/minute MRR were obtained for fluid prepared as per proposed estimation curve for efficient finishing process.

Phenotypic and proteomic approaches of the response to iron-limited condition in Staphylococcus lugdunensis

BackgroundStaphylococcus lugdunensis is a coagulase-negative Staphylococcus part of the commensal skin flora but emerge as an important opportunistic pathogen. Because iron limitation is a crucial stress during infectious process, we performed phenotypic study and compared proteomic profiles of this species incubated in absence and in presence of the iron chelator 2,2′-dipyridyl (DIP).ResultsNo modification of cell morphology nor cell wall thickness were observed in presence of DIP. However iron-limitation condition promoted biofilm formation and reduced the ability to cope with oxidative stress (1 mM H2O2). In addition, S. lugdunensis N920143 cultured with DIP was significantly less virulent in the larvae of Galleria mellonella model of infection than that grown under standard conditions. We verified that these phenotypes were due to an iron limitation by complementation experiments with FeSO4. By mass spectrometry after trypsin digestion, we characterized the first iron-limitation stress proteome in S. lugdunensis. Among 1426 proteins identified, 349 polypeptides were differentially expressed. 222 were more and 127 less abundant in S. lugdunensis incubated in iron-limitation condition, and by RT-qPCR, some of the corresponding genes have been shown to be transcriptionally regulated. Our data revealed that proteins involved in iron metabolism and carriers were over-expressed, as well as several ABC transporters and polypeptides linked to cell wall metabolism. Conversely, enzymes playing a role in the oxidative stress response (especially catalase) were repressed.ConclusionsThis phenotypic and global proteomic study allowed characterization of the response of S. lugdunensis to iron-limitation. We showed that iron-limitation promoted biofilm formation, but decrease the oxidative stress resistance that may, at least in part, explained the reduced virulence of S. lugdunensis observed under low iron condition.

Preparation and characterization of a novel MR fluid with MWCNTs/GO composites coated ferromagnetic particles

Magnetorheological (MR) fluid is a typical intelligent material which is widely adopted in the mitigation of civil engineering structures, and it is normally composed of nano-sized or micro-sized iron particles, carrier fluids and additives. In the study, ferromagnetic particles coated with multi-walled carbon nanotubes (MWCNTs) and graphene oxide (GO) composites were prepared with grafting technology and the influence concerning ratio of MWCNTs, GO, grafting agent as well as carbonyl iron (CI) particles was studied to select the composite ferromagnetic particles which have the best effects of coating through surface topography analysis. In addition, the MWCNTs/GO composites coated CI particles and surfactants-modified CI particles were combined together to prepare a series of MR fluids with different ratio of the two compound ferromagnetic particles, volume fraction of total ferromagnetic particles and additives by the control variable method and the influence of the factors on the performances of MR fluids was investigated through sedimentation stability, re-dispersion, zero field viscosity and shear yield stress tests. The test results presented that the introduction of MWCNTs/GO composites coated CI particles was beneficial to the improvement of stability with sedimentation rate lower than 6%.

Enhanced Fe3+ binding through cooperativity of 3-hydroxypyridin-4-one groups within a linear co-polymer: wrapping effect leading to superior antimicrobial activity.

To tackle the rise of antibiotic resistant pathogenic microbes, iron withdrawal agents have shown considerable promise as antibiotic alternatives due to the microbes' irreplaceable metabolic need for the essential element iron. DIBI is a water-soluble, linear co-polymer functionalized with 3-hydroxy-pyridin-4-one (HPO) chelators that selectively and strongly bind iron(III) in biological environments. Compared to HPO congeners, DIBI has over 1000 times higher antimicrobial activity against a broad-spectrum of Gram-(+) and Gram-(-) bacteria including highly antibiotic resistant clinical isolates. Herein, we explain the enhanced antimicrobial activity of DIBI by a cooperativity effect of the linear co-polymer wrapping around three iron(III) centres. DIBI's structural and iron(III) binding properties were investigated by comparative experiments against HPO monomer and deferiprone using chemical and physical characterization methods with direct biological implications such as pH stability, reductive off-loading of bound iron(III), trans-membrane permeability, and competition experiments with vertebrate transferrin class iron carrier. The three iron(III) ions bound to DIBI are preferentially incorporated into a tris-bidentate chelates, which forces the linear backbone of the polymer to wrap around the complexes, as the bound iron was much less susceptible to dithionite reduction than the tris iron(III) complexes of HPO monomers and deferiprone. The results suggest a high degree of cooperativity of the polymer-bound HPO groups to effect a wrapping of the polymer backbone around the chelated iron, shielding the iron(III) centres from ready access by microbes. The structural effect of DIBI is compared to polymers containing 3-hydroxy-pyridin-4-one chelators that do not undergo this wrapping effect.

MD simulation reveals differential binding of Cm(III) and Th(IV) with serum transferrin at acidic pH.

The iron carrier human serum transferrin (sTf) is known to transport other metals, including some actinides (An). Radiotoxic An are routinely involved in the nuclear fuel cycle and the possibility of their accidental exposure cannot be ruled out. Understanding An interaction with sTf assumes a greater significance for the development of safe and efficacious chelators for their removal from the blood stream. Here we report several 100 ns equilibrium MD simulations of Cm(III)- and Th(IV)-loaded sTf at various protonation states of the protein to explore the possibility of the two An ions release and speciation. The results demonstrate variation in protonation state of dilysine pair (K206 and K296) and the tyrosine (Y188) residue is necessary for the opening of Cm(III)-bound protein and the release of the ion. For the tetravalent thorium, protonation of dilysine pair suffices to cause conformational changes of protein. However, in none of the protonation states, Th(IV) releases from sTf because of its strong electrostatic interaction with D63 in the first shell of the sTf binding cleft. Analysis of hydrogen bond, water bridge, and the evaluation of potential of mean forces of the An ions' release from sTf, substantiate the differential behavior of Cm(III) and Th(IV) at endosomal pH. The results provide insight in the regulation of Cm(III) and Th(IV) bioavailability that may prove useful for effective design of their decorporating agents and as well may help the future design of radiotherapy based on tetravalent ions.

Volatiles from the fungal phytopathogen Penicillium aurantiogriseum modulate root metabolism and architecture through proteome resetting.

Volatile compounds (VCs) emitted by the fungal phytopathogen Penicillium aurantiogriseum promote root growth and developmental changes in Arabidopsis. Here we characterised the metabolic and molecular responses of roots to fungal volatiles. Proteomic analyses revealed that these compounds reduce the levels of aquaporins, the iron carrier IRT1 and apoplastic peroxidases. Fungal VCs also increased the levels of enzymes involved in the production of mevalonate (MVA)-derived isoprenoids, nitrogen assimilation and conversion of methionine to ethylene and cyanide. Consistently, fungal VC-treated roots accumulated high levels of hydrogen peroxide (H2 O2 ), MVA-derived cytokinins, ethylene, cyanide and long-distance nitrogen transport amino acids. qRT-PCR analyses showed that many proteins differentially expressed by fungal VCs are encoded by VC non-responsive genes. Expression patterns of hormone reporters and developmental characterisation of mutants provided evidence for the involvement of cyanide scavenging and enhanced auxin, ethylene, cytokinin and H2 O2 signalling in the root architecture changes promoted by fungal VCs. Our findings show that VCs from P. aurantiogriseum modify root metabolism and architecture, and improve nutrient and water use efficiencies through transcriptionally and non-transcriptionally regulated proteome resetting mechanisms. Some of these mechanisms are subject to long-distance regulation by photosynthesis and differ from those triggered by VCs emitted by beneficial microorganisms.

Abstract 6073: The lipogenic regulator SREBP induces Transferrin in circulating melanoma cells, suppressing their susceptibility to ferroptosis

Abstract Circulating tumor cells (CTCs) are shed by cancers into the bloodstream, where a viable subset overcomes oxidative stress to initiate metastatic outgrowth. Clonally derived cultured CTCs from patients with BRAF-mutant melanoma reveal upregulation of lipogenesis and iron homeostasis pathways, correlated with their baseline and acquired drug resistance. In CTCs, the lipogenesis regulator SREBP directly induces transcription of the iron carrier Transferrin (TF), thereby reducing intracellular reactive oxygen species (ROS) and lipid peroxidation, and conferring resistance to BRAF inhibitors and inducers of ferroptosis. Knockdown of endogenous TF impairs tumorigenesis by melanoma CTCs; their associated soft agar clonogenic defect is rescued by the lipophilic anti-oxidants Ferrostatin-1 or Vitamin E, and by cholesterol. Single cell RNA-seq of patient-derived melanoma CTCs identifies a subset with high lipogenic, iron metabolic and proliferative signatures, correlated with adverse clinical outcome. Together, the coordinated regulation of these SREBP-driven pathways contributes to cancer progression, drug resistance and metastasis. Citation Format: Xin Hong, Whijae Roh, Ryan J. Sullivan, Keith H. Wong, Ben S. Wittner, HongShan Guo, Taronish D. Dubash, Moshe Sade-Feldman, Ben K. Wesley, Genevieve M. Boland, Dieuwke L. Marvin, Todd Bonesteel, Chenyue Lu, Elad Horwitz, François Aguet, Samuel S. Freeman, Katherine Calhoun, Michelle K. Jewett, Linda T. Nieman, Nir Hacohen, Anders M. Näär, David T. Ting, Mehmet Toner, Shannon L. Stott, Gad Getz, Shyamala Maheswaran, Daniel A. Haber. The lipogenic regulator SREBP induces Transferrin in circulating melanoma cells, suppressing their susceptibility to ferroptosis [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 6073.

Designation and characterization of cold-set whey protein-gellan gum hydrogel for iron entrapment

This study is aimed at designing of a composite cold-set hydrogel using whey protein isolate (WPI) and gellan gum as iron carrier. The effect of total polymer concentration (TPC) (0.5 and 1.5%), WPI/gellan ratio (1:1, 1:2, and 1:3), and iron concentration (10, 40, and 70 mM) on physicochemical and rheological characteristics of hydrogel were analyzed. By increasing TPC, the release mechanism became complex regarding less erosion of structure in simulated gastrointestinal medium. Moreover, the CO peak area of FTIR spectra was enhanced. As WPI/gellan ratio decreased, the faster release occurred due to a more porous structure. The cumulative release of iron in acidic and neutral pH increased up to 71.74 and 9.14%; however, iron was released up to 88.55 and 28.72% in simulated gastric and intestinal medium, respectively. The iron release followed a chemically-controlled mechanism in all samples. The area and number of gel pores and water-holding capacity decreased as Fe concentration was enhanced, but denaturation temperature increased. These results suggest that the strong texture with a solid elastic behavior along with a high cumulative release of iron made our hydrogel suitable for iron delivery to reduce iron deficiency-related disorders.

Effects of Enterobacter cloacae HG-1 on the Nitrogen-Fixing Community Structure of Wheat Rhizosphere Soil and on Salt Tolerance.

The present study investigated the physiological and biochemical characteristics of Enterobacter cloacae HG-1 isolated from saline-alkali soil. We further studied the effect of this strain on the salt tolerance of wheat and on the community structure of nitrogen-fixing bacteria in rhizosphere soil. We determined that the investigated strain had high nitrogen fixation activity and produced iron carriers, 1-aminocyclopropane-1-carboxylic acid deaminase, and plant hormones. The metabolites of this strain contained 2,3-butanediol, [R-(R*, R*)], 2-heptanone, and other growth-promoting and antibacterial substances. The strain was also highly salt-tolerant (10% NaCl). After the inoculation of wheat with the HG-1 strain, we recorded increases in root length, plant height, fresh weight, and dry weight of 19.15%, 18.83%, 16.67%, and 17.96%, respectively, compared with uninoculated plants (P < 0.05). Compared with the leaves of uninoculated plants, the proline concentration in the leaves of inoculated plants increased by 12.43% (P < 0.05), the malondialdehyde level decreased by 27.26% (P < 0.05), K+ increased by 20.69%, Ca2+ increased by 57.53% and Na+ decreased by 31.43% (all P<0.05). Furthermore, we detected that inoculation with the HG-1 strain did not affect the species composition of nitrogen-fixing bacteria in wheat rhizosphere soil at the phylum level. However, the average relative abundance of Proteobacteria was significantly increased, whereas the abundance of Verrucomiorobia was significantly decreased compared with uninoculated plants. At the genus level, we detected 32 genera in control samples and 27 genera in inoculated samples, and the species diversity and relative abundance of samples inoculated with the HG-1 strain decreased compared with uninoculated plants. Inoculated samples had lower abundances of Azospirillum, Rhodomicrobium, and Anabaena. Our study demonstrated that the inoculation of wheat with E. cloacae HG-1 could promote the growth of wheat under salt stress and increase salt stress tolerance. The results of this study investigating the interaction among soil, plants, and microorganisms supplement agricultural microbial databases and could provide a reference for the development of microbial-based saline soil improvement programs.

Computational backbone design enables soluble engineering of transferrin receptor apical domain.

Supply of iron into human cells is achieved by iron carrier protein transferrin and its receptor that upon complex formation get internalized by endocytosis. Similarly, the iron needs to be delivered into the brain, and necessitates the transport across the blood-brain barrier. While there are still unanswered questions about these mechanisms, extensive efforts have been made to use the system for delivery of therapeutics into biological compartments. The dimeric form of the receptor, where each subunit consists of three domains, further complicates the detailed investigation of molecular determinants responsible for guiding the receptor interactions with other proteins. Especially the apical domain's biological function has been elusive. To further the study of transferrin receptor, we have computationally decoupled the apical domain for soluble expression, and validated the design strategy by structure determination. Besides presenting a methodology for solubilizing domains, the results will allow for study of apical domain's function.

Improvement of manganese phytoremediation by Broussonetia papyrifera with two plant growth promoting (PGP) Bacillus species

Combining phytoremediation plants and microorganisms is a promising method of remediating heavy metal contaminated soil. In this study, two manganese-tolerant strains were isolated from Mn slag and identified as Bacillus cereus HM5 and Bacillus thuringiensis HM7. These two Bacillus spp. have the ability to dissolve phosphorus, produce IAA and iron carrier. A pot experiment of Broussonetia papyrifera was conducted to explore potential of B. cereus HM5 and B. thuringiensis HM7 to improve effect of remedying Mn pollution by B. papyrifera. The strains were inoculated under different Mn treated (5 mmol/L, 50 mmol/L, Mn slag) respectively and the growth, root structure, root activity, physiological and biochemical characteristics of the leaves and accumulation of Mn for B. papyrifera were determinated. The effects of the soil environment to remediation were observed, the results showed that the biomass, total root length, surface area, crossings, tips, forks and root activity of B. papyrifera with inoculated strain were higher than those of the control group. The inoculation of these two Bacillus spp. increased the absorption of Mn by B. papyrifera and the concentration of Mn in the aerial parts of plants, indicating that the two strains could promote the growth of B. papyrifera and the accumulation of Mn. In addition, microbes reduced malonaldehyde content and the activities of antioxidant enzymes in leaves, suggesting that the two Bacillus spp. reduced Mn-induced oxidative stress. The principal component analysis showed that the added Bacillus strain prefer to promote plant root function maintenance and improve soil environment, rather than direct adsorption of heavy metals. These observations indicated that B. cereus HM5 and B. thuringiensis HM7 were valuable microorganisms, which could improve the remediating efficiency of B. papyrifera under Mn-contaminated soil.

Antarctic krill derived peptide as a nanocarrier of iron through the gastrointestinal tract

Antarctic krill (Euphausia superba) might have specific peptides that chelate iron ions and are iron carriers. In this study, iron-binding peptides were isolated from Antarctic krill using enzymatic (trypsin) hydrolysis and immobilized metal affinity chromatography (IMAC); the binding mode and surface morphology of Antarctic krill peptides (AKP)-iron complexes as well as their iron delivery behavior in the gastrointestinal tract were investigated. Results showed that the AKP bound 79.3% of available iron from the enzymatic hydrolysis for 180 min. The contents of negatively-charged amino acids (Asp and Glu) on the AKP showed a positive correlation (r = 0.80) with iron-binding activities (the data includes Asn and Gln), while positively-charged amino acids showed a negative correlation (r = −0.83). Moreover, His, Ser and Thr on the AKP were also involved in the iron-binding activities. Iron-binding peptides from Antarctic krill hydrolysates, isolated using IMAC-Fe3+ and identified using HPLC-MS/MS, showed a mass of 712–2451 Da, and were enriched in Asp (Asn), Glu (Gln), His, Ser or Thr. The iron ions mainly bound to carboxyl groups of AKP, thus forming nano-scale, spherical particles. The iron nanocarriers formed by AKP showed a significant iron transport activity after simulated gastrointestinal digestion, as compared to FeSO4 (P < 0.05). The results suggested that the AKP-iron nanocomposite has the potential to be a nutraceutical supplement for improving iron absorption.

Iron and age-related macular degeneration: a new track

Iron has a fundamental role for cell physiology and especially in retina as a cofactor of many pathways of the visual transduction. A tightly regulated homeostasis avoids the accumulation of prooxidant and proinflammatory free iron. A dysfunction of iron retinal homeostasis is associated with many genetic or age-related degenerative diseases such as age-related macular degeneration (AMD). Here, we describe various mechanisms reported during AMD, enhanced by iron accumulation and its homeostasis dysregulation. We have investigated a local treatment with transferrin, the natural iron carrier, to control these pathological pathways and iron dysfunction, without side effects. Iron has a central role in pathogenesis of AMD and is a target for futures therapies.

Screening of rhizosphere growth promoting bacteria and their growth promoting ability of sunflower in cold black soil area

High efficient growth promoting bacteria were screened from the rhizosphere soil of sunflower in the cold black soil area, and their growth promoting ability was tested to obtain the strains with comprehensive growth promoting ability. The phosphate solubilizing bacteria were screened out by inorganic phosphate bacteria culture medium, the phosphate solubilizing ability of the strain was determined by mo sb anti chromogenic method, the indoleacetic acid producing ability of the strain was determined by salkowski method, the iron carrier producing ability of the strain was determined by CAS method, and the growth promoting ability of the strain was evaluated comprehensively. Eleven strains of phosphate solubilizing bacteria were isolated and screened from soil samples. Among them, strain WP2 had the strongest phosphate solubilizing ability, and the concentration of phosphate radical was 12.75 μg/mL; strain WP1 had the strongest indoleacetic acid producing ability, and the concentration of indoleacetic acid was 25.37μg/mL; strain WP1 had the strongest iron producing ability, with Su = 72.76%, and the strength was 4+. It was found that WP1, WP2 and WP10 had strong ability of promoting growth and had strong potential of development and utilization. The above results can provide excellent strains for the development and promotion of special bio fertilizer suitable for the cold black soil.

Study on Magnatec oil-based MR fluid and its damping efficiency using MR damper with various annular gap configurations

Magnetorheological (MR) fluids are a talk of the day due to their potential applications in various fields. In the present work, six different MR fluids were prepared based on the variation in the percentage of carbonyl iron (CI) particles and carrier liquid. The smart material CI particle was well characterized by XRD, SEM-EDAX and VSM measurements. The effect of carrier fluid on sedimentation was tested using CI 50% and compared with the other carrier oil used. The Magnatec oil acts as a better candidate due to its sedimentation stability and thermal resistance. Therefore, the rheological measurement was examined for the three magnetorheological fluids (MRF) prepared, namely MRF 32, MRF 50 and MRF 80 with Magnatec oil as carrier liquid. The three various size annular gaps between the piston and the inner cylinder casing was also studied. Among the three variations, 1, 1.5 and 2 mm, the maximum damping force was obtained for 1-mm annular gap. A number of experimentations were carried out to investigate the performance of the MR fluid as well as the annular gap. Cyclic load test was performed with various annular gaps, and 0.536 kN was the maximum damping force for 1-mm annular gap.

Controversies on the Consequences of Iron Overload and Chelation in MDS.

Many patients with MDS are prone to develop systemic and tissue iron overload in part as a consequence of disease-immanent ineffective erythropoiesis. However, chronic red blood cell transfusions, which are part of the supportive care regimen to correct anemia, are the major source of iron overload in MDS. Increased systemic iron levels eventually lead to the saturation of the physiological systemic iron carrier transferrin and the occurrence of non-transferrin-bound iron (NTBI) together with its reactive fraction, the labile plasma iron (LPI). NTBI/LPI-mediated toxicity and tissue iron overload may exert multiple detrimental effects that contribute to the pathogenesis, complications and eventually evolution of MDS. Until recently, the evidence supporting the use of iron chelation in MDS was based on anecdotal reports, uncontrolled clinical trials or prospective registries. Despite not fully conclusive, these and more recent studies, including the TELESTO trial, unravel an overall adverse action of iron overload and therapeutic benefit of chelation, ranging from improved hematological outcome, reduced transfusion dependence and superior survival of iron-loaded MDS patients. The still limited and somehow controversial experimental and clinical data available from preclinical studies and randomized trials highlight the need for further investigation to fully elucidate the mechanisms underlying the pathological impact of iron overload-mediated toxicity as well as the effect of classic and novel iron restriction approaches in MDS. This review aims at providing an overview of the current clinical and translational debated landscape about the consequences of iron overload and chelation in the setting of MDS.

Iron uptake mechanisms as key virulence factors in bacterial fish pathogens.

This review summarizes the current knowledgeabout iron uptake systems in bacterial fish pathogens and their involvement in the infective process. Like most animal pathogens, fish pathogens have evolved sophisticated iron uptake mechanisms some of which are key virulence factors for colonization of the host. Among these systems, siderophore production and heme uptake systems are the best studied in fish pathogenic bacteria. Siderophores like anguibactin or piscibactin, have been described in Vibrio and Photobacterium pathogens as key virulence factors to cause disease in fish. In many other bacterial fish pathogens production of siderophores was demonstrated but the compounds were not yet chemically characterized and their role in virulence was not determined. The role of heme uptake in virulence was not yet clearly elucidated in fish pathogens although there exist evidence that these systems are expressed in fish tissues during infection. The relationship of other systems, like Fe(II) transporters or the use of citrate as iron carrier, with virulence is also unclear. Future trends of research on all these iron uptake mechanisms in bacterial fish pathogens are also discussed.

The (p)ppGpp-mediated stringent response regulatory system globally inhibits primary metabolism and activates secondary metabolism in Pseudomonas protegens H78.

Pseudomonas protegens H78 produces multiple secondary metabolites, including antibiotics and iron carriers. The guanosine pentaphosphate or tetraphosphate ((p)ppGpp)-mediated stringent response is utilized by bacteria to survive during nutritional starvation and other stresses. RelA/SpoT homologues are responsible for the biosynthesis and degradation of the alarmone (p)ppGpp. Here, we investigated the global effect of relA/spoT dual deletion on the transcriptomic profiles, physiology, and metabolism of P. protegens H78 grown to mid- to late log phase. Transcriptomic profiling revealed that relA/spoT deletion globally upregulated the expression of genes involved in DNA replication, transcription, and translation; amino acid metabolism; carbohydrate and energy metabolism; ion transport and metabolism; and secretion systems. Bacterial growth was partially increased, while the cell survival rate was significantly reduced by relA/spoT deletion in H78. The utilization of some nutritional elements (C, P, S, and N) was downregulated due to relA/spoT deletion. In contrast, relA/spoT mutation globally inhibited the expression of secondary metabolic gene clusters (plt, phl, prn, ofa, fit, pch, pvd, and has). Correspondingly, antibiotic and iron carrier biosynthesis, iron utilization, and antibiotic resistance were significantly downregulated by the relA/spoT mutation. This work highlights that the (p)ppGpp-mediated stringent response regulatory system plays an important role in inhibiting primary metabolism and activating secondary metabolism in P. protegens.

Preface for special issue on environmental biotechnology (2019)

Environmental biotechnology, as an emerging interdisciplinary subject combining modern biotechnology and environmental engineering, has been widely used in environmental pollution control and environmental monitoring. Efficient purification of environmental pollution and the production of useful substances have the potential to fundamentally solve environmental problems. In the present special issue, the principle and application of environmental biotechnology in the field of environmental pollutant degradation such as polycyclic aromatic hydrocarbons, antibiotics, and petroleum-based plastics has been summarized. Application of indole, microbial iron carrier and other molecules in bioremediation has been introduced. Hope to give a comprehensive view on basic environmental biotechnology, future research directions and comprehensive governance strategies.

Bacterial siderophores in community and host interactions.

Iron is an essential trace element for most organisms. A common way for bacteria to acquire this nutrient is through the secretion of siderophores, which are secondary metabolites that scavenge iron from environmental stocks and deliver it to cells via specific receptors. While there has been tremendous interest in understanding the molecular basis of siderophore synthesis, uptake and regulation, questions about the ecological and evolutionary consequences of siderophore secretion have only recently received increasing attention. In this Review, we outline how eco-evolutionary questions can complement the mechanistic perspective and help to obtain a more integrated view of siderophores. In particular, we explain how secreted diffusible siderophores can affect other community members, leading to cooperative, exploitative and competitive interactions between individuals. These social interactions in turn can spur co-evolutionary arms races between strains and species, lead to ecological dependencies between them and potentially contribute to the formation of stable communities. In brief, this Review shows that siderophores are much more than just iron carriers: they are important mediators of interactions between members of microbial assemblies and the eukaryotic hosts they inhabit.