Title:	Alterations in plant architecture and physiology allow maize to sustain yield after early defoliation.
Authors:	OLIVEIRA, D. de MARQUES, D. M. CASTRO, Y. A. MAGALHAES, P. C. BORGHI, E. KARAM, D. SANTOS FILHO, P. R. dos CARDOSO, A. A. SOUZA, T. C. de
Affiliation:	DANIELLE DE OLIVEIRA, UNIVERSIDADE FEDERAL DE ALFENAS; DANIELE MARIA MARQUES, UNIVERSIDADE FEDERAL DE ALFENAS; YAGO AFONSO CASTRO, UNIVERSIDADE FEDERAL DE ALFENAS; PAULO CESAR MAGALHAES, CNPMS; EMERSON BORGHI, CPPSE; DECIO KARAM, CNPMS; PLINIO RODRIGUES DOS SANTOS FILHO, UNIVERSIDADE FEDERAL DE ALFENAS; AMANDA A. CARDOSO, NORTH CAROLINA STATE UNIVERSITY; THIAGO CORRÊA DE SOUZA, UNIVERSIDADE FEDERAL DE ALFENAS.
Date Issued:	2026
Citation:	Agrosystem, Geoscience & Environment, v. 9, e70295, 2026.
Description:	Maize (Zea mays L.) tolerance to early defoliation is shaped by genotype-specific physiological and morphological responses. Defoliation disrupts the source–sink balance, altering carbon allocation and plant development. Understanding these responses is crucial for optimizing breeding programs and agronomic management. In this study, the effects of complete canopy defoliation at vegetative stage 4 on growth parameters, root morphology, chlorophyll fluorescence, and yield stability in four maize genotypes were evaluated. Defoliation significantly reduced total leaf area, plant height, and root biomass while increasing root tissue density and the harvest index across all genotypes. Despite these structural changes, no significant differences were observed in key yield components, especially grain yield. Chlorophyll fluorescence analysis revealed distinct genotype-specific responses. Under defoliation, KWS9606 VIP3 exhibited enhanced photochemical efficiency at 9 days after defoliation (DAD) and increased quenching photochemical (qP) at 17 and 24 DAD. While BRS1010, qP increased under defoliation at all dates, suggesting greater openness of PSII reaction centers. NPQ responses were variable and lacked a consistent pattern, indicating diverse energy dissipation strategies. NS90 PRO2 exhibited Maize (Zea mays L.) tolerance to early defoliation is shaped by genotype-specific physiological and morphological responses. Defoliation disrupts the source–sink balance, altering carbon allocation and plant development. Understanding these responses is crucial for optimizing breeding programs and agronomic management. In this study, the effects of complete canopy defoliation at vegetative stage 4 on growth parameters, root morphology, chlorophyll fluorescence, and yield stability in four maize genotypes were evaluated. Defoliation significantly reduced total leaf area, plant height, and root biomass while increasing root tissue density and the harvest index across all genotypes. Despite these structural changes, no significant differences were observed in key yield components, especially grain yield. Chlorophyll fluorescence analysis revealed distinct genotype-specific responses. Under defoliation, KWS9606 VIP3 exhibited enhanced photochemical efficiency at 9 days after defoliation (DAD) and increased quenching photochemical (qP) at 17 and 24 DAD. While BRS1010, qP increased under defoliation at all dates, suggesting greater openness of PSII reaction centers. NPQ responses were variable and lacked a consistent pattern, indicating diverse energy dissipation strategies. NS90 PRO2 exhibited
Thesagro:	Milho Zea Mays Fisiologia Vegetal Produtividade Desfolha
NAL Thesaurus:	Plant physiology Defoliation
DOI:	https://doi.org/10.1002/agg2.70295
Type of Material:	Artigo de periódico
Access:	openAccess
Appears in Collections:	Artigo em periódico indexado (CNPMS)