A Pictorial Vision of Free Rhythm in Plant Movement

Plant Movement and Seed Dispersal of Russian Thistle (Salsola iberica)

Weed Science ◽

10.1017/s0043174500080838 ◽

1995 ◽

Vol 43 (1) ◽

pp. 63-69 ◽

Cited By ~ 30

Author(s):

George P. Stallings ◽

Donald C. Thill ◽

Carol A. Mallory-Smith ◽

Lawrence W. Lass

Keyword(s):

Seed Dispersal ◽

Individual Plant ◽

Positioning Systems ◽

Average Percentage ◽

Seed Loss ◽

Adjacent Site ◽

Wheat Stubble ◽

Plant Movement ◽

Eastern Washington ◽

Salsola Iberica

Russian thistle plant movement and seed dispersal were studied in 1991 and 1992 by placing Russian thistle plants in the center of wheat fields in eastern Washington. Three adjacent site treatments, with 24 plants on each site, were used each year; wheat stubble, summerfallow planted to winter wheat, and a “stationary” site. Plants in the “stationary” site were anchored to the ground to prevent tumbling. Plants in the stubble and summerfallow sites were allowed to tumble naturally. Individual plant movement was monitored and recorded weekly by satellite global positioning systems technology. Average estimated seed number per plant at the beginning of the experiment was 57,400 in 1991 and 66,000 in 1992. The direction plants moved correlated highly with wind direction. Some plants moved a maximum distance of 4069 m in 6 wks, while other plants moved only 60 m because of variable winds and being compressed by snow or frozen into wheat stubble. Average percentage seed loss in 1991 and 1992 for stationary plants was 15 and 26%, and for tumbling plants was 48 and 66%, respectively.

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Measurement of plant movement in young and mature plants using electronic speckle pattern interferometry

Applied Optics ◽

10.1364/ao.35.003695 ◽

1996 ◽

Vol 35 (19) ◽

pp. 3695 ◽

Cited By ~ 5

Author(s):

Astrid Aksnes Dyrseth

Keyword(s):

Speckle Pattern ◽

Electronic Speckle Pattern Interferometry ◽

Plant Movement

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A model of the plant-to-plant movement of aphids II. Estimation of parameters and the application

Researches on Population Ecology ◽

10.1007/bf02514738 ◽

1968 ◽

Vol 10 (1) ◽

pp. 105-114 ◽

Cited By ~ 4

Author(s):

Masae Shiyomi

Keyword(s):

Estimation Of Parameters ◽

Plant Movement

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On-Plant Movement and Feeding of Western Bean Cutworm (Lepidoptera: Noctuidae) Early Instars on Corn

Environmental Entomology ◽

10.1603/en12149 ◽

2012 ◽

Vol 41 (6) ◽

pp. 1494-1500 ◽

Cited By ~ 18

Author(s):

S. V. Paula-Moraes ◽

T. E. Hunt ◽

R. J. Wright ◽

G. L. Hein ◽

E. E. Blankenship

Keyword(s):

Western Bean Cutworm ◽

Plant Movement ◽

Lepidoptera Noctuidae

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Functional–morphological analyses of the delicate snap-traps of the aquatic carnivorous waterwheel plant (Aldrovanda vesiculosa) with 2D and 3D imaging techniques

Annals of Botany ◽

10.1093/aob/mcaa135 ◽

2020 ◽

Vol 126 (6) ◽

pp. 1099-1107 ◽

Cited By ~ 1

Author(s):

Anna S Westermeier ◽

Natalie Hiss ◽

Thomas Speck ◽

Simon Poppinga

Keyword(s):

3D Imaging ◽

Imaging Techniques ◽

Agent Based ◽

Dionaea Muscipula ◽

Adaptive Architecture ◽

Plant Movement ◽

2D And 3D ◽

First Time ◽

Structural Insights ◽

Successful Capture

Abstract Background and Aims The endangered aquatic carnivorous waterwheel plant (Aldrovanda vesiculosa) catches prey with 3–5-mm-long underwater snap-traps. Trapping lasts 10–20 ms, which is 10-fold faster than in its famous sister, the terrestrial Venus flytrap (Dionaea muscipula). After successful capture, the trap narrows further and forms a ‘stomach’ for the digestion of prey, the so-called ‘sickle-shaped cavity’. To date, knowledge is very scarce regarding the deformation process during narrowing and consequent functional morphology of the trap. Methods We performed comparative analyses of virtual 3D histology using computed tomography (CT) and conventional 2D histology. For 3D histology we established a contrasting agent-based preparation protocol tailored for delicate underwater plant tissues. Key Results Our analyses reveal new structural insights into the adaptive architecture of the complex A. vesiculosa snap-trap. In particular, we discuss in detail the arrangement of sensitive trigger hairs inside the trap and present actual 3D representations of traps with prey. In addition, we provide trap volume calculations at different narrowing stages. Furthermore, the motile zone close to the trap midrib, which is thought to promote not only the fast trap closure by hydraulics but also the subsequent trap narrowing and trap reopening, is described and discussed for the first time in its entirety. Conclusions Our research contributes to the understanding of a complex, fast and reversible underwater plant movement and supplements preparation protocols for CT analyses of other non-lignified and sensitive plant structures.

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