Loading…

Change in the Physiological Aspects of Soybean Caused by Infestation by Bemisia tabaci MEAM1

Whiteflies cause significant crop losses through direct sap feeding, inducing plant physiological disorders and promoting the growth of sooty mold. Moreover, whiteflies can indirectly harm plants by transmitting plant viruses, particularly begomoviruses and criniviruses, resulting in severe viral di...

Full description

Saved in:
Bibliographic Details
Published in:Agronomy (Basel) 2024-03, Vol.14 (3), p.481
Main Authors: Silva, Luciana B., Almeida, Lucas C., e Silva, Maria C. F., Brito, Ramilos R. de, Miranda, Rafael de S., Rodrigues, Raimundo H. F., Santos, Carlos M. P. dos, Ribeiro, Gilvana da S., Morais, João V. S., Silva, Alisson F. T. da, Mayard, Hernesise, Oliveira, Thayline Rodrigues de, Costa Lima, Vânia Maria Gomes da, Silva Fontes, Lucia da, Rocha, Neurandir Sobrinho da, Jesus Lacerda, Julian de, Pavan, Bruno Ettore
Format: Article
Language:English
Subjects:
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Whiteflies cause significant crop losses through direct sap feeding, inducing plant physiological disorders and promoting the growth of sooty mold. Moreover, whiteflies can indirectly harm plants by transmitting plant viruses, particularly begomoviruses and criniviruses, resulting in severe viral disease epidemics. This study aimed to evaluate the physiological characteristics of susceptible and resistant soybean cultivars to B. tabaci. The experiments were conducted in a greenhouse. Eleven soybean cultivars were selected and infested with 100 adults of B. tabaci at the V3 stage. The evaluation of photosynthetic parameters, such as photosynthetic rate, leaf transpiration, stomatal conductance, and internal CO2 concentration, revealed that B. tabaci infestation influenced gas exchange in soybean plants. The photosynthetic rate was higher in cultivars AS3810 and M8349 during the V6 stage. Infestations caused alterations in photosynthetic parameters, suggesting increased energy demand to maintain photosynthetic activity. However, the response to infestation varied among the different cultivars, indicating varying levels of resistance and tolerance to the whitefly’s damage. Furthermore, the infestation had a more notable impact during the vegetative phenological stage. In summary, infestation by B. tabaci has a discernible impact on the physiology of soybean plants, resulting in alterations in gas exchange parameters and water use efficiency. The reaction to infestation exhibited variations among different soybean cultivars, indicating potential differences in resistance to the pest. This study underscores the significance of assessing the physiological consequences of whitefly infestations on soybean crops.
ISSN:2073-4395
2073-4395
DOI:10.3390/agronomy14030481