ABSTRACT
Arbuscular mycorrhizal fungi (AMF) play a key role in terrestrial ecosystems, while the ecological restoration application of AMF in mining areas has been progressively gaining attention. This study simulated a low nitrogen (N) environment in copper tailings mining soil to explore inoculative effects of four AMF species on the eco-physiological characteristics of Imperata cylindrica, and provided plant-microbial symbiote with excellent resistance to copper tailings. Results show that N, soil type, AMF species, and associated interactions significantly affected ammonium (NH4 +), nitrate nitrogen (NO3 -), and total nitrogen (TN) content and photosynthetic characteristics of I. cylindrica. Additionally, interactions between soil type and AMF species significantly affected the biomass, plant height, and tiller number of I. cylindrica. Rhizophagus irregularis and Glomus claroideun significantly increased TN and NH4 + content in the belowground components I. cylindrica in non-mineralized sand. Moreover, the inoculation of these two fungi species significantly increased belowground NH4 + content in mineralized sand. The net photosynthetic rate positively correlated to aboveground total carbon (TC) and TN content under the high N and non-mineralized sand treatment. Moreover, Glomus claroideun and Glomus etunicatum inoculation significantly increased both net photosynthetic and water utilization rates, while F. mosseae inoculation significantly increased the transpiration rate under the low N treatment. Additionally, aboveground total sulfur (TS) content positively correlated to the intercellular carbon dioxide (CO2) concentration, stomatal conductance, and the transpiration rate under the low N sand treatment. Furthermore, G. claroideun, G. etunicatum, and F. mosseae inoculation significantly increased aboveground NH4 + and belowground TC content of I. cylindrica, while G. etunicatum significantly increased belowground NH4 + content. Average membership function values of all physiological and ecological I. cylindrica indexes infected with AMF species were higher compared to the control group, while corresponding values of I. cylindrica inoculated with G. claroideun were highest overall. Finally, comprehensive evaluation coefficients were highest under both the low N and high N mineralized sand treatments. This study provides information on microbial resources and plant-microbe symbionts in a copper tailings area, while aiming to improve current nutrient-poor soil conditions and ecological restoration efficiency in copper tailings areas.
ABSTRACT
Squid processing by-product contains unutilized abundant proteins. In this study, 6 proteases (pepsin, protamex, trypsin, neutral protease, alkaline protease, and papain) were firstly employed to hydrolyze the squid processing by-product protein. The neutral protease-digested hydrolysate was found to have the most promising ACE (angiotensin-converting enzyme) inhibitory activity. Based on Box-Behnken design, the optimal hydrolysis process was determined to be: 52.4 â of temperature, 5.7 h of time, pH 7.1, and 8151 U/g of enzyme. Under these conditions, the ACE inhibition rate and polypeptide content of the hydrolysate were 84.26% and 229.09 mg/g, respectively. Subsequently, ultrafiltration was performed, and the ACE and renin inhibitory activities of the filtrate (< 1 kDa) were the highest, reaching 87.48 ± 1.76% and 69.72 ± 1.16%, with IC50 values of 1.34 ± 0.12 mg/mL and 1.47 ± 0.06 mg/mL, respectively. However, these activities decreased to 35.15 ± 1.31% and 43.17% ± 1.42%, respectively, after digestion by simulated gastrointestinal juice. Nevertheless, this is the first report representing the neutral protease-digested hydrolysate of squid processing by-product as a potential source of both ACE and renin inhibitors.
Subject(s)
Angiotensin-Converting Enzyme Inhibitors , Protein Hydrolysates , Angiotensin-Converting Enzyme Inhibitors/chemistry , Angiotensin-Converting Enzyme Inhibitors/pharmacology , Animals , Decapodiformes/metabolism , Hydrolysis , Peptide Hydrolases/metabolism , Protein Hydrolysates/chemistry , ReninABSTRACT
The phyllosphere and rhizosphere of plants and their living environment jointly form a complex ecosystem. Rhizosphere microorganisms are also the main driving force of the circulation of soil materials, which can provide a basis for the growth and development of plants. Phyllosphere and rhizosphere microorganisms can also be used as ecological indicators, and play significant roles in the ecological stability and recovery of mining areas. In this study, we selected a dominant species, Bothriochloa ischaemum, as the research object. We studied the characteristics of phyllosphere and rhizosphere bacterial communities in B. ischaemum from copper tailings with high-throughput sequencing methods. We explored the key ecological factors affecting the structure and diversity of phyllosphere and rhizosphere bacterial communities in B. ischaemum. The results showed that there were significant differences in the bacterial community structures between the rhizosphere and phyllosphere. The dominant phyllosphere bacterial genera of B. ischaemum included Pseudomonas, Enterobacter, and Sphingomonas. The dominant rhizosphere bacterial genera were Acidibacter and Solrubrobacter. Moreover, the Shannon diversity, abundance-based coverage estimator (ACE), and Chao1 indices of rhizosphere bacterial communities were significantly higher than those of phyllosphere communities. The key ecological factors affecting the dominant phyllosphere and rhizosphere bacterial genera included soil water content, pH, soil arsenic and zinc, total nitrogen, and sulfur of B. ischaemum, as well as plant cadmium and chromium. Furthermore, the Shannon diversity indices of rhizosphere bacterial communities were negatively correlated with root copper contents, and Simpson indices were positively correlated with root total nitrogen. There was a significant positive correlation between the ACE index and leaf total sculpture. These results provide a scientific basis for the exploration and utilization of phyllosphere and rhizosphere bacterial resources, and could improve the efficiency of ecological restoration in copper tailings.
Subject(s)
Copper , Rhizosphere , Copper/analysis , Ecosystem , Poaceae , Soil , Soil MicrobiologyABSTRACT
To date, no specific drug has been discovered for the treatment of COVID-19 and hence, people are in a state of anxiety. Thus, there is an urgent need to search for various possible strategies including nutritional supplementation. In this study, we have tried to provide a reference for protein supplementation. Specifically, 20 marine fish proteins were subjected to in silico hydrolysis by gastrointestinal enzymes, and a large number of active peptides were generated. Then, the binding abilities of these peptides to SARS-CoV-2 main protease and monoamine oxidase A were assessed. The results showed that NADH dehydrogenase could be a good protein source in generating potent binders to the two enzymes, followed by cytochrome b. In addition, some high-affinity oligopeptides (VIQY, ICIY, PISQF, VISAW, AIPAW, and PVSQF) were identified as dual binders to the two enzymes. In summary, the supplementation of some fish proteins can be helpful for COVID-19 patients; the identified oligopeptides can be used as the lead compounds to design potential inhibitors against COVID-19 and anxiety.
Subject(s)
Antiviral Agents/metabolism , Betacoronavirus/metabolism , Coronavirus Infections/virology , Dietary Supplements , Fish Proteins/metabolism , Monoamine Oxidase/metabolism , Pneumonia, Viral/virology , Animals , Antiviral Agents/chemistry , Antiviral Agents/therapeutic use , Aquatic Organisms , Betacoronavirus/enzymology , COVID-19 , Coronavirus Infections/drug therapy , Decapodiformes/metabolism , Fish Proteins/chemistry , Fish Proteins/therapeutic use , Fishes/metabolism , Models, Molecular , Molecular Docking Simulation , Monoamine Oxidase Inhibitors , Pandemics , Perciformes/metabolism , Pneumonia, Viral/drug therapy , Protein Binding , Protein Conformation , SARS-CoV-2 , Salmon/metabolism , Tuna/metabolismABSTRACT
A combined soil bacterial and fungal community survey was conducted for a copper tailings dam in the Chinese Loess Plateau. We investigated the seasonal differences in the composition and function of soil microbial community to examine the key environmental factors influencing soil microorganisms during restorative ecological processes. Significant seasonal differences were found in the community structure of both bacterial and fungal communities. Bacterial community abundance and fungal community (Shannon index) measurements were highest in summer. Soil nitrite nitrogen (NO2 --N) was the dominant factor influencing both bacterial and fungal communities. The bacterial community composition was significantly affected by NO2 --N and ammonium nitrogen (NH4 +-N) in spring, and fungal community structure was significantly affected by soil water content in autumn. Moreover, the fungal community exhibited significant functional feature differences among seasons, whereas bacterial community functional groups remained similar. This study aimed to clarify the adaptation response of microbes applying different approaches used in ecological restoration approaches specific to mining areas, and to identify the natural biofertility capacity of the microbial communities that colonize soil ecosystems.
ABSTRACT
Interactions between plants and microbes can affect ecosystem functions, and many studies have demonstrated that plant properties influence mutualistic microorganisms. Here, high-throughput sequencing was used to investigate rhizosphere and phyllosphere fungal communities during different plant development stages. Results demonstrated that phyllosphere and rhizosphere fungal community structures were distinct during all developmental stages while they were mediated separately by plant carbon and soil sulfur. Comparatively, the effect of root properties on phyllosphere fungal diversity was greater than soil properties. Moreover, rhizosphere fungal networks of Bothriochloa ischaemum were more complex than phyllosphere fungal networks. This study demonstrated that the effect of plant and soil traits on phyllosphere and rhizosphere fungal communities could potentially be significant, depending on the applicable environmental condition and plant development stage. Although links between phyllosphere and rhizosphere communities have been established, further studies on functional fungal groups during phytoremediation processes are necessary. This study comprehensively analyzed dynamic relationships between phyllosphere and rhizosphere fungal communities during different plant development stages in a polluted environment. These fungal communities were determined to be expedient to the development and utilization of beneficial microbial communities during different development stages, which could more effectively help to stabilize and reclaim contaminated copper tailings soil.
ABSTRACT
Copper mining and the byproducts associated with the industry have led to serious pollution in the Loess Plateau of China. There is a potential in improving the ecological restoration efficiency of such degraded land through combining microbial and plant remediation approaches. However, the community structure and function of phyllosphere and rhizosphere microorganisms and their response to plant development in copper tailings dams are poorly understood. This study investigated the impact of the phyllosphere and rhizosphere microbial communities on Bothriochloa ischaemum during three distinct plant development stages: seedling, tiller, and mature. The relative species abundance and Shannon index of bacterial communities of the rhizosphere during the seedling and tiller stages were distinct from that in the mature stage. Dominant bacteria at the level of phyla, such as Proteobacteria, Cyanobacteria, Actinobacteria, and Bacteroidetes, followed distinct patterns associated with plant development in the phyllosphere, but the predominant bacteria were similar in the rhizosphere. Redundancy analysis showed that aboveground total nitrogen and the carbon and nitrogen ratio of this plant species significantly affected phyllosphere bacterial community structure, whereas soil water content, soil nutrients, electrical conductivity, and salinity significantly affected rhizosphere bacterial community structure. Moreover, keystone phyllosphere and rhizosphere bacterial species differed significantly. This study sheds new light on understanding the dynamic relationship of phyllosphere and rhizosphere bacterial communities during plant development in copper tailings. These results are beneficial to the development and utilization of beneficial microbial communities at different stages of development, which might help to reclaim and stabilize tailings more effectively.