Articles tagged with Nitrogen Fixing Bacteria
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A new international study reveals that nitrogen fixation occurs beneath Arctic sea ice, increasing available nitrogen for algae and potentially boosting marine life. This discovery could also impact carbon absorption in the Arctic Ocean.
Researchers found that bean plants and other species evolved a predisposition for the symbiosis at least three times, supporting a long-standing theory. This biological trick allows plants to access atmospheric nitrogen, boosting crop yields.
Researchers studied a microscopic alliance between algae and cyanobacteria to understand how bacteria lose genes and adapt to increasing host dependence. The study found that the level of integration between the symbionts affects genome size, gene content, and metabolic pathways.
Researchers have identified clusters of genes in rhizobia that drive greater plant biomass in legumes, shedding light on the complex chemical interactions between host and bacterial genomes. The study's findings could help optimize plant growth by improving the rhizosphere.
Research led by Michigan State University suggests that an enzyme called NrfA can help retain nitrogen in soil, reducing the need for fertilizer and preventing harmful algal blooms. This could have significant positive agricultural implications.
Researchers have found new organisms that can capture carbon dioxide and clean pollutants from the environment. By exploring extremophiles in homes, scientists can gain insights into their unique characteristics and develop sustainable solutions.
A recent study from the University of Illinois shows that gene-edited bacteria can supply equivalent of 35 pounds of nitrogen from air during early corn growth, increasing vegetative growth, nitrogen accumulation and yield by an average of 2 bushels per acre.
Researchers at John Innes Centre have discovered a biological mechanism that enhances partnerships between plant roots and soil microbes, increasing nutrient uptake. This finding holds great potential for advancing sustainable agriculture by reducing the need for inorganic fertilizers.
Researchers at the University of California - San Diego uncovered the 'method of last resort' mechanism used by diazotrophs to protect their nitrogenase enzyme from oxygen damage. This complex process involves a protein called FeSII, which binds to the nitrogenase and halts ammonia production when oxygen levels increase.
A study found that nitrogen-fixing bacteria in soil enhance flowers' attractiveness to bumblebees. Plants with these bacteria grew significantly taller and larger than those without, and their flowers became more vibrant and attractive to pollinators.
Researchers at the University of Cambridge have discovered that the plant hormone gibberellin is essential for legume nitrogen-fixing root nodule formation and maturation. The study used a highly sensitive next-generation biosensor to visualize GA accumulation in specific zones of the root, revealing its critical role in nodulation.
A new study by RIKEN CSRS shows that biomass from purple photosynthetic marine bacterium Rhodovulum sulfidophilum is an excellent nitrogen fertilizer, effective as inorganic synthetic fertilizers but with lower environmental side effects. The biomass boosts plant growth without altering soil pH or salinity.
Researchers studied bacterial evolution in lucinid clams surrounding the Isthmus of Panama, where Caribbean and Pacific environments differ significantly. The study found that symbiotic bacteria adapted to these changes by acquiring nitrogen fixation genes and developing unique metabolic capabilities.
A new study in Nature Communications reveals that symbiotic bacteria play a critical role in modulating the profile of root secreted molecules, influencing the assembly of a symbiotic root microbiome. The findings provide valuable insights into the complex interplay between nitrogen nutrition and plant-bacteria interactions.
Researchers have discovered the first known nitrogen-fixing organelle within a eukaryotic cell, which challenges current understanding of biological nitrogen fixation. The discovery provides insight into ocean ecosystems and has potential implications for agriculture.
Researchers found a symbiotic relationship between cyanobacteria UCYN-A and marine algae, B. bigelowii, where UCYN-A fix nitrogen gas into ammonium without regulating dinitrogen use. This suggests they may be on the path to becoming organelle-like structures.
Legume plants have a unique ability to interact with nitrogen-fixing bacteria, allowing them to thrive without external nitrogen. Researchers identified four essential phosphorylation sites on the SYMRK kinase that mediate this symbiotic relationship.
Researchers discovered IMA peptides facilitate iron transport to root nodules for nitrogen fixation in legume plants. These peptides maintain nitrogen homeostasis and regulate plant growth in response to increased nitrogen concentrations.
Researchers have identified two genetic factors, LSH1/LSH2, that promote the production of specialized root cells required for nitrogen-fixing bacteria to thrive in legumes. This discovery brings us closer to engineering non-legume crops to develop root nodule organs and reduce our reliance on industrial nitrogen fertilizers.
A new study reveals that cycad species that survived the dinosaur extinction relied on symbiotic bacteria in their roots for nitrogen. This discovery sheds light on how these plants adapted to changing environments and could provide insights into understanding Earth's climate history.
Researchers developed a metal-organic coating that protects bacterial cells from damage without impeding their growth or function. The coated bacteria improved the germination rate of various seeds by 150 percent, making it possible to deploy microbes as fertilizers for large-scale agricultural use.
Researchers found that competition between beneficial bacterial strains degrades the service they provide to plants, resulting in smaller benefits. The study used native California plant and eight compatible nitrogen-fixing bacterial strains to directly measure their ability to infect plants and provide benefits.
Researchers discovered a symbiotic relationship between diatom Hemiaulus hauckii and cyanobacterium Richelia euintracellularis, with the diatom supplying reduced organic compounds to support nitrogen fixation. The study found that proteins from the endosymbiont play a crucial role in molecule transport across cell membranes.
Researchers developed a novel strategy to engineer root nodule symbiosis in legumes and cereals using nanobodies. This approach, tested in barley and Lotus plants, initiates nodulation by bringing receptors together, revealing the core complex involved in symbiotic signaling.
A recent study discovered a legume locus that stimulates promiscuous interaction with soil bacteria, forming nitrogen-fixing nodules with up to 30 different rhizobial strains. This finding opens the door for crop improvement by naturally promoting plant growth through symbiotic associations.
A comprehensive study reveals that nitrogen-fixers are most diverse in arid regions of the US, contrary to expectations. Plants have evolved creative ways to acquire nitrogen, and their diversity increases in these environments due to adaptations such as thicker cuticles.
Researchers at MIT discovered a peptide that sequesters heme, an iron-containing molecule, and sends bacteria into an iron-starvation mode, potentially treating diseases like periodontal disease and sickle cell disease. This finding could translate to therapeutic applications for patients with excessive heme in their blood.
Researchers at the University of California, Davis have discovered a new pathway for cereals to capture nitrogen from the air, reducing the need for expensive fertilizers. The breakthrough could save farmers billions of dollars annually and benefit the environment by decreasing nitrogen pollution.
Researchers at Rutgers University have made a groundbreaking discovery about nitrogen-fixing bacteria in leaf cells, which can provide plants with essential nutrients. This breakthrough has the potential to transform crop cultivation methods, reducing the environmental impact of fertilizer use and preserving soil health.
The John Innes Centre researchers identified the role of the signaling protein CaM2, which regulates calcium channels and shapes calcium signals. This led to accelerated calcium frequency, earlier signaling with bacteria, and enhanced root nodule symbiosis in engineered legume roots.
Researchers found that desert microbes produce nitrous oxide (N2O) emissions in arid soils after rain, contradicting the long-held assumption that it comes from fertilized agricultural fields. The study reveals a new source of nitrogen pollution in deserts, driven by fossil fuel combustion and industrial processes.
Researchers engineered Azotobacter vinelandii to produce ammonia and excrete it into crop plants, reducing water pollution. This approach could mitigate environmental pollution and provide sustainable solutions for nitrogen management in soil.
Researchers at Aarhus University have discovered how plant receptors recognize specific carbohydrate signaling molecules from their bacterial symbionts. The ability allows plants to select and accommodate nitrogen-fixing bacteria inside their roots.
Researchers identify two transcription factors regulating leghemoglobin production in legume nodules, critical for symbiotic bacteria relationships. The discovery offers potential to improve nitrogen fixation and reduce synthetic fertilizer use.
Researchers will test inexpensive techniques to increase asymbiotic nitrogen fixation, aiming to reduce reliance on expensive certified organic fertilizers. The project aims to provide evidence for a cheap, effective, and sustainable form of nitrogen for organically managed crops.
Researchers found that clover grown with symbiotic nitrogen-fixing bacteria in Martian regolith experienced significant 75% more root and shoot growth compared to uninoculated plants. However, the regolith showed no excess production of nitrogen compounds, suggesting a potential role for these microbes in terraforming Mars soils.
Researchers found that surface runoff alters microbial communities in cave pools, with sulfur-oxidizing bacteria replaced by human contaminants during heavy rains. The study highlights the impact of surface pollution on groundwater sources and cave ecosystems.
Research by plant pathologist Gary Stacey aims to develop effective inoculation protocols for biological nitrogen fixation in non-leguminous crops. The study found that bacterial colonization leads to significant shifts in plant metabolism, with some metabolites more abundant in inoculated plants.
Scientists have transferred genes into bacteria to convert nitrogen from the air into a natural fertilizer, reducing the need for man-made fertilizers. This research could increase crop production and alleviate environmental impacts, particularly in underdeveloped countries.
Researchers discovered that legumes acquire the ability to form root nodules by recruiting a lateral root developmental pathway. The ASL18a gene plays a key role in this process, allowing for cooperative action with genes NF-Y and NIN to induce cell division and nodule formation.
A recent study found that a fungus containing N2-fixing endobacteria improves rice nitrogen nutrition, increasing biomass and ammonium in treated plants. The three-kingdom interaction among the fungus, bacteria, and plant may hold the key to improving nitrogen nutrition in crop plants.
Researchers at Stellenbosch University have discovered a unique association between the Cape geophyte genus Oxalis and the nitrogen-fixing bacterial genus Bacillus. The bacteria help Oxalis fix nitrogen from the air and perform extraordinary feats of germination, with some species inheriting the bacteria from mother plant to seed.
A microRNA called miR2111 travels from leaves to roots, downregulating a gene that would hinder root responses to symbiotic bacteria. This finding helps understand the mechanisms of efficient nitrogen-fixing symbiosis and potential ways to exploit it agronomically.
An international research team has identified a new LysM receptor kinase called NRFe involved in the symbiosis between legumes and nitrogen-fixing rhizobia. The study found that NRFe plays a crucial role in robust symbiotic signalling in Lotus japonicus.
Researchers uncover an enzymatic pathway in certain microorganisms that produces both ammonia and methane simultaneously. This previously unknown route for natural methane production has significant implications for understanding microbial interactions and the environment.
Scientists will investigate the variation in benefits of plant-bacteria symbioses in California, focusing on evolution, ecology, and genetics. The five-year Dimensions of Biodiversity award aims to develop a predictive framework for understanding these interactions.
A comprehensive review highlights the potential benefits of non-rhizobia bacteria in nitrogen-fixing nodules of legumes, including improved plant fitness under environmental stress. The study's findings may lead to new organic production practices and reduced pesticide use, promoting sustainable crop productivity.
A new study reveals that ocean acidification can overwhelm benefits to nitrogen-fixing bacteria, hampering essential services for marine life. Trichodesmium cyanobacteria, which contributes up to 50% of marine nitrogen fixation, shows negative impacts under acidic conditions and with limited iron availability.
Researchers found that intact nitrogen-fixing symbiosis is necessary for taxonomically diverse and distinctive bacterial communities in legumes. This symbiotic relationship allows legumes to thrive in limited nitrogen environments and may also benefit non-legume plants.
Researchers at the University of Washington found that bacteria in tree branches can fix nitrogen, a crucial nutrient for plant growth, without requiring root nodules. This breakthrough could significantly reduce fertilizer use and costs, benefiting agricultural crops and bioenergy production.
A team of international scientists led by Maren Friesen from Michigan State University discovered a previously unknown bacteria that can fix its own nitrogen, a compound used in critical biological functions. The finding has significant implications for reducing pollution and greenhouse gas emissions, making it a 'unicorn' worth chasing.
A team of molecular biologists has found a gene that encodes a protein recognizing cell membranes surrounding symbiotic bacteria, directing other proteins to harvest nutrients. This discovery reveals the fundamental mechanisms behind plant-microbe interactions, with implications for future agricultural advances.
Researchers at UMass Amherst have identified a key molecule in nitrogen-fixing bacteria that may hold promise for improving crop yields without increasing fertilizer use. The discovery of the 'double agent' peptide could be a key factor in future efforts to improve legume crops and promote sustainable farming practices.
Researchers have discovered beneficial bacteria that live inside plant tissue, improving nitrogen use efficiency and plant growth. This breakthrough has potential benefits for sustainable agriculture with minimum environmental impacts.
Research reveals that legume plants selectively regulate access to symbiotic and endophytic bacteria, maintaining competitive symbionts in the soil. The study provides insights into genetic mechanisms controlling compatibility and identifies layers of accommodation for these microbes.
Research reveals that invasive prairie plant Lespedeza cuneata has superior performance when paired with specific bacteria, leading to increased nitrogen fixation and competitiveness. The study highlights the ecological risks of invasive species and underscores the importance of native plant partnerships in soil symbiosis.
Researchers found that plant seeds can be pre-colonized with beneficial bacteria, providing enhanced microbial protection. This discovery has significant implications for creating food-safe antimicrobials and understanding the importance of early colonization in establishing a healthy microbiome.
Researchers at Florida State University have made groundbreaking findings on a bacteriophage that infects nitrogen-fixing bacteria. The study reveals novel details about the virus's DNA and physical structure, shedding light on how it invades and impacts bacteria.
Researchers have identified a group of bacteria from the genus Burkholderia that can be used to fertilize crops without harming humans. These beneficial strains fix atmospheric nitrogen into ammonia, which helps plants thrive. The discovery has significant implications for sustainable agriculture in less productive areas.
Research shows that bacteria living in Gulf of Mexico beaches can thrive on a diet of oil by fixing nitrogen from the air, opening doors to more sophisticated cleanup techniques. However, some bacteria play an important role in the ecosystem experienced a sharp decline following the contamination.