Reversible Calcium-Regulated Stopcocks in Legume Sieve Tubes [W]

Knoblauch, Michael; Peters, Winfried S.; Ehlers, Katrin; Bel, Aart J. E. van

doi:10.1105/tpc.13.5.1221

Cited by 190 publications

(115 citation statements)

References 39 publications

Supporting

Mentioning

114

Contrasting

Order By: Relevance

“…Several have investigated phloem translocation speeds by further developing this dye tracing approach (Schumacher, 1948;Froelich et al, 2011;Jensen et al, 2011;Savage, Zwieniecki, and Holbrook, 2013). Dyes have also been used to quantify the capacity of loading and unloading pathways (Oparka et al, 1994;Liesche and Schulz, 2012), as well as the impact of wounding on a sieve element function (Schulz, 1992;Knoblauch et al, 2001).…”

Section: Phloem Flow Speedmentioning

confidence: 99%

Sap flow and sugar transport in plants

et al. 2016

View full text Add to dashboard Cite

Green plants are Earth's primary solar energy collectors. They harvest the energy of the Sun by converting light energy into chemical energy stored in the bonds of sugar molecules. A multitude of carefully orchestrated transport processes are needed to move water and minerals from the soil to sites of photosynthesis and to distribute energy-rich sugars throughout the plant body to support metabolism and growth. The long-distance transport happens in the plants' vascular system, where water and solutes are moved along the entire length of the plant. In this review, the current understanding of the mechanism and the quantitative description of these flows are discussed, connecting theory and experiments as far as possible. The article begins with an overview of low-Reynolds-number transport processes, followed by an introduction to the anatomy and physiology of vascular transport in the phloem and xylem. Next, sugar transport in the phloem is explored with attention given to experimental results as well as the fluid mechanics of osmotically driven flows. Then water transport in the xylem is discussed with a focus on embolism dynamics, conduit optimization, and couplings between water and sugar transport. Finally, remarks are given on some of the open questions of this research field.

show abstract

Section: Phloem Flow Speedmentioning

confidence: 99%

Sap flow and sugar transport in plants

et al. 2016

View full text Add to dashboard Cite

show abstract

“…MR imaging (MRI) systems rely on the quantitative measure of the presence and the movement of water in plants, for which organs compete, in particular during fruit development. One of the major constraints for the measurement of sap-flow (the fluid transported in xylem cells), is the extreme sensitivity to invasive experimentation [121]. MRI and NMR are able to overcome this gap, since they record the displacement of water inside the plant through imaging analysis.…”

Section: Magnetic Resonance Studiesmentioning

confidence: 99%

Sensing Technologies for Precision Phenotyping in Vegetable Crops: Current Status and Future Challenges

Tripodi¹,

Massa²,

Venezia³

et al. 2018

Agronomy

View full text Add to dashboard Cite

Abstract:Increasing the ability to investigate plant functions and structure through non-invasive methods with high accuracy has become a major target in plant breeding and precision agriculture. Emerging approaches in plant phenotyping play a key role in unraveling quantitative traits responsible for growth, production, quality, and resistance to various stresses. Beyond fully automatic phenotyping systems, several promising technologies can help accurately characterize a wide range of plant traits at affordable costs and with high-throughput. In this review, we revisit the principles of proximal and remote sensing, describing the application of non-invasive devices for precision phenotyping applied to the protected horticulture. Potentiality and constraints of big data management and integration with "omics" disciplines will also be discussed.

show abstract

“…The increase in free Ca 2+ caused due to mechanical damage occurs in all irrespective of the plant species and family. 26,27 Despite the wealth of experimental data, very little is known about P-proteins at the molecular level. The first structural P-protein to be characterized was phloem protein 1 (PP1) from squash (Cucurbita maxima).…”

Section: 12mentioning

confidence: 99%

“…46,47 On the basis of dynamic structural changes which are unique to the crystalline P-proteins of legumes distinguishes them from the non-dispersive phloem-specific protein bodies of other families (such as Urticaceae and Rosaceae). 48 Classically the phloem protein bodies have been classified namely into 2 broad categories. 9 They are referred to as "nondispersive" and "dispersive" protein bodies.…”

mentioning

confidence: 99%