Impact of cefotaxime on somatic embryogenesis and shoot regeneration in sugarcane

Totipotency of Daucus carota L. Somatic Cells Microencapsulated Using Spray Drying Technology

The carrot is considered a model system in plant cell culture. Spray drying represents a widely used technology to preserve microorganisms, such as bacteria and yeasts. In germplasm conservation, the most used methods are freeze drying and cryopreservation. Therefore, the aim of this work was to evaluate the effect of spray drying on the viability and totipotency of somatic carrot cells. Leaf, root and stem explants were evaluated to induce callus with 2 mg/L of 2,4-dichlorophenoxyacetic acid (2,4-D). Calli obtained from the stem were cultivated in a liquid medium with 1 mg/L of 2,4-D. Cell suspensions were spray dried with maltodextrin-gum Arabic and maltodextrin-xanthan gum mixtures, two outlet air temperatures (50 and 60 °C) and 120 °C inlet air temperature. Results showed that carrot cells were viable after spray drying, and this viability remained for six months at 8 °C. The totipotency of the microencapsulated cells was proven. Cells that were not spray dried regenerated 24.6 plantlets, while the spray dried cells regenerated 19 plantlets for each gram of rehydrated powder. Thus, spray drying allowed researchers to obtain viable and totipotent cells. This work is the first manuscript that reported the spray drying of plant somatic cells.

Optimized somatic embryogenesis and plant regeneration in elite Argentinian sugarcane (Saccharum spp.) cultivars

Background

Biotechnological breeding of elite sugarcane cultivars is currently limited because of the difficulty of regenerating plants by tissue culture. Here, we report that commercially elite sugarcane genotypes, which are adapted to Argentinian agro-ecological conditions, are capable of being regenerated via indirect somatic embryogenesis. Leaf rolls of five elite genotypes were cultured following two callus induction protocols using different concentrations of 2,4-D as the growth regulator. Embryogenic calluses were regenerated under light conditions. Regenerated plants were subsequently acclimatized in the greenhouse under two acclimatization procedures before being transplanted to the field.

Results

Four of the five genotypes were able to form somatic embryos following the two induction protocols. The variables related to embryogenic callus production were influenced by the interaction between genotype and culture conditions. For plant regeneration, the embryogenic calluses were further cultured on an IBA-supplemented medium, where we observed a high genotype dependence. Calluses from the four cultivars regenerated a good number of plants. With the procedures described here, we obtained more than 90% of well-acclimatized plants both in the greenhouse and in the field.

Conclusions

This protocol provides a simple way to regenerate sugarcane plants through indirect somatic embryogenesis. Also, the results confirm that tissue culture ability is highly genotype-dependent in sugarcane. Our findings suggest that these elite cultivars could be good candidates for biotechnological breeding.

Cellular, Molecular, and Physiological Aspects of In Vitro Plant Regeneration

Plants generally have the highest regenerative ability because they show a high degree of developmental plasticity. Although the basic principles of plant regeneration date back many years, understanding the cellular, molecular, and physiological mechanisms based on these principles is currently in progress. In addition to the significant effects of some factors such as medium components, phytohormones, explant type, and light on the regeneration ability of an explant, recent reports evidence the involvement of molecular signals in organogenesis and embryogenesis responses to explant wounding, induced plant cell death, and phytohormones interaction. However, some cellular behaviors such as the occurrence of somaclonal variations and abnormalities during the in vitro plant regeneration process may be associated with adverse effects on the efficacy of plant regeneration. A review of past studies suggests that, in some cases, regeneration in plants involves the reprogramming of distinct somatic cells, while in others, it is induced by the activation of relatively undifferentiated cells in somatic tissues. However, this review covers the most important factors involved in the process of plant regeneration and discusses the mechanisms by which plants monitor this process.

Efecto de Dicamba y de ácido 2,4 diclorofenoxiacético sobre la embriogénesis somática en caña de azúcar

<p><strong>Título en ingles</strong>: Efecto de Dicamba y de ácido 2,4 diclorofenoxiacético sobre la embriogénesis somática en caña de azúcar</p><p>El cultivo <em>in vitro</em> de la caña de azúcar ha sido establecido en muchas variedades comerciales con el propósito de producir material libre de enfermedades microbianas, conservar germoplasma, detectar resistencia a enfermedades y plagas, etc. En este sentido, el objetivo de este trabajo fue analizar la efectividad de las auxinas sintéticas ácido 2,4-diclorofenoxiacético (2,4D) y ácido 3,6-dicloro-2-metoxibenzoico (Dicamba), en la inducción del proceso de embriogénesis somática y la regeneración de vitroplántulas de distintas variedades de caña de azúcar (C26670, RB855546, V99245, V756, V781, V0050, CC8592, CC8475). Para esto se cultivaron discos de hojas en fase de macollamiento, de 1 cm de diámetro y 2 mm de grosor, en medio Murashige-Skoog, 1962 (MS) suplementado con 50 ml.l-1 agua de coco, 30 g.l-1 sacarosa y dos tratamientos diferentes: 3 mg.l-1 2,4-D ó 6.63 mg.l-1 Dicamba, ambos en completa oscuridad a 25ºC, durante 1 mes. Los callos obtenidos se colocaron en medio de regeneración, conteniendo ½ sales MS, 200 ml.l-1 agua de coco y 60 g.L-1 sacarosa, incubándose bajo luz continua, 25ºC, por 2 meses. El mayor porcentaje de callo embriogénico se obtuvo en medios suplementados con Dicamba un promedio de 70,83 % de callo embriogénico por variedad ; mientras que en los medios con 2,4D se obtuvo 62,08 % de callo embriogénico por variedad. Se obtuvo un promedio de 89,00 % de plantas regeneradas a partir de los callos obtenidos en medios con Dicamba y 66,12 % de plantas a partir de callos obtenidos en medios con 2,4D. Con el uso de Dicamba se estableció un sistema eficiente de embriogénesis somática para estas variedades de caña de azúcar.</p>

Effect of β-lactam antibiotics on plant regeneration in carrot protoplast cultures

Protoplasts of three carrot cultivars were isolated from in vitro-grown plantlets by overnight incubation in an enzyme mixture composed of 1% (w/v) cellulase Onozuka R-10 and 0.1% (w/v) pectolyase Y-23. After cell immobilization in modified thin alginate layers, three types of β-lactam antibiotics (cefotaxime, carbenicillin, or timentin) at five different concentrations (100, 200, 300, 400, or 500 mg L^-1) were added to the culture medium. In 20-d-old cultures, a different number of cell colonies had formed and varied on average from 27 to 56% in carbenicillin- and cefotaxime-containing media, respectively. Supplementation of the culture media with antibiotics at concentrations higher than 100 mg L^-1 resulted in a decrease in plating efficiency in comparison with the controls. However, from all antibiotic treatments, except carbenicillin at concentrations of 400-500 mg L^-1, efficient plant regeneration occurred. For this reason, we believe that cefotaxime and timentin in the concentrations analyzed here may be used in complex in vitro procedures or valuable carrot cultures as a prophylactic agent for prevention against occasional contaminations.

Cefotaxime prevents microbial contamination and improves microspore embryogenesis in wheat and triticale

Cefotaxime (100 mg/l) mitigate occasional gram negative bacterial contamination in wheat and triticale microspore culture and most importantly it increases cell growth and green plant production. Isolated microspore culture is a promising option to rapidly fix the product of meiotic recombination of F1 hybrids, in the process of varietal development. Clean culture and high embryogenesis rate are essential to commercial triticale and wheat microspore cultures. So, this study investigated (1) contaminants from isolated microspores cultures, (2) two antibiotics to control bacterial growth, and (3) the contribution of antibiotics to increased microspore-derived embryo-like structures (ELS), green and albino plants. Five species of bacteria were identified in contaminated cultures (Erwinia aphidicola, Pantoea agglomerans, Pseudomonas sp., Staphylococcus epidermis and Staphylococcus warneri) using fatty acid analysis and 16S ribosomal RNA sequences analysis, and yeast. Antibacterial susceptibility test using Cefotaxime and Vancomycin resulted in strong inhibition of 24 bacterial isolates, using Cefotaxime at 100 mg/l, but not Pseudomonas sp. Other antibiotic treatments inhibited bacterial growth at least partially. Microspore induction medium supplemented with the same antibiotics treatments resulted in successful microspore embryogenesis and green plant production. Antibiotic treatments were first tested in triticale and then validated in wheat cultivars AC Carberry and AC Andrew. Induction medium supplemented with Cefotaxime at 50 and 100 mg/l substantially increased the formation of ELS and green plants in triticale and wheat, respectively. Incidentally, it also affected the occurrence of albinism in all genotypes. Our results demonstrated dual purpose of Cefotaxime for isolated microspore culture, most importantly it increases cell growth and success of microspore cultures in triticale and wheat genotypes, but would also prevent accidental loss of cultures with most common bacterial contaminants.

Cefotaxime prevents microbial contamination and improves microspore embryogenesis in wheat and triticale

Cefotaxime (100 mg/l) mitigate occasional gram negative bacterial contamination in wheat and triticale microspore culture and most importantly it increases cell growth and green plant production. Isolated microspore culture is a promising option to rapidly fix the product of meiotic recombination of F1 hybrids, in the process of varietal development. Clean culture and high embryogenesis rate are essential to commercial triticale and wheat microspore cultures. So, this study investigated (1) contaminants from isolated microspores cultures, (2) two antibiotics to control bacterial growth, and (3) the contribution of antibiotics to increased microspore-derived embryo-like structures (ELS), green and albino plants. Five species of bacteria were identified in contaminated cultures (Erwinia aphidicola, Pantoea agglomerans, Pseudomonas sp., Staphylococcus epidermis and Staphylococcus warneri) using fatty acid analysis and 16S ribosomal RNA sequences analysis, and yeast. Antibacterial susceptibility test using Cefotaxime and Vancomycin resulted in strong inhibition of 24 bacterial isolates, using Cefotaxime at 100 mg/l, but not Pseudomonas sp. Other antibiotic treatments inhibited bacterial growth at least partially. Microspore induction medium supplemented with the same antibiotics treatments resulted in successful microspore embryogenesis and green plant production. Antibiotic treatments were first tested in triticale and then validated in wheat cultivars AC Carberry and AC Andrew. Induction medium supplemented with Cefotaxime at 50 and 100 mg/l substantially increased the formation of ELS and green plants in triticale and wheat, respectively. Incidentally, it also affected the occurrence of albinism in all genotypes. Our results demonstrated dual purpose of Cefotaxime for isolated microspore culture, most importantly it increases cell growth and success of microspore cultures in triticale and wheat genotypes, but would also prevent accidental loss of cultures with most common bacterial contaminants.