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Stevia is an important non-caloric sweetener that has health-beneficial properties. The objective is to evaluate growth, development, and rooting of stevia plants during different seasons of the year using growth hormones. Eight experiments were set up in Ciudad Guzman, Jalisco, Mexico, with three treatments (T): T1, indol-3 butyric acid (IBA) 7.4 mM; T2, alphanaphthylacetamide (ANA) 6.4 mM + IBA 0.3 mM; and T3, control. The variables evaluated were rooted plantlets, plant height, root length, number of leaves, stem diameter, leaf dry weight, stem dry weight, root dry weight, leaf area, shoot biomass, total biomass, as well as development and growth indexes. Four samplings were conducted in each experiment. The results show that the most appropriate months for propagating stevia cuttings are February, March, April, May, and July, when 96% to 99% of the cuttings rooted. The hormones had the best results related to production of root development. The control was outstanding only in variables related to production of shoot biomass and not to root development. It is concluded that stevia can be propagated vegetatively using cuttings treated with IBA 7.4 mM or ANA 6.4 mM + IBA 0.3 mM, preferable in the period from February to July, with the exception of June.
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Species of the genus Agave are distributed originally in the tropical and subtropical areas of the American continent with about 200 taxa and 136 species, and its center of origin is probably limited to México. These kind of plants usually grow and live in extreme environmental conditions such as heat and drought where their CAM pathway for fixing CO2 allow them to survive in conditions where other plants cannot survive. Although this kind of plants resist harsh environmental conditions, climate change is imposing stronger kinds of stress that diminish their productive potential and in some cases are cause of death. Because of this, genetic improvement becomes a need of fundamental importance in this kind of species. Despite their economic importance, Agave species have received scarce attention with regard to its genetic improvement, probably due to their unique botanical features such as plant architecture, spines, long life span, and monocarpy, among others, which make hybridization a difficult task for the intra- and interspecific gene transfer and creation of genetic variability among many other breeding techniques.The protocol here presented is a combination of a novel hybridization technique and biotechnological tools, and allows the use of several procedures for the genetic improvement of agaves such as pollen selection, clonal selection, and somatic cell selection, among others, since the rescued embryos can be used for micropropagation, for phenotype/genotype selection or the production of cell lineages for diverse genetic improvement purposes.
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Agave/embriología , Fitomejoramiento/métodos , Técnicas de Embriogénesis Somática de Plantas/métodos , Polinización/fisiología , Hibridación Genética , Polen/fisiología , Preservación BiológicaRESUMEN
Freeze-drying technology is the best dehydration process to preserve shelf-life and allowing avocado to maintain its sensorial and nutritional characteristics. The aim of this work was to determine if the freeze-drying and production condition have an effect on the nutritional quality of the avocado pulp grown in rain-fed and irrigation orchards. Four treatments were applied: non-freeze-dried rain-fed fruits, non-freeze-dried irrigation fruits, freeze-dried rain-fed fruits and freeze-dried irrigation fruits. Results showed that the fruit is made up of 71.4%, 16%, and 12.6% pulp, seed and skin, respectively. The pulp is made up of 71.51%, 19.96%, 2.81%, 0.51% and 1.51% water, lipids, ashes, crude fiber and protein, respectively. Avocado oil is composed by 61%, 18.8%, 11.6% and 7% oleic, palmitic, linoleic, and palmitoleic fatty acids, respectively. The freeze-drying decreased the linoleic acid by 1.43 g/100g. Under rain-fed conditions 4% and 13% less total fat and oleic fatty acid are produced than in irrigation conditions. We conclude that freeze-dried avocado pulp shows slight changes in their nutritional quality.
La tecnología de liofilización es el mejor proceso de deshidratación para mantener mayor vida de anaquel y conservar las propiedades nutricionales y sensoriales de la pulpa del aguacate. El objetivo de este estudio fue determinar si el liofilizado y condición de producción tienen un efecto sobre la calidad nutrimental de la pulpa de aguacate cultivado en huertas de riego y temporal. Se aplicaron 4 tratamientos: frutos de temporal no liofilizado, frutos de riego no liofilizado, frutos liofilizados de temporal y frutos liofilizados de riego. Los resultados muestran que el fruto está compuesto por 71.39, 16 y 12.6% de pulpa, hueso y cascara respectivamente. La pulpa está compuesta por 71.51, 19.96, 2.81, 0.51 y 1.5 % de humedad, lípidos, cenizas, fibra cruda y proteína, respectivamente. El aceite del aguacate está constituido de 61. 18.8, 11.6 y 7% de ácidos grasos oleico, palmítico, linoléico y palmitoleico, respectivamente. El liofilizado disminuyó 1.43 g/100 g de ácido linoléico. Bajo condiciones de temporal se produce 4 y 13% menos grasa total y ácido graso oleico que en condiciones de riego. Se concluye que la pulpa del aguacate liofilizada presenta ligeros cambios en su calidad nutrimental.
Asunto(s)
Calidad de los Alimentos , Persea/química , Composición de Alimentos , Ácidos Grasos , Liofilización , Riego AgrícolaRESUMEN
Se evaluaron 63 cultivares de mandarina (Citrus spp.) provenientes de la colección del Campo Citrícola Experimental Francisco Villa, Tamaulipas, México, usando marcadores morfológicos y AFLP (Amplified Fragment Length Polymorphism). Se usaron 20 caracteres cuantitativos y 10 cualitativos de hojas, flores y frutos. Las mejores combinaciones de iniciadores AFLP fueron la Mse +CAG más Eco +ACA, y Mse +CAA más Eco +AGG, dando un total de 109 bandas con un 86 por ciento de polimorfismo. Tanto los marcadores morfológicos como los moleculares mostraron un alto grado de variación entre los individuos analizados, lo que indica una importante fuente de diversidad genética que puede ser utilizada en futuros programas de mejoramiento genético. Aunque la comparación de los datos morfológicos y moleculares usando la prueba de Mantel no mostró una correlación significativa (r= 0.31), ambas técnicas parecen ser complementarias para la caracterización de mandarinas