Hola,
¿eres nuevo aquí?

Regístrate gratis y conecta tu empresa con financiación pública, partners y proyectos.

Tengo cuenta

Regístrate

Ver video

maxSYMize

Financiado

Cerrado

Harnessing mechanisms for plant carbon delivery to symbiotic soil fungi for sust...

Harnessing mechanisms for plant carbon delivery to symbiotic soil fungi for sustainable food production The arbuscular mycorrhizal (AM) symbiosis between plants and symbiotic soil fungi confers key nutritional benefits to plants: AM fungi increase plant productivity by up to 30% by improving mineral nutrient uptake from the soil. In... ver más

31/01/2030

THE CHANCELLOR MAS...

1M€

Presupuesto del proyecto: 1M€

Líder del proyecto

THE CHANCELLOR MASTERS AND SCHOLARS OF THE UN... No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

Fecha límite participación Sin fecha límite de participación.

Financiación concedida El organismo HORIZON EUROPE notifico la concesión del proyecto el día 2024-10-09

ERC-2024-STG: ERC STARTING GRANTS Scope:Objectives

I+D

Cerrada hace 1 año

0% 100% 100%

Características del participante

Este proyecto no cuenta con búsquedas de partenariado abiertas en este momento.

Información adicional privada

No hay información privada compartida para este proyecto. Habla con el coordinador.

1 Participantes

THE CHANCELLOR MASTERS AND S...

1.50M€ | Lider

Conecta tu I+D

¿Tienes un proyecto y buscas un partner? Gracias a nuestro motor inteligente podemos recomendarte los mejores socios y ponerte en contacto con ellos. Te lo explicamos en este video

Duración del proyecto: 63 meses Fecha Inicio: 2024-10-09
Fecha Fin: 2030-01-31

Líder del proyecto

THE CHANCELLOR MASTERS AND SCHOLARS OF THE UN... No se ha especificado una descripción o un objeto social para esta compañía.

TRL 4-5

Presupuesto del proyecto 1M€

Fecha límite de participación Sin fecha límite de participación.

Descripción del proyecto The arbuscular mycorrhizal (AM) symbiosis between plants and symbiotic soil fungi confers key nutritional benefits to plants: AM fungi increase plant productivity by up to 30% by improving mineral nutrient uptake from the soil. In exchange for these nutrients, plants transfer more than one gigaton of photosynthetically fixed carbon each year to the AM fungal network in the soil. This carbon transfer has a major impact not just on plant and fungal physiology, but also on the global carbon cycle. My previous work identified a molecular pathway in plant roots that is activated during fungal colonization of root cells and transfers fixed carbon to AM fungi in the form of lipids. This finding represents a breakthrough in the field of AM symbiosis as we were able to describe, for the first time, how and in which form carbon is delivered to AM fungi. My discovery unlocks an opportunity: I propose to engineer the model crop rice to maximise carbon delivery to the fungal mycelium by exploiting the mechanisms underpinning carbon allocation to AM fungi. This approach could lead to enhanced nutrient uptake by promoting the symbiotic association, thereby reducing the need for synthetic fertilizer. Moreover, it also has the potential to increase carbon sequestration and soil fertility. However, it is currently unknown how plant carbon metabolism is altered at a whole plant level to increase carbon flux to the fungal mycelium, and how plants control the amount of carbon allocated to AM fungi. To achieve this ambitious aim, I will exploit the recent technological advances in genetics, carbon tracing, and single cell transcriptomics to map the carbon allocation pathway from leaves to roots and to AM fungi at single cell resolution (aim 1) and identify the genetic and transcriptional regulators of this pathway (aim 2). These insights, along with established knowledge, will be used to maximise carbon delivery from crop plants to the fungal mycelium in the soil (aim 3).

Conecta tu I+D

Entra hoy

¿Olvidé mi contraseña?

Financiación

Empresas

CTIs/Universidades

Proyectos

Investigadores