Team:Cambridge-JIC/Marchantia/Background
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<p>Liverworts are defined by their simplicity. Marchantia, like other liverworts, has no vascular tissue and anchors itself not with true roots but with very long single cells called rhizoids, which become a matted array of filaments extending only ten or fifteen millimetres into the substrate. This simplicity is due to the retention of primitive characteristics evolved in early plants. One of these is the absence of flowers or seeds and the propagation of the plant in two old-fashioned ways.</p> | <p>Liverworts are defined by their simplicity. Marchantia, like other liverworts, has no vascular tissue and anchors itself not with true roots but with very long single cells called rhizoids, which become a matted array of filaments extending only ten or fifteen millimetres into the substrate. This simplicity is due to the retention of primitive characteristics evolved in early plants. One of these is the absence of flowers or seeds and the propagation of the plant in two old-fashioned ways.</p> | ||
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+ | <p> Marchantia can be found worldwide, from tropical to arctic climates and urban areas. It grows in damp habitats, such as banks of pools and rivers, bogs, fens and dune slacks. After fires, Marchantia rapidly colonizes the burnt ground, restoring an eco-system. </p> | ||
<p>One of these ways is through the splash cups (or gemma cups) which pockmark the upper surface of the plant. Inside these cups grow tiny sproutlings of marchantia called gemmae, with undeveloped rhizoids and thalli. They are halted from growing large inside their cups by the presence of a compound called lunularic acid in the space they inhabit, placed there by the tissue of the splash cup. When it rains, drops which fall into these cups rebound out and take these tiny gemmae with them, carrying them to the soil. Once on solid ground, they start to grow into a new individual.</p> | <p>One of these ways is through the splash cups (or gemma cups) which pockmark the upper surface of the plant. Inside these cups grow tiny sproutlings of marchantia called gemmae, with undeveloped rhizoids and thalli. They are halted from growing large inside their cups by the presence of a compound called lunularic acid in the space they inhabit, placed there by the tissue of the splash cup. When it rains, drops which fall into these cups rebound out and take these tiny gemmae with them, carrying them to the soil. Once on solid ground, they start to grow into a new individual.</p> | ||
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<p>These characteristics and the simple structure of marchantia’s genome, which often contains just one gene where in higher plants (like Arabidopsis) are found complex clusters of genes of similar and overlapping functions, make it a fascinating plant to study. They also make it a chassis perfect for synthetic biology. </p> | <p>These characteristics and the simple structure of marchantia’s genome, which often contains just one gene where in higher plants (like Arabidopsis) are found complex clusters of genes of similar and overlapping functions, make it a fascinating plant to study. They also make it a chassis perfect for synthetic biology. </p> | ||
- | <p> | + | |
+ | <h3>Key Features of Marchantia</h3> | ||
+ | <UL> | ||
+ | <lI>1. Descendant of earliest land plants | ||
+ | <li>2. Haploid genetics | ||
+ | <li>3. Vegetative propagation by gemmae/self-propagates/isogenic lines | ||
+ | <li>4. Easily propagated in vitro, small | ||
+ | <li>5. Gametes induced by far-red light | ||
+ | <li>6. Crossing easy | ||
+ | <li>7. Spores stable for >1 year | ||
+ | <li>8. EST collection available | ||
+ | <li>9. Easily regenerates in tissue culture | ||
+ | <li>10. High frequency nuclear and plastid transformation | ||
+ | <li>11. Y chromosome and plastid genomes sequenced | ||
+ | <li>12. 280 MB genome sequence has been completed and is being mined. | ||
+ | </UL> | ||
+ | |||
+ | |||
+ | </p> | ||
+ | <h3>Current Resources</h3> | ||
+ | <p>The OpenPlant project has assembled on a single database the complete library of published research done on Marchantia polymorpha. This offers a connected platform of knowledge and a forum for scientific exchange. There are two strains of polymorpha under study. Visit Marchantia.org for more information.</p> | ||
<br> | <br> | ||
<p><b>To fully make advantage of the many possibilities this new chassis may present, it is crucial to analyse and characterise its genome. Read more about our <a href="https://2014.igem.org/Team:Cambridge-JIC/Marchantia/Codon">codon optimisation</a> and <a href="https://2014.igem.org/Team:Cambridge-JIC/Marchantia/Promoter">promoter hunt</a> work.</b></p> | <p><b>To fully make advantage of the many possibilities this new chassis may present, it is crucial to analyse and characterise its genome. Read more about our <a href="https://2014.igem.org/Team:Cambridge-JIC/Marchantia/Codon">codon optimisation</a> and <a href="https://2014.igem.org/Team:Cambridge-JIC/Marchantia/Promoter">promoter hunt</a> work.</b></p> |
Latest revision as of 17:35, 17 October 2014
Introduction to Marchantia
Marchantia polymorpha is a member of one of the most primitive divisions of land plants, the liverworts. It grows as flat sheets of tissue called thalli (a singular one is called a thallus), and once spotted is a common sight by the sides of ponds and streams, and in shaded gaps in masonry throughout the world. Each plant grows to be between two and ten centimetres across, and is quite unlike more familiar plants in a number of ways.
Some marchantia plants near a shoe for scale
Liverworts are defined by their simplicity. Marchantia, like other liverworts, has no vascular tissue and anchors itself not with true roots but with very long single cells called rhizoids, which become a matted array of filaments extending only ten or fifteen millimetres into the substrate. This simplicity is due to the retention of primitive characteristics evolved in early plants. One of these is the absence of flowers or seeds and the propagation of the plant in two old-fashioned ways.
Marchantia can be found worldwide, from tropical to arctic climates and urban areas. It grows in damp habitats, such as banks of pools and rivers, bogs, fens and dune slacks. After fires, Marchantia rapidly colonizes the burnt ground, restoring an eco-system.
One of these ways is through the splash cups (or gemma cups) which pockmark the upper surface of the plant. Inside these cups grow tiny sproutlings of marchantia called gemmae, with undeveloped rhizoids and thalli. They are halted from growing large inside their cups by the presence of a compound called lunularic acid in the space they inhabit, placed there by the tissue of the splash cup. When it rains, drops which fall into these cups rebound out and take these tiny gemmae with them, carrying them to the soil. Once on solid ground, they start to grow into a new individual.
A gemma cup with gemmae visible inside
Marchantia can reproduce sexually as well as through this ‘fragmentation’, and is in fact dioecious, meaning that an individual plant is either a male or a female. When induced by a shift in ambient light to far red, which signals that other plants are looming overhead, strange mushroom-like structures begin to sprout from the top of each plant. In males, these eventually take the form of a flat polygonal table, in females, the sprouts become archegonia, which look like miniature palm trees and when mature will bear eggs.
The antheridia, as the male table-like structures are called, produce two-tailed sperm instead of the pollen you might expect. These are spread by rain to the waiting eggs of the archegonia , which they fertilise and induce to become hardy spores. These spores number in the thousands in each archegonium, which when twinned with the dispersal of gemma makes marchantia very prolific.
An archegonium, removed from a female plant (left) and an antheridium from a male plant (right)
The plants also have the ability to regenerate a whole new plant from a mere scrap of tissue, without the necessity of adding any hormones or other growth factors. Like in other primitive plants such as ferns, every cell contains a haploid genome except for a small amount of sexual tissue during the plant’s spore production stage.
These characteristics and the simple structure of marchantia’s genome, which often contains just one gene where in higher plants (like Arabidopsis) are found complex clusters of genes of similar and overlapping functions, make it a fascinating plant to study. They also make it a chassis perfect for synthetic biology.
Key Features of Marchantia
- 1. Descendant of earliest land plants
- 2. Haploid genetics
- 3. Vegetative propagation by gemmae/self-propagates/isogenic lines
- 4. Easily propagated in vitro, small
- 5. Gametes induced by far-red light
- 6. Crossing easy
- 7. Spores stable for >1 year
- 8. EST collection available
- 9. Easily regenerates in tissue culture
- 10. High frequency nuclear and plastid transformation
- 11. Y chromosome and plastid genomes sequenced
- 12. 280 MB genome sequence has been completed and is being mined.
Current Resources
The OpenPlant project has assembled on a single database the complete library of published research done on Marchantia polymorpha. This offers a connected platform of knowledge and a forum for scientific exchange. There are two strains of polymorpha under study. Visit Marchantia.org for more information.
To fully make advantage of the many possibilities this new chassis may present, it is crucial to analyse and characterise its genome. Read more about our codon optimisation and promoter hunt work.