Degradation
of Germplasm Resources

Currently, the issue of germplasm degradation is increasingly drawing widespread attention. Germplasm resources serve as a crucial foundation for agricultural production. However, due to various factors, the germplasm resources of many crops and organisms are undergoing severe degradation. This degradation manifests in several aspects, including reduced genetic diversity, decreased stress resistance, and declining productivity.

Plant Germplasm
Improvement

The research team at Magicpen bio has developed a high-throughput gene editing technology in-house, creating a large-scale array of targeted mutants and conducting high-throughput phenotypic identification. Utilizing gene editing techniques and genetic improvement methods, they have embarked on research into drought tolerance germplasm improvement for various crucial crops. By delving deep into the genetic resources of crops themselves and precisely editing key genes, the research team has successfully enhanced the adaptability and survival rate of multiple crops under drought conditions.

Genetic Transformation Platform

We possess mature genetic transformation systems for various crops such as wheat, corn, rice, and dwarf morning glory. Leveraging this advanced technology, we can rapidly obtain transgenic plants, providing reliable support for gene function identification. Whether the research focus lies in agricultural biotechnology, crop improvement, or biopharmaceuticals, our transformation systems will serve as crucial tools for achieving scientific objectives.

How We Do It

With the aid of genetic engineering technology, we have transformed plants into biofactories, synthesizing bio-products that are more beneficial to humans. These products include nutrient-enhanced foods, natural medicinal compounds, environmentally-friendly cosmetics, and more. Through plant synthesis, we sidestep the side effects of chemical synthesis, offering safer and healthier alternatives. This technology not only advances the development of healthy living but also opens new pathways for the environmental industry.

Author

Anthocyanins are a class of natural pigments with extensive application prospects, widely used in the food, cosmetics, and pharmaceutical industries. Traditional methods of anthocyanin extraction often rely on chemical synthesis or direct extraction from specific plants, both of which are typically costly and environmentally burdensome. Therefore, developing a sustainable biosynthetic strategy, utilizing transgenic plants as production platforms, not only reduces production costs but also enables environmentally friendly anthocyanin production.

Author

Our Products

Currently, utilizing tobacco plants as our base, we have incorporated genes related to anthocyanin synthesis, allowing us to continuously obtain plant-derived anthocyanins. In the future, we aim to produce a wider array of substances within plants, to be applied across the food, cosmetics, and pharmaceutical industries.

Author

Through our meticulously established diverse gene library, combined with mature gene amplification techniques, we have achieved efficient gene cloning. This innovative approach not only provides a high-throughput platform for gene expression and analysis but also opens up entirely new possibilities for research and development in the life sciences. Whether in basic research or applied exploration, our gene library and amplification system will serve as powerful tools for achieving scientific breakthroughs.

High-Throughput Vector Construction

In addition to our high-throughput gene cloning platform, we have also established a high-throughput vector construction platform. Through mature high-throughput vector construction techniques, large-scale vector construction tasks can be easily accomplished. This advanced technology not only enables the efficient production of a large quantity of vectors but also distinguishes itself from traditional library construction techniques by accurately inserting each gene into the target vector, yielding individual vectors. This provides robust support for scientific research endeavors. Whether in genetic engineering, gene editing, or protein expression, our high-throughput vector construction system serves as a reliable assistant in achieving scientific objectives.

Genetic Transformation Platform

We possess mature genetic transformation systems for various crops such as wheat, corn, rice, and dwarf morning glory. Leveraging this advanced technology, we can rapidly obtain transgenic plants, providing reliable support for gene function identification. Whether the research focus lies in agricultural biotechnology, crop improvement, or biopharmaceuticals, our transformation systems will serve as crucial tools for achieving scientific objectives.

Given the limitations imposed on outdoor cultivation, our greenhouse has become an indispensable resource. Be it the cold winter or the hot summer, the greenhouse can provide us with the required biological materials. In this controlled environment, we can cultivate various plants to meet different demands for raw materials. Due to stringent environmental control, the quality of these plants is more stable and reliable.