Location History:
- Shizuoka-ken, JP (2002 - 2006)
- Iwata-gun, JP (2011)
Company Filing History:
Years Active: 2002-2011
Title: Innovations of Inventor Hideaki Saito
Introduction
Hideaki Saito is a prominent inventor based in Shizuoka-ken, Japan. He has made significant contributions to the field of plant biotechnology, particularly in the transformation of monocotyledons. With a total of 3 patents to his name, Saito's work has the potential to revolutionize agricultural practices.
Latest Patents
One of Saito's latest patents is a method of transforming monocotyledons using scutella of immature embryos. This innovative method reduces the time required for transformation to regeneration of a whole plant, minimizing the occurrence of mutants. It can be applied to various plants where traditional regeneration systems are not established. The method involves transforming the scutellum of an immature embryo with a bacterium containing a desired gene, allowing for the creation of transformants without the need for complex apparatuses.
Another notable patent is a DNA fragment directing gene expression predominant in flower organs. This invention provides a novel DNA sequence with flower organ-specific promoter activity, enabling the expression of foreign genes specifically in the pistil or lodicule. The patent includes a DNA fragment that can be identified from genomic libraries of rice or other plants, facilitating genetic manipulation.
Career Highlights
Hideaki Saito is currently associated with Japan Tobacco Inc., where he continues to innovate in the field of biotechnology. His work has garnered attention for its practical applications in agriculture and genetic research.
Collaborations
Saito has collaborated with notable colleagues such as Yoshimitsu Takakura and Tsuyoshi Inoue, contributing to advancements in their shared field of expertise.
Conclusion
Hideaki Saito's contributions to plant biotechnology through his innovative patents demonstrate his commitment to advancing agricultural science. His work not only enhances our understanding of plant transformation but also opens new avenues for genetic research and application.