A method for disinfecting explants of Kadsura coccinea stems with buds and a method for directly inducing rapid proliferation of sterile buds by using the explants of Kadsura coccinea stems with buds involve processes such as selection, treatment and disinfection of explants, primary culture, subculture proliferation culture. The problem of difficulty in tissue culture and primary culture of Kadsura coccinea stems is solved, and the advantages include low contamination rate of explants, high propagation rate and robust proliferation of axillary buds. This allows obtaining sterile axillary buds of Kadsura coccinea through tissue culture, and provides support for tissue culture, rapid propagation and factory seedling of Kadsura coccinea in the future.

The present disclosure describes novel methods for preparing leaf-derived plant cell suspension cultures. The cell suspension cultures produced by the methods provide a renewable and efficient source of protoplasts for high-throughput transformation and other uses. Applicants have surprisingly found that protoplasts can be obtained from the cell suspension cultures with inexpensive cell wall degrading enzymes and that the protoplasts provide increased transformation efficiencies relative to protoplasts from other sources.

The present application relates to methods for the production of plant material suitable for the extraction and purification of saponins, through plantations of clone plants of defined chemotype, including ultrahigh density plantations of Quillaja saponaria Molina, and methods to increase the recovery of saponins by solid/liquid extraction of the harvested plant material.

Methods of in vitro clonal propagation, regeneration and transformation in Cannabis are provided. Also provided is the use of such methods in improvements of cannabis cultivars such as via breeding.

Provided are a composition for editing a Cannabis gene, a kit for editing a Cannabis gene, a kit for inhibiting Cannabis DNA expression and targeting the DNA, and a method of editing Cannabis DNA, each using a gene editing protein; a method of preparing an edited Cannabis gene including a step of forming calli; a gRNA for editing a Cannabis gene; and a use of the gRNA of the present invention and a use of both the gene editing protein and the gRNA for editing a Cannabis gene.

The present disclosure describes a method of culturing and harvesting plant shoot tips. The method includes providing a sterile vessel configured to hold at least one plant with one or more root masses and a first set of shoot tips, cutting across a base of the shoot tips with the one or more root masses held in the vessel to cut a first plurality of cut shoot tips at a first time; then growing a second set of shoot tips from the one or more root masses in the vessel; and then cutting across the one or more root masses held in the vessel to cut a second plurality of cut shoot tips. Plant tissue culture devices are also described.

The present invention relates to novel plants, in particular to pepper plants capable of producing fruits which can be kept a longer period of time on the plant as well as being stored after harvesting under refrigerated conditions without exhibiting excessive softening. The invention thus refers to pepper plant which produces fruits with significantly increased fruit firmness at the harvesting stage, wherein said increased fruit firmness is controlled by a genetic determinant, monogenic, wherein said increased fruit firmness is defined as a fruit deformation under a 1 kg load force that is lower than that of a fruit from a control pepper plant which does not have the said genetic determinant.

In a first aspect, the invention relates to a method for obtaining a sweet potato propagating material. In a second and third aspect, the invention relates to sweet potato propagating material and a plurality thereof.

The present invention provides a method for improving a one-time seedling rate of microspore embryoids of Brassica campestris ssp. Chinensis Makino, including the steps of: spraying 6-BA onto a flower bud of a plant; sterilizing the flower bud with alcohol and HgCl.sub.2; releasing microspores, filtering and centrifuging to obtain purified microspores; diluting the microspores with a NLN medium, subpackaging into culture dishes, and adding phytic acid; finally, subjecting to heat shock treatment and transferring to culture in the dark until embryoids appear, and then conducting shaking culture; transferring the cultured embryos in a cotyledon stage onto a MS medium for differentiation culture, wherein the culture conditions are: 4° C., 14 h of illumination by blue-red compound light/day, and 14 days of culture; and then continuing to culture under the condition of 25° C. and 14 h of illumination by blue-red compound light/day until seedlings.

The present disclosure provides approaches for reducing tobacco-specific nitrosamines (TSNAs) in tobacco. Some of these approaches include genetically engineering tobacco plants to increase one or more antioxidants, increase oxygen radicle absorbance capacity (ORAC), or reduce nitrite. Also provided are methods and compositions for producing modified tobacco plants and tobacco products therefrom comprising reduced TSNAs.