Dynamic protoneural networks in plants

Debono, Marc-Williams

doi:10.4161/psb.24207

Cited by 23 publications

(18 citation statements)

References 82 publications

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“…As previously suggested 12,15 the dynamic of global electrical signals in plants, emerging from the integration of local (cell-tocell) electrical activity, is not a pure stochastic noise (white noise), and can be related to the physiologic state of the plants under different environmental conditions. A variety of natural phenomena are well described by 1/f btype noises, with b ranging from 0 (white noise) to > 2 (reddened noise)., 19,23,24 In our study, the interval of the b exponents values (often from 1.5 up to 3) of the PSD functions (Fig.…”

Section: Discussionmentioning

confidence: 95%

“…Thus, the dynamic that emerges from integration of electrical signals of each cell in a tissue must exhibits a high level of complexity. On the other hand, as observed herein, eventual bursts of spikes emerge as an outcome of self-organized collective behavior among groups of cells., 15,16 To try elucidating the possible roles of the temporal dynamic of electrical signaling in the plant-environment relationship, our study brings evidence that plants can be pushed to a selforganized critical state under some specific situations. The power law distribution of the spikes in the log-log histogram (pdf), only in plants subjected to environmental stimuli supports this hypothesis.…”

Section: E1290040-4mentioning

confidence: 99%

“…This complex system transports, integrates and processes electrical and molecular signals that can stores information and engenders a genetic and cognitive memory that operate together. 13 In plants, based on empirical studies, 14 Debono 15 have correlated electrophytografic activity (EPG) as resultant of an integration of intracellular APs derivate from synchronized "protoneural networks," diffusing information at the whole plant level. EPGs are extracellular spontaneous surface potential variations, as well as evoked bursts of spikes recorded at the level of leaves or roots.…”

Section: Introductionmentioning

confidence: 99%

“…Accordingly, low voltage potential variations recorded at the level of group of polarized cells or tissues could participate to the fine regulation of physiologic functions of plants. 15 In the present study, we have investigated how the low-voltage electrical signals of soybean seedlings change their temporal dynamic under different constant environmental conditions. Herein, to work on a specific framework to settle this type of the study, we are adopting the term "electrome" 13 as a reference to the non-local electrophysiology measurements.…”

Section: Introductionmentioning

confidence: 99%

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Plant “electrome” can be pushed toward a self-organized critical state by external cues: Evidences from a study with soybean seedlings subject to different environmental conditions

Souza

Ferreira

Saraiva

et al. 2017

Plant Signaling & Behavior

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In the present study, we have investigated how the low-voltage electrical signals of soybean seedlings change their temporal dynamic under different environmental conditions (cold, low light, and low osmotic potential). We have used electrophytografic technique (EPG) with sub-dermal electrodes inserted in 15-days-old seedlings located between root and shoot, accounting for a significant part of the individual seedlings. Herein, to work on a specific framework to settle this type of the study, we are adopting the term "electrome" as a reference to the totality of electrical activity measured. Taking into account the non-linear dynamic of the plants electrophysiology, we have hypothesized that the stimuli, as applied in a constant way, could push the system to a critical state, exhibiting spikes without a characteristic size, indicating self-organized criticality (SOC). The results from the power spectral density analysis (PSD), showed that the interval of the large majority of the β exponents were between 1.5 and 3, indicating that the time series, regardless environmental conditions, showed long-range temporal correlation (long memory for β≠0 and β≠2). The analyses from the histograms of the runs showed different patterns of distributions concerning the experimental conditions. However, the runs exhibiting typical spikes, mostly under low light and osmotic stress, showed power law distribution with exponent μ ≅ 2, which is an indicative for SOC. Overall, our results have confirmed that the temporal dynamic of the electrical signaling shows a complex non-linear behavior with long-range persistence. Moreover, the hypothesis that plant electrome can exhibit a self-organized critical state evoked by environmental cues, dissipating energy by bursts of electrical spikes without a characteristic size, was reinforced. Finally, new perspectives for research and additional hypothesis were presented.

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Section: Discussionmentioning

confidence: 95%

Section: E1290040-4mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plant “electrome” can be pushed toward a self-organized critical state by external cues: Evidences from a study with soybean seedlings subject to different environmental conditions

Souza

Ferreira

Saraiva

et al. 2017

Plant Signaling & Behavior

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“…Currently, the mainstream of plant sciences considers plants for passive automata-like organisms, lacking any sensory-motoric circuits. But this position, which is based on ancient Aristotelian worldviews, depriving plants of cognition-relevant sensitivities and activities are not tenable anymore (Brenner et al, 2006, 2007;Trewavas, 2007, Trewavas, 2009; Barlow, 2008; Baluška, 2009; Calvo and Keijzer, 2010; Karpiński, 2010; and Szechyńska-Hebda, 2010;; Trewavas and Baluška, 2011; Marder, 2012, 2013; Debono, 2013). Especially root behavior shows cognitive features which are not possible to explain with currently dominated views of passive, automata-like organisms (Baluška et al, 2010b; Barlow, 2010a, b; Gagliano et al, 2012).…”

Section: Perspectives and Outlookmentioning

confidence: 99%

Root Apex Transition Zone As Oscillatory Zone

Baluška¹,

Mancuso²

2013

Front. Plant Sci.

118

140

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Root apex of higher plants shows very high sensitivity to environmental stimuli. The root cap acts as the most prominent plant sensory organ; sensing diverse physical parameters such as gravity, light, humidity, oxygen, and critical inorganic nutrients. However, the motoric responses to these stimuli are accomplished in the elongation region. This spatial discrepancy was solved when we have discovered and characterized the transition zone which is interpolated between the apical meristem and the subapical elongation zone. Cells of this zone are very active in the cytoskeletal rearrangements, endocytosis and endocytic vesicle recycling, as well as in electric activities. Here we discuss the oscillatory nature of the transition zone which, together with several other features of this zone, suggest that it acts as some kind of command center. In accordance with the early proposal of Charles and Francis Darwin, cells of this root zone receive sensory information from the root cap and instruct the motoric responses of cells in the elongation zone.

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Mesological Plasticity as a New Model to Study Plant Cognition, Interactive Ecosystems, and Self-Organized Evolutionary Processes

Debono¹

2022

Evolutionary Biology – New Perspectives on Its Development

Self Cite

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The plasticity of living systems acts at several levels of evolutionary biology including self-organization, phenotypic, phylo-, onto-and epigenetic processes, while mesology is an approach situated in between ecology and phenomenology. After a description of the specific objects of plasticity and mesology as non-dualist studies of the dynamical coupling between beings and their singular milieu, we will develop some arguments regarding the perception-action loop and the sensory flux of informations crossing the evolution of the living, before focusing on recent discoveries about plant electrome. Using for the first time mesological plasticity as a frame to reanalyze the Uexcküll's assertions about Umwelt and meaning-making theories of plants, this chapter shows the leading rule of electromic interfaces in the generation of spontaneous low-voltage variations continuously emitted by plants via electrophytographic or EPG recordings. Used as early markers, EPGs are considered in this framework as natural systems of monitoring and discrimination of environmental stimuli that allow the identification of the electromic signature of a plant-stimulus pair in a given milieu.More generally, we will develop the trajections associated with complex behaviours of plants: a bottom-up transdisciplinary view of co-evolutionary or ecosemiotic processes highlighting their specific sensitive fields and cognitive accesses to experience (their otherness) as well as new phenomenologies about interactive ecosystems and phytosemiotics.

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Dynamic protoneural networks in plants

Cited by 23 publications

References 82 publications

Plant “electrome” can be pushed toward a self-organized critical state by external cues: Evidences from a study with soybean seedlings subject to different environmental conditions

Plant “electrome” can be pushed toward a self-organized critical state by external cues: Evidences from a study with soybean seedlings subject to different environmental conditions

Root Apex Transition Zone As Oscillatory Zone

Mesological Plasticity as a New Model to Study Plant Cognition, Interactive Ecosystems, and Self-Organized Evolutionary Processes

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