Botanists and biologists began to research
A. thaliana in the early 1900s, and the first systematic description of mutants was done around 1945.
A. thaliana is now widely used for studying
plant sciences, including
genetics,
evolution, population genetics, and plant development. Although
A. thaliana the plant has little direct significance for agriculture,
A. thaliana the model organism has revolutionized our understanding of the genetic, cellular, and molecular biology of flowering plants. The first mutant in
A. thaliana was documented in 1873 by
Alexander Braun, describing a
double flower phenotype (the mutated gene was likely
Agamous, cloned and characterized in 1990).
Friedrich Laibach (who had published the chromosome number in 1907) did not propose
A. thaliana as a model organism, though, until 1943. His student, Erna Reinholz, published her thesis on
A. thaliana in 1945, describing the first collection of
A. thaliana mutants that they generated using
X-ray mutagenesis. Laibach continued his important contributions to
A. thaliana research by collecting a large number of accessions (often questionably referred to as "
ecotypes"). With the help of Albert Kranz, these were organised into a large collection of 750 natural accessions of
A. thaliana from around the world. In the 1950s and 1960s, John Langridge and
George Rédei played an important role in establishing
A. thaliana as a useful organism for biological laboratory experiments. Rédei wrote several scholarly reviews instrumental in introducing the model to the scientific community. The start of the
A. thaliana research community dates to a newsletter called
Arabidopsis Information Service, established in 1964. The first International
Arabidopsis Conference was held in 1965, in
Göttingen, Germany. In the 1980s,
A. thaliana started to become widely used in plant research laboratories around the world. It was one of several candidates that included maize,
petunia, and tobacco.
Genomics s,
A. thaliana has one of the smallest genomes among plants. but that title is now considered to belong to plants in the genus
Genlisea, order
Lamiales, with
Genlisea tuberosa, a carnivorous plant, showing a genome size of approximately 61 Mbp. It was the first plant genome to be sequenced, completed in 2000 by the
Arabidopsis Genome Initiative. The most up-to-date version of the
A. thaliana genome is maintained by
The Arabidopsis Information Resource (TAIR). The genome encodes ~27,600
protein-coding
genes and about 6,500 non-coding genes. However, the Uniprot database lists 39,342 proteins in their
Arabidopsis reference proteome. Among the 27,600 protein-coding genes 25,402 (91.8%) are now annotated with "meaningful" product names, although a large fraction of these proteins is likely only poorly understood and only known in general terms (e.g. as "DNA-binding protein without known specificity"). Uniprot lists more than 3,000 proteins as "uncharacterized" as part of the reference proteome.
Chloroplast genome The
plastome of
A. thaliana is a 154,478 base-pair-long DNA molecule, a size typically encountered in most flowering plants (see the
list of sequenced plastomes). It comprises 136 genes coding for small subunit ribosomal proteins (
rps, in yellow: see figure), large subunit ribosomal proteins (
rpl, orange), hypothetical chloroplast open reading frame proteins (
ycf, lemon), proteins involved in photosynthetic reactions (green) or in other functions (red), ribosomal RNAs (
rrn, blue), and transfer RNAs (
trn, black).
Mitochondrial genome The
mitochondrial genome of
A. thaliana is 367,808 base pairs long and contains 57 genes. There are many repeated regions in the
A. thaliana mitochondrial genome. The largest repeats
recombine regularly and isomerize the genome. Like most plant mitochondrial genomes, the
A. thaliana mitochondrial genome exists as a complex arrangement of overlapping branched and linear molecules
in vivo.
Genetics Genetic transformation of
A. thaliana is routine, using
Agrobacterium tumefaciens to transfer
DNA into the plant genome. The current protocol, termed "floral dip", involves simply dipping
floral buds into a solution containing
Agrobacterium carrying a plasmid of interest and a detergent. This method avoids the need for
tissue culture or plant regeneration. The
A. thaliana gene knockout collections are a unique resource for plant biology made possible by the availability of high-throughput transformation and funding for genomics resources. The site of T-DNA insertions has been determined for over 300,000 independent transgenic lines, with the information and seeds accessible through online T-DNA databases. Through these collections, insertional mutants are available for most genes in
A. thaliana. Characterized accessions and mutant lines of
A. thaliana serve as experimental material in laboratory studies. The most commonly used background lines are L
er (Landsberg
erecta), and Col, or Columbia. Other background lines less-often cited in the scientific literature are Ws, or Wassilewskija, C24, Cvi, or Cape Verde Islands, Nossen, etc. (see for ex.) Sets of closely related accessions named Col-0, Col-1, etc., have been obtained and characterized; in general, mutant lines are available through stock centers, of which best-known are the Nottingham Arabidopsis Stock Center-NASC The Col-0 accession was selected by Rédei from within a (nonirradiated) population of seeds designated 'Landsberg' which he received from Laibach. Columbia (named for the location of Rédei's former institution,
University of Missouri-
Columbia) was the reference accession sequenced in the Arabidopsis Genome Initiative. The Later (Landsberg
erecta) line was selected by Rédei (because of its short stature) from a Landsberg population he had mutagenized with X-rays. As the L
er collection of mutants is derived from this initial line, L
er-0 does not correspond to the Landsberg accessions, which designated La-0, La-1, etc. Trichome formation is initiated by the GLABROUS1 protein.
Knockouts of the corresponding gene lead to
glabrous plants. This
phenotype has already been used in
gene editing experiments and might be of interest as visual marker for plant research to improve gene editing methods such as
CRISPR/Cas9. Non-Mendelian inheritance controversy In 2005, scientists at
Purdue University proposed that
A. thaliana possessed an alternative to previously known mechanisms of
DNA repair, producing an unusual pattern of
inheritance, but the phenomenon observed (reversion of mutant copies of the
HOTHEAD gene to a wild-type state) was later suggested to be an artifact because the mutants show increased outcrossing due to organ fusion.
Lifecycle The plant's small size and rapid lifecycle are also advantageous for research. Having specialized as a
spring ephemeral, it has been used to found several laboratory strains that take about 6 weeks from germination to mature seed. The small size of the plant is convenient for cultivation in a small space, and it produces many seeds. Further, the
selfing nature of this plant assists genetic experiments. Also, as an individual plant can produce several thousand seeds, each of the above criteria leads to
A. thaliana being valued as a genetic model organism.
Cellular biology Arabidopsis is often the model for study of
SNAREs in plants. This has shown SNAREs to be heavily involved in
vesicle trafficking. Zheng et al. 1999 found an arabidopsis SNARE called is probably essential to
Golgi-
vacuole trafficking. This is still a wide open field and plant SNAREs' role in trafficking remains understudied.
DNA repair The
DNA of plants is vulnerable to
ultraviolet light, and
DNA repair mechanisms have evolved to avoid or repair genome damage caused by UV. Kaiser et al. showed that in
A. thaliana cyclobutane pyrimidine dimers (CPDs) induced by UV light can be repaired by expression of CPD
photolyase.
Germination in lunar regolith On May 12, 2022,
NASA announced that specimens of
Arabidopsis thaliana had been successfully germinated and grown in samples of
lunar regolith. While the plants successfully germinated and grew into seedlings, they were not as robust as specimens that had been grown in
volcanic ash as a control group, although the experiments also found some variation in the plants grown in regolith based on the location the samples were taken from, as
A. thaliana grown in regolith gathered during
Apollo 12 &
Apollo 17 were more robust than those grown in samples taken during
Apollo 11. ==Development==