Personal profile
Short presentation
Dr. Trinh is a seasoned scientist with fourteen years of expertise in the field of Life Science, including research and advanced education. His areas of knowledge encompass plant breeding, molecular biology, photosynthesis, cell biology, biochemistry, and microbiology. He also harbors a deep fascination with engaging subjects like quinoa, sustainability, agriculture, biotechnology, and biodiversity.
A critical biological process, photosynthesis transforms light energy into organic compounds in organisms capable of photosynthesis, bridging the gap between sunlight and life on our planet. The importance of enhancing the efficiency of photosynthesis in plants cannot be overstated, considering they only convert about 6% of solar energy into biomass. Boosting photosynthesis could help us meet the food demands of an anticipated ten billion people by 2050. During his Ph.D. studies at the Tokyo Institute of Technology, Dr. Trinh delved into photosynthesis, particularly its complex regulation, under Professor Shinji Masuda's mentorship. His research contributed to seven peer-reviewed papers.
Global food security is threatened by the expected climate change and rapid global warming. Common crops like maize, rice, wheat, and soybeans lack the resilience to withstand increasing abiotic stresses such as high temperatures, cold, frost, drought, soil salinization, and flooding. As a member of Professor Michael Palmgren's research team at the University of Copenhagen, their group "Exploring P-type Pumps and Novel Crops" seeks to cultivate novel crops that can adapt to extreme conditions while still yielding abundantly. Dr. Trinh's current work centers on improving the resilient, yet underutilized, quinoa plant, originally from the Andean region of South America, through the use of genetic technologies. Their goal is to make quinoa a worldwide staple by improving key agricultural characteristics, including seed size, resistance to shattering, pre-harvest sprouting, plant stature, flowering time, and tolerance to heat and mildew. Equally essential is the removal of antinutritional saponins from quinoa seeds.
Education/Academic qualification
Life Science and Technology, Doctor of Science, Physiological characterization of novel photosynthetic regulatory proteins in Arabidopsis thaliana, Institute of Science Tokyo
Award Date: 25 Sept 2020
Biological Sciences, Master of Science, Mutational analysis of a novel chloroplast protein, Triplet-cysteine Motif Repeat protein 1 (TMR1), by CRISPR-CAS9-based gene editing., Institute of Science Tokyo
Award Date: 20 Sept 2017
Biochemistry, Master of Science, Study on antibacterial and antioxidative activities of carboxymethyl and aryl chitooligosaccharides, Vietnam National University Ho Chi Minh City
Award Date: 30 May 2013
Biology, Bachelor of Science, Isolation of canthaxanthin from microorganisms, Vietnam National University Ho Chi Minh City
Award Date: 14 Sept 2010
Keywords
- Faculty of Science
- Plant physiology
- Molecular Biology
- Plant biotechnology
- Plant breeding
- Quinoa
- Photosynthesis
Collaborations and top research areas from the last five years
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Chloroplast envelope-localized DLDG1 modulates H+ translocation across thylakoid membranes via plastidial ATP synthase
Trinh, M. D. L., Esmailpourmoghadam, E., Sato, R., Miyake, C., Palmgren, M. & Masuda, S., 2025, In: Plant Physiology. 199, 1, 14 p., kiaf373.Research output: Contribution to journal › Journal article › Research › peer-review
1 Citation (Scopus) -
Root restriction accelerates genomic target identification in quinoa under controlled conditions
Visintainer, D., Sørensen, N. F., Chen, M., Trinh, M. D. L., da Fonseca, R. R., Fondevilla, S. & Lopez-Marques, R. L., 2025, In: Physiologia Plantarum. 177, 2, 15 p., e70223.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile2 Citations (Scopus)59 Downloads (Pure) -
Unlocking in vitro transformation of recalcitrant plants
Luo, G., Trinh, M. D. L., Falkenberg, M. K. D., Chiurazzi, M. J., Najafi, J., Nørrevang, A. F., Pereira Correia, P. M. & Palmgren, M., 2025, In: Trends in Plant Science. 30, 12, p. 1306-1321Research output: Contribution to journal › Comment/debate › Research › peer-review
7 Citations (Scopus) -
Site-directed genotype screening for elimination of antinutritional saponins in quinoa seeds identifies TSARL1 as a master controller of saponin biosynthesis selectively in seeds
Trinh, M. D. L., Visintainer, D., Günther, J., Østerberg, J. T., Rodrigues da Fonseca, R. A., Fondevilla, S., Moog, M. W., Luo, G., Nørrevang, A. F., Crocoll, C., Nielsen, P. V., Jacobsen, S.-E., Wendt, T., Bak, S., López-Marqués, R. L. & Palmgren, M., 2024, In: Plant Biotechnology Journal. 22, 8, p. 2216-2234 19 p.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile14 Citations (Scopus)58 Downloads (Pure) -
Accelerated Domestication of New Crops: Yield is Key
Luo, G., Najafi, J., Correia, P. M. P., Trinh, M. D. L., Chapman, E. A., Østerberg, J. T., Thomsen, H. C., Pedas, P. R., Larson, S., Gao, C., Poland, J., Knudsen, S., DeHaan, L. & Palmgren, M., 2022, In: Plant and Cell Physiology. 63, 11, p. 1624-1640 pcac065.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile34 Citations (Scopus)93 Downloads (Pure) -
Chloroplast pH Homeostasis for the Regulation of Photosynthesis
Trinh, M. D. L. & Masuda, S., 2022, In: Frontiers in Plant Science. 13, 16 p., 919896.Research output: Contribution to journal › Review › peer-review
Open AccessFile48 Citations (Scopus)41 Downloads (Pure) -
The epidermal bladder cell-free mutant of the salt tolerant quinoa challenges our understanding of halophyte crop salinity tolerance
Moog, M. W., Trinh, M. D. L., Nørrevang, A. F., Bendtsen, A. K., Wang, C., Østerberg, J. T., Shabala, S., Hedrich, R., Wendt, T. & Palmgren, M., 2022, In: New Phytologist. 236, 4, p. 1409-1421 13 p.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile33 Citations (Scopus)82 Downloads (Pure) -
The evolution of plant proton pump regulation via the R domain may have facilitated plant terrestrialization
Stéger, A., Hayashi, M., Lauritzen, E. W., Herburger, K., Shabala, L., Wang, C., Bendtsen, A. K., Nørrevang, A. F., Madriz-Ordeñana, K., Ren, S., Trinh, M. D. L., Thordal-Christensen, H., Fuglsang, A. T., Shabala, S., Østerberg, J. T. & Palmgren, M., 2022, In: Communications Biology . 5, 15 p., 1312.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile20 Citations (Scopus)95 Downloads (Pure)
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The Nordic Photosynthesis Congress and Nordic Algae Symposium 2025
Trinh, M. D. L. (Participant)
20 Oct 2025 → 23 Oct 2025Activity: Participating in an event - types › Organisation of and participation in conference
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Accelerating quinoa breeding through site-directed genotype screening reveals TSARL1 as a key regulator of saponin biosynthesis in quinoa seeds
Trinh, M. D. L. (Speaker)
21 Aug 2024 → 23 Aug 2024Activity: Presentations, memberships and other activity types › Lecture and oral contribution
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International Quinoa Symposium 2024
Trinh, M. D. L. (Speaker)
24 Jul 2024 → 26 Jul 2024Activity: Participating in an event - types › Organisation of and participation in conference
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Accelerating quinoa breeding through site-directed genotype screening reveals TSARL1 as a key regulator of saponin biosynthesis in quinoa seeds
Trinh, M. D. L. (Speaker)
24 Jul 2024 → 26 Jul 2024Activity: Presentations, memberships and other activity types › Lecture and oral contribution
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Using new technology to specifically identify quinoa mutants deficient in the biosynthesis of seed saponins
Trinh, M. D. L. (Invited speaker)
28 Mar 2023 → 31 Mar 2023Activity: Presentations, memberships and other activity types › Lecture and oral contribution