Arabidopsis thaliana – NIH Director's Blog (original) (raw)
Watch Flowers Spring to Life
Posted on April 25th, 2019 by Dr. Francis Collins
Spring has sprung! The famous Washington cherry blossoms have come and gone, and the tulips and azaleas are in full bloom. In this mesmerizing video, you’ll get a glimpse of the early steps in how some spring flowers bloom.
Floating into view are baby flowers, their cells outlined (red), at the tip of the stem of the mustard plant Arabidopsis thaliana. Stem cells that contain the gene STM (green) huddle in the center of this fast-growing region of the plant stem—these stem cells will later make all of the flower parts.
As the video pans out, slightly older flowers come into view. These contain organs called sepals (red, bumpy outer regions) that will grow into leafy support structures for the flower’s petals.
Movie credits go to Nathanaёl Prunet, an assistant professor at the University of California, Los Angeles, who shot this video while working in the NIH-supported lab of Elliot Meyerowitz at the California Institute of Technology, Pasadena. Prunet used confocal microscopy to display the different ages and stages of the developing flowers, generating a 3D data set of images. He then used software to produce a bird’s-eye view of those images and turned it into a cool movie. The video was one of the winners in the Federation of American Societies for Experimental Biology’s 2018 BioArt competition.
Beyond being cool, this video shows how a single gene, STM, plays a starring role in plant development. This gene acts like a molecular fountain of youth, keeping cells ever-young until it’s time to grow up and commit to making flowers and other plant parts.
Like humans, most plants begin life as a fertilized cell that divides over and over—first into a multi-cell embryo and then into mature parts, or organs. Because of its ease of use and low cost, Arabidopsis is a favorite model for scientists to learn the basic principles driving tissue growth and regrowth for humans as well as the beautiful plants outside your window. Happy Spring!
Links:
Meyerowitz Lab (California Institute of Technology, Pasadena)
Prunet Lab (University of California, Los Angeles)
The Arabidosis Information Resource (Phoenix Bioinformatics, Fremont, CA)
BioArt Scientific Image and Video Competition (Federation of American Societies for Experimental Biology, Bethesda, MD)
NIH Support: National Institute of General Medical Sciences
Posted In: Cool Videos
Tags: 2018 BioArt Scientific Image & Video Competition, Arabidopsis, Arabidopsis thaliana, BioArt, development, developmental biology, flowers, model organism, mustard plant, plants, stem cells, STM, video
Snapshots of Life: Arabidopsis Art
Posted on June 16th, 2016 by Dr. Francis Collins
Credit: Nathanaël Prunet, California Institute of Technology, Pasadena
Modern sculptors might want to take a few notes from Mother Nature. The striking, stone-like forms that you see above are a micrograph of flower buds from the mustard plant Arabidopsis thaliana, which serves as an important model organism in biomedical research. In the center are the shoot apical meristems, consisting of undifferentiated stem cells (gray) that give rise to the flowers. Around the edge are buds that are several hours older, in which the flowers have just begun to form off of the shoot apical meristems. And, to the bottom left, are four structures that are the early sepals that will surround the fully formed flower that will bloom in a few weeks. The colored circles indicate areas of gene activity involved in determining the gender of the resulting flower, with masculinizing genes marked in green and feminizing in red.
This image, a winner in the Federation of American Societies for Experimental Biology’s 2015 BioArt competition, is the creation of postdoctoral student Nathanaёl Prunet, now in the NIH-supported lab of Elliot Meyerowitz at the California Institute of Technology, Pasadena, CA. Using scanning electron microscopy, Prunet snapped multiple 2D photographs of Arabidopsis buds at different tissue depths and computationally combined them to produce this 3D image.
Tags: Arabidopsis, Arabidopsis thaliana, development, FASEB Bioart 2015, flowers, genomics, model organisms, mustard plant, nutrition, pattern formation, plant biology, plants, regenerative medicine, sepal, shoot apical meristems
Snapshots of Life: From Arabidopsis to Zinc
Posted on January 21st, 2016 by Dr. Francis Collins
Credit: Suzana Car, Maria Hindt, Tracy Punshon, and Mary Lou Guerinot, Dartmouth College, Hanover, NH
To most people, the plant Arabidopsis thaliana might seem like just another pesky weed. But for plant biologists, this member of the mustard green family is a valuable model for studying a wide array of biological processes—including the patterns of zinc acquisition shown so vividly in the Arabidopsis leaf above. Using synchrotron X-ray fluorescence technology, researchers found zinc concentrations varied considerably even within a single leaf; the lowest levels are marked in blue, next lowest in green, medium in red, and highest in white, concentrated at the base of tiny hairs (trichomes) that extend from the leaf’s surface.
A winner in the Federation of American Societies for Experimental Biology’s 2015 BioArt competition, this micrograph stems from work being conducted by Suzana Car and colleagues in the NIH-funded lab of Mary Lou Guerinot at Dartmouth College, Hanover, NH. The researchers are still trying to figure out exactly what zinc is doing at the various locations within Arabidopsis, as well as whether zinc concentrations are constant or variable. What is well known is that zinc is an essential micronutrient for human health, with more than 300 enzymes dependent on this mineral to catalyze chemical reactions within our bodies.
Tags: Arabidopsis thaliana, diet, FASEB Bioart 2015, global health, micronutrients, model organisms, nutrition, plants, synchrotron X-ray fluorescence technology, zinc, zinc deficiency