Effect of hydric stress-related acoustic emission on transcriptional and biochemical changes associated with a water deficit in Capsicum annuum L

Laura Helena Caicedo-Lopez; Ramon Gerardo Guevara-Gonzalez; Juan E Andrade; Adolfo Esquivel-Delgado; Andrés Esteban Perez-Matzumoto; Irineo Torres-Pacheco; Luis Miguel Contreras-Medina

doi:10.1016/j.plaphy.2021.05.011

Effect of hydric stress-related acoustic emission on transcriptional and biochemical changes associated with a water deficit in Capsicum annuum L

Plant Physiol Biochem. 2021 Aug:165:251-264. doi: 10.1016/j.plaphy.2021.05.011. Epub 2021 May 12.

Authors

Laura Helena Caicedo-Lopez¹, Ramon Gerardo Guevara-Gonzalez², Juan E Andrade³, Adolfo Esquivel-Delgado⁴, Andrés Esteban Perez-Matzumoto⁴, Irineo Torres-Pacheco², Luis Miguel Contreras-Medina⁵

Affiliations

¹ Biosystems Engineering Group, Faculty of Engineering, Autonomous University of Queretaro-Campus Amazcala, El Marques, Queretaro, Mexico; Group of Basic and Applied Bioengineering, Faculty of Engineering, Autonomous University of Queretaro-Campus Amazcala, El Marqués, Querétaro, Mexico.
² Biosystems Engineering Group, Faculty of Engineering, Autonomous University of Queretaro-Campus Amazcala, El Marques, Queretaro, Mexico.
³ Department of Food Science and Human Nutrition, The University of Illinois at Urbana-Champaign, Champaign, IL, 61801, USA.
⁴ Physical Metrology, National Metrology Center (CENAM) km 4.5 Carretera a Los Cues C.P. 76246, El Marqués, Qro, Mexico.
⁵ Group of Basic and Applied Bioengineering, Faculty of Engineering, Autonomous University of Queretaro-Campus Amazcala, El Marqués, Querétaro, Mexico. Electronic address: miguel.contreras@uaq.mx.

PMID: 34082331
DOI: 10.1016/j.plaphy.2021.05.011

Abstract

At specific vibration frequencies like ones generated by insects such as caterpillar chewing and bee's buzz-pollination turn on the plants secondary metabolism and their respective pathways gets activated. Thus, studies report that vibrations and sound waves applied to plants improves their fitness performance. Commonly, acoustic treatments for plants have used arbitrarily random frequencies. In this work, a group of signals obtained from hydric-stressed plants was recorded as vibrational patterns using a laser vibrometer. These vibration-signals were classified as representative of each condition and then externally applied as Acoustic Emission Patterns (AEP). The present research hypothesized that specific vibration frequencies could "emulate" a plant signal through mechanical energy based on tplant's ability to recognize vibration pattern similarity to a hydric status. This investigation aimed to apply the AEP's as characteristic vibrations classified as Low hydric stress (LHS), medium hydric stress (MHS), and high hydric stress (HHS) to evaluate their effect on healthy-well watered plants at two developmental stages. In the vegetative stage, the gene expression related to antioxidant and hydric stress responses was assessed. The LHS, MHS, and HHS acoustic treatments up-regulated the peroxidase (Pod) (~2.8, 1.9, and 3.6-fold change, respectively). The superoxide dismutase (Mn-sod) and phenylalanine ammonia-lyase (Pal) genes were up-regulated by HHS (~0.23 and ~0.55-fold change, respectively) and, the chalcone synthase (Chs) gene was induced by MHS (~0.63-fold-change). At the fructification stage, the MHS treatment induced a significant increase in Capsaicin content (5.88-fold change), probably through the at3and kas gene activation. Findings are correlated for a better understanding of plant responses to different multi frequency-signals tones from vibrations with potential for agricultural applications.

Keywords: Acoustic emission; Capsaicinoids; Gene transcription; Hydric stress; Physical elicitor; Plants stimulant.

MeSH terms

Acoustics
Animals
Capsicum* / genetics
Peroxidases
Phenylalanine Ammonia-Lyase
Water

Substances

Water
Peroxidases
Phenylalanine Ammonia-Lyase