Self‐case report of oral and skin lesions associated with positivity of COVID‐19

Maksymowych, Roman. (Villanova U., Villanova, Pa.) Quantitative analysis of leaf development in Xanthium pensylvanicum. Amer. Jour. Bot. 46(9): 635–644. Illus. 1959.—An attempt was made to find a quantitative way of describing the development of the leaf and to correlate the developmental processes, designating precisely their sequence. The processes were presented in terms of the absolute and relative rates of leaf length, expansion of lamina in surface, increase in thickness, rates of cell division of leaf 9 and 13, and tissue differentiation of 3 portions of the lamina. All rates were estimated over the entire period of development, from initiation of a primordium to its maturity. The leaf plastochron index (L.P.I.) was used as a morphological time‐scale. The relative plastochron rates were used for the purpose of correlation of the developmental processes. Leaf 9 elongates exponentially up to 3.0 L.P.I. with an average relative rate (dlnL/dpl) of about 0.78 pl‐1, and it stops growing around 8.0 L.P.I. The lamina stops elongating about 1.5 plastochrons before the petiole. The tip of the lamina expands its surface at a constantly lower relative rate than the middle and the basal portions of the blade. The average relative rate of expansion in area (dlnA/dpl) for the whole lamina is 1.7pl‐1 during the exponential stage. Differentiation of the laminar tissues proceeds basipetally, from the tip toward the base of the leaf. The relative rate of expansion of lamina in thickness (dlnT/dpl) is 0.55 pl‐1 at 1.5 L.P.I. and after 4.0 L.P.I. all cells cease elongating in a plane perpendicular to the leaf surface. The formation of cells proceeds exponentially up to 3.0 L.P.I. and about this time cell divisions stop in all parts of the lamina. The mean relative rate of cell formation (dlnC/dpl) at the exponential phase is 1.41 pl‐1, an increase of about 31% per day. At least 27 generations of cells are involved in the process of leaf formation and the generation time was calculated to be 0.5 plastochron or 2.2 days.

show abstract

Phyllotactic Change Induced by Gibberellic Acid in Xanthium Shoot Apices

Maksymowych

Erickson

1977

American J of Botany

View full text Add to dashboard Cite

Gibberellic acid (GA) treatment of vegetative shoots of Xanthium leads to a change in phyllotaxis as diagnosed in transverse sections of apical buds. A method of analysis is proposed for estimating the phyllotactic parameters, the plastochron ratio, a, and the divergence angle, α, from measurements of the angular and radial positions of leaf primordia in sections. GA treatment significantly decreases the plastochron ratio, a, from 1.35 in controls, to 1.19 in GA‐treated plants, as shown by an analysis of variance, but has no significant effect on the divergence angle. The estimates of a and α are compared with the parameters of theoretical phyllotaxis models, leading to the designation (2, 3) for controls, and (3, 5) for GA‐treated plants, where the integers 2, 3, and 5 designate sets of contact parastichies. The change in a is interpreted as indicating a change in the relative position at which leaf primordia are initiated in the apical meristem, and this effect is discussed in relation to theories of leaf initiation.

show abstract

Long‐term Developmental Changes in Xanthium Induced by Gibberellic Acid

Maksymowych

Cordero

Erickson

1976

American J of Botany

View full text Add to dashboard Cite

One application of gibberellic acid (GA3) to Xanthium shoots resulted in an initial large stimulation, followed by inhibition, of internode elongation. After presumed translocation of the hormone from the locus of its application to the stem apex several morphological changes were observed. There was a significant increase in number of mitotic figures in the apical meristem and a twofold increase in volume of the apical dome. With time, the rate of leaf production was accelerated about 1.8 times. The phyllotaxis of leaf primordia initiated under the influence of GA:, changed from a (2, 3) contact parastichy pattern in control shoot to a (3, 5) pattern. Final petiole length was smaller than the control, and the absolute rate of lamina expansion decreased under prolonged treatment. Gibberellic acid had a pronounced effect on leaf morphology. GAa induced the development of lanceolate leaves instead of typical deltoid leaves. The reduction in leaf area coincided with a 32% reduction in the average area of epidermal cells. Plastochron changes were correlated with anatomical and morphological changes during the course of leaf development.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Roman Maksymowych

Phyllotactic Change Induced by Gibberellic Acid in Xanthium Shoot Apices

Quantitative Analysis of Leaf Development in Xanthium Pensylvanicum

Phyllotactic Change Induced by Gibberellic Acid in Xanthium Shoot Apices

Long‐term Developmental Changes in Xanthium Induced by Gibberellic Acid

Contact Info

Product

Resources

About