Acclimatization of Sweet Potatoes Under in vitro Application of Diatomaceous Earth.

Diatomaceous earth is an organic naturally occurring material rich in silicon. This silicon source can be used in organic agriculture, it also has a great potential of use in the acclimatization of crops. However, there are no reports of the effects of diatomaceous earth supplementation on the micropropagation of sweet potato. Thus, the objective of this study was to evaluate the effects of different concentrations of diatomaceous earth applied in vitro on the growth, physiology and anatomy of sweet potato cv. 'Brazlândia Branca' after acclimatization. Four concentrations of diatomaceous earth. After 30 days of in vitro growth, the plants were transferred to a greenhouse for acclimatization. After 45 days, leaf number, shoot and root length, fresh and dry shoot and root mass, gas exchange, chlorophyll content, root and leaf anatomy. The experimental design was completely randomized. The supplementation of diatomaceous earth in the in vitro cultivation had beneficial effects, increasing the accumulation of mass, improving the photosynthetic apparatus and promoting favorable anatomical characteristics during the acclimatization of the sweet potato plants. In addition, the use of diatomaceous earth achieved adequate seedling development, with higher seedling quality and resistance to biotic and abiotic effects than attained with control treatment.

Polyploidy induction in Physalis alkekengi / Indução de poliploidia em Physalis alkekengi

Physalis alkekengi is an ornamental plant that can also be used as a medicinal plant due to its anti-inflammatory, bactericidal, antitumor and fungicidal properties. Polyploidization can be an important tool in the genetic improvement of this species. The objective this work was to obtain tetraploids in vitro and to evaluate the phytotechnical traits of P. alkekengi. For this, nodal segments of P. alkekengi var. Franchettii were inoculated into petri dishes containing 100 ml of MS medium supplemented with colchicine at concentrations 0; 0.04; 0.08; 0.12; and 0.16% and kept in the dark for 24 and 48h. After the respective treatment periods with colchicine the segments were inoculated into test tubes. The tetraploids were identified by flow cytometry and classical cytogenetics. In vitro seedlings were measured: root length, nodal segment length, leaflet number and total leaf area. In the acclimatization phase, the area of the second leaf and total leaf, petiole radius, stem length, fruit weight with calyx, without calyx, fruit diameter, number of seeds and brix of the pulp were evaluated. Chlorophyll a, chlorophyll b, total chlorophyll, total carotenoid, total chlorophyll / total carotenoid ratio and chlorophyll a / b ratio were also estimated. The treatment that most produced tetraploid seedlings was with 0.08% colchicine per 24h. No significant difference was observed in 7 (seven) variables, these being all variables of photopigments, stem diameter (steam) and brix. In general, diploid (2x) plants were better in 9 (nine) while tetraploid seedlings were better in 6 (six) of the phytotechnical variables. It was concluded that the MS medium supplemented with 0.08% colchicine for 24 h allowed P. alkekengi tetraploides to be obtained with better phytotechnical qualities.

Physalis alkekengi é uma planta ornamental que também pode ser usada como planta medicinal devido às suas propriedades anti-inflamatórias, bactericidas, antitumorais e fungicidas. A poliploidização pode ser uma ferramenta importante para o melhoramento genético dessa espécie. O objetivo deste trabalho foi obter tetraplóides in vitro e avaliar as características fitotécnicas de P. alkekengi. Para isso, segmentos nodais de P. alkekengi var. Franchettii foram inoculados em placas de Petri contendo 100 ml de meio MS suplementado com colchicina nas concentrações 0; 0,04; 0,08; 0,12; e 0,16% e mantido no escuro por 24 e 48h. Após os respectivos períodos de tratamento com colchicina, os segmentos foram inoculados em tubos de ensaio. Os tetraplóides foram identificados por citometria de fluxo e citogenética clássica. As plântulas in vitro foram medidas: comprimento da raiz, comprimento do segmento nodal, número de folhetos e área foliar total. Na fase de aclimatação foram avaliadas a área da segunda folha e área foliar total, raio do pecíolo, comprimento do caule, peso do fruto com cálice, sem cálice, diâmetro do fruto, número de sementes e brix da polpa. Também foram estimadas clorofila a, clorofila b, clorofila total, carotenóides totais, razão clorofila total / carotenóide total e razão clorofila a / b. O tratamento que mais produziu mudas tetraplóides foi com colchicina a 0,08% por 24 horas. Não foi observada diferença significativa em 7 (sete) variáveis, sendo todas variáveis de fotopigmentos, diâmetro do caule (vapor) e brix. Em geral, as plantas diplóides (2x) foram melhores em 9 (nove) variáveis fitotécnicas, enquanto as mudas tetraplóides foram melhores em 6 (seis). Concluiu-se que o meio MS suplementado com colchicina a 0,08% por 24 h permitiu obter tetraploides de P. alkekengi com melhores qualidades fitotécnicas.

Anatomical modifications of Butia capitata propagated under colored shade nets.

The jelly palm plant [Butia capitata (Martius) Beccari] is a native palm of the Cerrado biome used for many purposes in northern Minas Gerais State, Brazil. Dormancy is common in palm seeds, resulting in slow and uneven germination that may take years to complete. Modification in the growth pattern, anatomical parameters, physiological and biochemical characteristics of the plant can be verified due to changes in the light spectrum transmitted through colored shade nets used. Therefore, the objective of this study is to evaluate the effect of colored shade nets on the leaf and root anatomy of the jelly palm plant. The experiment was performed in a completely randomized design, with five treatments, ten replicates and eight plants per replicate, totaling 400 plants. Four colored photo-converter nets with 50% shading and different radiation proportions were employed: white (985 µmol.m-2.s-1), red (327 µmol.m-2.s-1), black (433 µmol.m-2.s-1) and silver (405 µmol.m-2.s-1). The plants cultivated under direct sunlight (1000 µmol.m-2.s-1) were considered as the control group. Leaf and root anatomical analysis was performed on 10 plants per treatment. It is possible to conclude that the colored shade nets caused changes in leaf and root anatomy of the jelly palm plant (Butia capitata).