Soil Type Influences Novel "Milpa" Isolates of Virens and That Promote Solubilization, Mineralization, and Phytoabsorption of Phosphorus in L

Overview

Journal J Fungi (Basel)

Date 2022 Nov 10

PMID 36354945

Authors

Dorcas Zuniga-Silgado

Ayixon Sanchez-Reyes

Maria Laura Ortiz-Hernandez

Miranda Otero

Edgar Balcazar-Lopez

Susana Valencia-Diaz

Mario Serrano

Jeffrey J Coleman

Luis Sarmiento-Lopez

Luz E de-Bashan

Jorge Luis Folch-Mallol

Affiliations

Soon will be listed here.

Abstract

The genus has significant economic importance since it is cultivated and consumed worldwide for its flavor and pungent properties. In 2021, Mexico produced 3.3 billion tons on 45,000 hectares which yielded USD 2 billion in exports to the USA, Canada, Japan, etc. Soil type has a dramatic effect on phosphorus (P) availability for plantsdue to its ion retention.In a previous study, novel fungal isolates were shown to solubilize and mineralize P in different kinds of soils with different P retention capacities. The aim of this work was to study the effects of the mineralogy of different kinds of "milpa" soils on the germination, biomass production, and P absorption of chili plants (). The germination percentage, the germination speed index, and the mean germination time were significantly increased in the plants treated with dual inoculation. Foliar phosphorus, growth variables, and plant biomass of chili plants grown in a greenhouse were enhanced in different soil types and with different inocula. Correlation studies suggested that the most significant performance in the foliar P concentration and in the growth response of plants was achieved in Vertisol with dual inoculation of 7 × 10 mL spores per chili plant, suggesting this would be an appropriate approach to enhance chili cultivation depending on the soil type. This study stresses the importance of careful analysis of the effect of the soil type in the plant-microbe interactions.

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