Morphology, Development, and Recrystallization of Epicuticular Waxes of Johnsongrass (Sorghum halepense)

Weed Science ◽  
1990 ◽  
Vol 38 (1) ◽  
pp. 22-33 ◽  
Author(s):  
Chester G. McWhorter ◽  
Rex N. Paul ◽  
William L. Barrentine
Keyword(s):  
Physical Properties ◽  
Epicuticular Wax ◽  
Sorghum Halepense ◽  
Epicuticular Waxes ◽  
Tubular Structures ◽  
Cuticular Membrane ◽  
Crystalline Structures ◽  
Capillary Method ◽  
Leaf Surfaces ◽  
Morphology Development

Johnsongrass leaves were covered with epicuticular wax that varied from 16 to 25 μg/cm2on leaf blades and 56 to 206 μg/cm2on leaf sheaths. At emergence, leaves were covered with a layer of smooth amorphous wax, but crystalline wax (wax plates) began to form on the amorphous wax within 1 or 2 days. This continued until all leaf surfaces were covered with wax plates. At 3 to 4 weeks of age, a smooth layer of coalescence wax was deposited over the wax plates. Formation of coalescence wax continued until nearly all leaf surfaces were covered with a smooth wax layer. Production of wax filaments began when plants were 3 to 4 weeks old and these tubular structures extended 100 to 200 μm above all other wax formations. Deposition of amorphous wax continued after stomata closed in the darkness, sealing over stomata, but the wax layer was broken when stomata opened again in the light. A capillary method was devised that was used to evaporate chloroform containing leaf waxes through 0.1- to 1.2-μm pores in inert filters to recrystallize amorphous wax and wax plates similar to that produced on johnsongrass leaves. Recrystallization of wax from wax filaments dissolved in chloroform produced the same structures of amorphous wax and wax plates as when only wax from leaves with amorphous wax and wax plates was used. Wax washed from leaves also produced wax plates and a variety of crystalline structures on the walls of glass vials after chloroform solutions were evaporated. This result indicated that the morphology of epicuticular waxes is influenced more by their inherent chemical and physical properties than by underlying cells or the cuticular membrane.

scholarly journals Leaf Cuticular Transpiration Barrier Organization in Tea Tree Under Normal Growth Conditions

2021 ◽  
Vol 12 ◽  
Author(s):  
Mingjie Chen ◽  
Yi Zhang ◽  
Xiangrui Kong ◽  
Zhenghua Du ◽  
Huiwen Zhou ◽  
...  
Keyword(s):  
Correlation Analysis ◽  
Complex Structure ◽  
Epicuticular Wax ◽  
Dominant Factor ◽  
Epicuticular Waxes ◽  
Cuticular Transpiration ◽  
Functional Relationships ◽  
Leaf Surfaces ◽  
Cuticle Thickness ◽  
Water Transpiration

The cuticle plays a major role in restricting nonstomatal water transpiration in plants. There is therefore a long-standing interest to understand the structure and function of the plant cuticle. Although many efforts have been devoted, it remains controversial to what degree the various cuticular parameters contribute to the water transpiration barrier. In this study, eight tea germplasms were grown under normal conditions; cuticle thickness, wax coverage, and compositions were analyzed from the epicuticular waxes and the intracuticular waxes of both leaf surfaces. The cuticular transpiration rates were measured from the individual leaf surface as well as the intracuticular wax layer. Epicuticular wax resistances were also calculated from both leaf surfaces. The correlation analysis between the cuticular transpiration rates (or resistances) and various cuticle parameters was conducted. We found that the abaxial cuticular transpiration rates accounted for 64–78% of total cuticular transpiration and were the dominant factor in the variations for the total cuticular transpiration. On the adaxial surface, the major cuticular transpiration barrier was located on the intracuticular waxes; however, on the abaxial surface, the major cuticular transpiration barrier was located on the epicuticular waxes. Cuticle thickness was not a factor affecting cuticular transpiration. However, the abaxial epicuticular wax coverage was found to be significantly and positively correlated with the abaxial epicuticular resistance. Correlation analysis suggested that the very-long-chain aliphatic compounds and glycol esters play major roles in the cuticular transpiration barrier in tea trees grown under normal conditions. Our results provided novel insights about the complex structure–functional relationships in the tea cuticle.

Epicuticular Wax on Johnsongrass (Sorghum halepense) Leaves

Weed Science ◽  
1993 ◽  
Vol 41 (3) ◽  
pp. 475-482 ◽  
Author(s):  
Chester G. Mcwhorter
Keyword(s):  
Drought Stress ◽  
Relative Humidity ◽  
Leaf Blade ◽  
Unit Area ◽  
Grain Sorghum ◽  
Epicuticular Wax ◽  
Sorghum Halepense ◽  
Wax Deposition ◽  
Narrow Side ◽  
Leaf Surfaces

Studies were conducted to investigate the uniformity of epicuticular wax deposition on leaf blades of johnsongrass. Johnsongrass leaves grown under drought stress had greatly increased epicuticular wax weights compared to leaves from plants with adequate moisture, but relative humidity (95% vs. 40 ± 5%) had little effect on wax deposition. Wax weights decreased as leaves matured. Sections of lower leaf surfaces of young johnsongrass leaves tended to have more wax than sections of upper leaf surfaces, but weights were nearly equal on upper vs. lower leaf surfaces of older leaves. The narrow side of asymmetrical johnsongrass leaf blades often had more wax per unit area than the wide side. The area over the midvein contained more wax per unit area than either the narrow or wide side of the leaf blade. Greatest wax concentrations on individual leaves were over the midvein area near the leaf apex. Leaf blades of johnsongrass had more wax per unit area than leaves of corn or grain sorghum.

Surfactant-Induced Phytotoxicity

1994 ◽  
Vol 8 (3) ◽  
pp. 519-525 ◽  
Author(s):  
Richard H. Falk ◽  
Richard Guggenheim ◽  
Gerhard Schulke
Keyword(s):  
Electron Microscopy ◽  
Scanning Electron Microscopy ◽  
Tissue Damage ◽  
Epicuticular Wax ◽  
Morphological Alteration ◽  
Epicuticular Waxes ◽  
Common Purslane ◽  
Morphology Changes ◽  
Cryo Scanning Electron Microscopy ◽  
Scanning Electron

The leaves of tall morningglory, giant duckweed, and common purslane were treated with nine surfactants at a concentration of 0.1% and examined after 24 hr using cryo-scanning electron microscopy for phytotoxicity as evidenced by tissue damage and epicuticular wax morphology changes. In some instances, tissue damage could be discerned; however, the effects of a particular surfactant were not uniform across the three species. Morphological alteration of epicuticular waxes was not observed. Gas chromatographic analyses of the epicuticular waxes of the species used in the study reveal component differences and may, in part, explain the lack of uniform response across species for a particular surfactant.

Anatomy of Johnsongrass

Weed Science ◽  
1971 ◽  
Vol 19 (4) ◽  
pp. 385-393 ◽  
Author(s):  
C. G. McWhorter
Keyword(s):  
Sorghum Halepense ◽  
Vascular Bundles ◽  
Leaf Surfaces

The number of vascular bundles in the rhizomes of different ecotypes of johnsongrass (Sorghum halepense(L.) Pers.) varied from 71 to 154. The size of vascular bundles varied from 60 to 150 μ in an ecotype from California to 100 to 230 μ in an ecotype from Georgia. The size of xylem cells in these vascular bundles also varied widely, but the size of phloem cells was more constant. The number of vascular bundles in culms ranged from 43 to 123. The average number of vascular bundles in individual leaves varied from 46 to 158 for different ecotypes. The number of stomata on leaf surfaces deviated from 63 to 148/sq mm for 10 different ecotypes. An average of 95 stomata/sq mm occurred on the upper surface of johnsongrass leaves while an average of 113 stomata occurred on lower surfaces. The arrangement and size of stomata varied in different johnsongrass ecotypes.

scholarly journals A novel maize gene, glossy6 involved in epicuticular wax deposition and drought tolerance

2018 ◽  
Author(s):  
LI Li ◽  
Yicong Du ◽  
Cheng He ◽  
Charles R. Dietrich ◽  
Jiankun Li ◽  
...  
Keyword(s):  
Drought Tolerance ◽  
Intracellular Trafficking ◽  
Epicuticular Wax ◽  
Epicuticular Waxes ◽  
Wild Type ◽  
Terrestrial Plants ◽  
Surface Waxes ◽  
Extracellular Transport ◽  
Plant Surfaces ◽  
Wax Load

SUMMARYEpicuticular waxes, long-chain hydrocarbon compounds, form the outermost layer of plant surfaces in most terrestrial plants. The presence of epicuticular waxes protects plants from water loss and other environmental stresses. Cloning and characterization of genes involved in the regulation, biosynthesis, and extracellular transport of epicuticular waxes on to the surface of epidermal cells have revealed the molecular basis of epicuticular wax accumulation. However, intracellular trafficking of synthesized waxes to the plasma membrane for cellular secretion is poorly understood. Here, we characterized a maize glossy (gl6) mutant that exhibited decreased epicuticular wax load, increased cuticle permeability, and reduced seedling drought tolerance relative to wild type. We combined an RNA-sequencing based mapping approach (BSR-Seq) and chromosome walking to identify the gl6 candidate gene, which was confirmed via the analysis of multiple independent mutant alleles. The gl6 gene represents a novel maize glossy gene containing a conserved, but uncharacterized domain. Functional characterization suggests that the GL6 protein may be involved in the intracellular trafficking of epicuticular waxes, opening a door to elucidating the poorly understood process by which epicuticular wax is transported from its site of biosynthesis to the plasma membrane.SIGNIFICANCE STATEMENTPlant surface waxes provide an essential protective barrier for terrestrial plants. Understanding the composition and physiological functions of surface waxes, as well as the molecular basis underlying wax accumulation on plant surfaces provides opportunities for the genetic optimization of this protective layer. Genetic studies have identified genes involved in wax biosynthesis, extracellular transport, as well as spatial and temporal regulation of wax accumulation. In this study, a maize mutant, gl6 was characterized that exhibited reduced wax load on plant surfaces, increased water losses, and reduced seedling drought tolerance compared to wild type controls. The gl6 gene is a novel gene harboring a conserved domain with an unknown function. Quantification and microscopic observation of wax accumulation as well as subcellular localization of the GL6 protein provided evidence that gl6 may be involved in the intracellular trafficking of waxes, opening a door for studying this necessary yet poorly understood process for wax loading on plant surfaces.

scholarly journals Relationships between Postharvest Water Loss and Physical Properties of Pepper Fruit (Capsicum annuum L.)

HortScience ◽  
1993 ◽  
Vol 28 (12) ◽  
pp. 1182-1184 ◽  
Author(s):  
N.K. Lownds ◽  
M. Banaras ◽  
P.W. Bosland
Keyword(s):  
Physical Properties ◽  
Water Content ◽  
Surface Area ◽  
Water Loss ◽  
Loss Rate ◽  
Epicuticular Wax ◽  
Initial Water Content ◽  
Initial Water ◽  
Water Loss Rate ◽  
Wax Content

Physical characteristics [initial water content, surface area, surface area: volume (SA: V) ratio, cuticle weight, epicuticular wax content, and surface morphology] were examined to determine relationships between physical properties and water-loss `rate in pepper fruits. `Keystone', `NuMex R Naky', and `Santa Fe Grande' peppers, differing in physical characteristics, were stored at 8, 14, or 20C. Water-loss rate increased linearly with storage time at each temperature and was different for each cultivar. Water-loss rate was positively correlated with initial water content at 14 and 20C, SA: V ratio at all temperatures, and cuticle thickness at 14 and 20C. Water-loss rate was negatively correlated with surface area and epicuticular wax content at all temperatures. Stomata were absent on the fruit surface, and epicuticular wax was amorphous for each cultivar.

Epicuticular wax forms on leaf surfaces of Zizania aquatica

1970 ◽  
Vol 48 (2) ◽  
pp. 201-205 ◽  
Author(s):  
W. R. Hawthorn ◽  
J. M. Stewart
Keyword(s):  
Continuous Light ◽  
Epicuticular Wax ◽  
Experimental Conditions ◽  
Zizania Aquatica ◽  
Leaf Surfaces ◽  
Young Leaves ◽  
Floating Leaves ◽  
Wax Production ◽  
The Relationship ◽  
Floating Leaf

The epicuticular wax forms on the leaves of the three varieties of Zizania aquatica L. were determined from control plants in the field and greenhouse, and served as a reference for interpreting changes in the wax forms of plants grown under different experimental conditions. Short stubby wax rodlets first appeared 15 cm below the water's surface on the portion of the adaxial surface of young leaves which eventually became floating (leaf numbers 4 to 6). Wax rodlets and platelets were present on both surfaces of the aerial leaves (leaf numbers 7 to 12). The relationship between wax appearance and leaf numbers could be varied by manipulating the water level; for as long as water surrounded the permanently submersed leaves or the submerged portions of the floating leaves, wax production was inhibited. Growth under continuous light and constant temperature conditions indicated that factors other than the day–night cycle were responsible for wax ultrastructure.

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