nutrient-cycling
Nutrient cycling refers to the movement and exchange of inorganic and organic matter—including carbon, nitrogen, phosphorus, and other minerals—through ecosystems in continuous, repeating pathways. Unlike energy flow, which moves unidirectionally through food webs, nutrients are recirculated between living organisms, soil, water, and the atmosphere. For plant science, understanding these cycles is essential, as plants both depend on and actively drive nutrient availability, influencing productivity, ecosystem health, and how plants adapt to varying environmental conditions.
open_in_new WikipediaNitrogen-Fixing Cereals: Engineering nif Gene Clusters in Wheat Mit...
It points toward a future where staple crops like wheat need less synthetic fertilizer — meaning ...
Root Exudate Metabolomics Reveals Phosphorus Acquisition Strategies...
Understanding how lupins unlock phosphorus from soil could lead to crops that need far less chemi...
Strigolactone Signaling Controls Tillering Response to Phosphorus i...
Understanding how rice controls its own growth in poor soil could help farmers breed varieties th...
Phosphorus Recovery from Wastewater Using Constructed Wetlands with...
It means the phosphorus that would otherwise pollute your local waterways could instead end up ba...
Key role of moss in supplementing nitrogen for plant growth under w...
It shows that the humble mosses you see blanketing forest floors and tundra are quietly working a...
Evidence for resource transfer via common endophyte networks.
The web of fungi threading through your garden soil is even more intricate than we knew — endophy...
Long-term nutrient management shapes soil microbial and metabolic s...
The compost you turn in your backyard bin is assembling a microbial workforce that no synthetic f...
Pineapple peel cellulose based eco-friendly fertilizer nanocomposit...
It means the fertilizers of the future could be made from fruit scraps rather than petrochemicals...
Cytoplasmic flow dynamics in arbuscular mycorrhizal fungi are intri...
Every tomato, oak seedling, and wildflower meadow you've ever grown likely owes part of its root ...
Sulfur as a Central Integrator of Plant-Microbe Interactions: From ...
The garlic, kale, and broccoli in your garden use sulfur compounds as both a immune system and a ...
Five-year fertilization alters soil microbial composition and funct...
Fertilizing degraded sandy land to grow more food can quietly undermine the soil's own nutrient-r...
Hidden players in plant response to sulfur deficit and beyond: insi...
Sulfur is a nutrient that affects the flavor of vegetables like broccoli and garlic, the health o...
Temporal dynamics of nutrient elements in biochar and biochar-amend...
If you've ever added charcoal or biochar to your garden beds hoping for a quick nutrient boost, t...
Long-term localization experiments reveal aging degradation mechani...
Those small plastic-coated fertilizer pellets you spread in your garden or that farmers use on cr...
LbCDF-B encodes a vacuolar Zn transporter in Laccaria bicolor with ...
Every oak, pine, and beech in your local forest survives partly because fungi wrapped around thei...
A sea-to-soil solution for the green tides threatening shellfish aq...
Seaweed pulled off oyster beds and spread on garden soil could close the nutrient loop between oc...
Lipid-mediated responses to nutrient and other stresses: roles in p...
When you skip a watering or forget to fertilize, your garden plants are quietly reshuffling the f...
Larger soil clumps are the main gatekeepers for plant-available phosphorus
The compost you work into your garden beds builds the kind of large, loose soil clusters that sci...
Resource recovery from low-rank coal and livestock manure for susta...
Compost that could end up in your garden or on the farms that grow your food might one day be mad...
Functional characterization of LbCDF-A, an ER-localized Zn transpor...
The mushroom-forming fungi colonizing the roots of oaks, pines, and birches in your local woods a...