Line 256: | Line 256: | ||
<div class="w3-center"> | <div class="w3-center"> | ||
− | <img src="https://static.igem.org/mediawiki/2018/2/25/T--hebrewu--Open_Source_HL.png" width=" | + | <img src="https://static.igem.org/mediawiki/2018/2/25/T--hebrewu--Open_Source_HL.png" width="30%"> |
<br /> <br /> <br /> | <br /> <br /> <br /> | ||
− | + | <p style="padding-left:215px;padding-right:230px;text-align:justify;line-height:1.5"> | |
+ | We created an open source platform aimed at helping researchers and organizations worldwide tackle their dioxin pollution. In our open source page, we present the basic foundations necessary to create a viable transgenic plant based on our research and experiments. | ||
+ | <br /><br /> | ||
+ | Our open source page features two main programs: our synthetic enzymatic pathway (i.e. optimized gene sequences for each plant, including descriptions), and our proposed plants that are optimal for our pathway. | ||
+ | We chose the plants based on 4 categories: Transformation, dioxin uptake efficiency, sterilization methods and plant durability. We did our best to gather the necessary information to support it using both academic research and verified gardening sites.<br /><br /> | ||
+ | |||
+ | Transformation - How many methods are known for the transformation of this plant? How easy and effective are they?<br /> | ||
+ | Dioxin uptake efficiency - How well does the plant absorb dioxin from the ground, compared to other plants?<br /> | ||
+ | Sterilization methods - With these types of solutions, it is important to be ecologically responsible; releasing genetically engineered plants into the environment is no trivial matter. The ability to sterilize the plants, along with short life expectancies in general, is key for the safe release of transformed plants.<br /> | ||
+ | Plant durability - Under what conditions do the plants grow? Where do they grow? Do they grow in regions that are in dire need of solutions to dioxin contaminations?<br /> | ||
+ | |||
+ | </p> | ||
Line 278: | Line 289: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
<div class="w3-container" style="width:80%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | <div class="w3-container" style="width:80%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | ||
− | | + | Uptake Rate</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | Zucchini | + | Deep root systems. |
+ | </li> | ||
+ | <li> | ||
+ | Zucchini roots grow mainly downward, while pumpkin`s grow mainly outward. | ||
</li> | </li> | ||
<li> | <li> | ||
− | + | High uptake values of nutrition from soil. | |
</li> | </li> | ||
<li> | <li> | ||
− | + | Able to absorb dioxins through roots and deliver them throughout the plant (potential for high-speed degradation in the plant). | |
</li> | </li> | ||
</ul><br /> | </ul><br /> | ||
Line 295: | Line 309: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-green" style="width:50%"><span class="w3-badge w3-white">2</span> | + | <div class="w3-container w3-green" style="width:50%"><span class="w3-badge w3-white">2</span> Growth Conditions</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | Short | + | Short-season plants, grown in hot seasons. |
</li> | </li> | ||
<li> | <li> | ||
Line 308: | Line 322: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-red" style="width:40%"><span class="w3-badge w3-white">3</span> | + | <div class="w3-container w3-red" style="width:40%"><span class="w3-badge w3-white">3</span> Transformation</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | Existing transformation methods | + | Existing transformation methods use agrobacterium. |
</li> | </li> | ||
<li> | <li> | ||
− | Whole genome sequence doesn`t exist yet. | + | Whole-genome sequence doesn`t exist yet. |
</li> | </li> | ||
</ul><br /> | </ul><br /> | ||
− | |||
− | |||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-yellow" style="width:30%"><span class="w3-badge w3-white">4</span> | + | <div class="w3-container w3-yellow" style="width:30%"><span class="w3-badge w3-white">4</span> Sterilization</div> |
</div> | </div> | ||
<ul> | <ul> | ||
− | <li> | + | <li> **************************** |
</li> | </li> | ||
</ul><br /> | </ul><br /> | ||
Line 346: | Line 358: | ||
<div class="w3-dark-grey w3-center" style="padding-left:10%;padding-right:10%"> | <div class="w3-dark-grey w3-center" style="padding-left:10%;padding-right:10%"> | ||
<br /> <br /> | <br /> <br /> | ||
− | <h2 class="w3-center w3-panel" style="width:100%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | + | <h2 class="w3-center w3-panel" style="width:100%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> Uptake Rate</h2> |
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
<br /> <br /> | <br /> <br /> | ||
Line 358: | Line 370: | ||
<p class="w3-large w3-serif"> | <p class="w3-large w3-serif"> | ||
<i class="fa fa-quote-right w3-xxlarge w3-margin-right"></i> | <i class="fa fa-quote-right w3-xxlarge w3-margin-right"></i> | ||
− | "Plants have been frequently shown to remove POPs from soils (Zhao et al. 2006; Susarla et al. 2002; Macek et al. 2000). The high propensity of selected Cucurbitaceae to extract PCDDs/PCDFs from soil was first reported by Hülster et al. (1994), who found that C. pepo L. fruits contained double the PCDD/PCDF concentrations of other examined plants. " </p> | + | "Plants have been frequently shown to remove POPs from soils (Zhao et al. 2006; Susarla et al. 2002; Macek et al. 2000). The high propensity of selected Cucurbitaceae to extract PCDDs/PCDFs from soil was first reported by Hülster et al. (1994), who found that C. pepo L. fruits contained double the PCDD/PCDF concentrations of other examined plants." </p> |
</div> <br /> <br /> | </div> <br /> <br /> | ||
+ | |||
+ | *****************************************************<br /> | ||
+ | |||
+ | <!-- | ||
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
− | Current results demonstrated that cultivation of C. pepo L. cv. ‘Atena Polka’ reduced total PCDD/PCDF content by a mean value of 37 % in soil amended with sewage sludge and 32 % in soil treated with urban sediment (Fig. 1A1, B1; Table 2S). Mean reduction in TEQ concentrations were 68 and 52 % in soil amended with sewage sludge and sediment, respectively; values almost twice those of PCDD/PCDF content (Fig. 1A2, B2; Table 2S). Wilcoxon matched pair test revealed significant differences in total and TEQ values before and after C. pepo L. cv. ‘Atena Polka’ cultivation at p = 0.067. The greatest decline of total PCDD/PCDF content was observed for control samples (66 % for soil with sewage sludge and 81 % for soil with sediment), while the greatest reduction of TEQ values was detected in samples fertilized with 9 and 18 t/ha of sewage sludge (72 and 73 %, respectively) (Fig. 1; Table 2S). In soil amended with 3 t/ha of sludge, ‘Atena Polka’ cultivation led to a 63 % reduction of TEQ. Other large decreases were also noted for soil amended with 9 and 18 t/ha of urban sediments (59 and 70 %, respectively), while a much smaller reduction (21 %) was noted for a dose of 3 t/ha (Fig. 1; Table 2S). The above declines in soil total and TEQ PCDD/PCDF concentrations are, from one site, a result of ‘Atena Polka’ cultivation, however, the bioremediation activity of soil microorganisms seems to also be an important factor responsible for the obtained reductions (Urbaniak 2013; Field and Sierra-Alvarez 2008). | + | Current results demonstrated that cultivation of C. pepo L. cv. ‘Atena Polka’ reduced total PCDD/PCDF content by a mean value of 37 % in soil amended with sewage sludge and 32 % in soil treated with urban sediment (Fig. 1A1, B1; Table 2S). Mean reduction in TEQ concentrations were 68 and 52 % in soil amended with sewage sludge and sediment, respectively; values almost twice those of PCDD/PCDF content (Fig. 1A2, B2; Table 2S). Wilcoxon matched pair test revealed significant differences in total and TEQ values before and after C. pepo L. cv. ‘Atena Polka’ cultivation at p = 0.067. The greatest decline of total PCDD/PCDF content was observed for control samples (66 % for soil with sewage sludge and 81 % for soil with sediment), while the greatest reduction of TEQ values was detected in samples fertilized with 9 and 18 t/ha of sewage sludge (72 and 73 %, respectively) (Fig. 1; Table 2S). In soil amended with 3 t/ha of sludge, ‘Atena Polka’ cultivation led to a 63 % reduction of TEQ. Other large decreases were also noted for soil amended with 9 and 18 t/ha of urban sediments (59 and 70 %, respectively), while a much smaller reduction (21 %) was noted for a dose of 3 t/ha (Fig. 1; Table 2S). The above declines in soil total and TEQ PCDD/PCDF concentrations are, from one site, a result of ‘Atena Polka’ cultivation, however, the bioremediation activity of soil microorganisms seems to also be an important factor responsible for the obtained reductions (Urbaniak 2013; Field and Sierra-Alvarez 2008).<sup>3</sup> |
− | </p> | + | </p> --> |
<img src="https://static.igem.org/mediawiki/2018/d/d5/T--Hebrewu--Zuccini_info_1_0.jpeg" style="width:60%"> | <img src="https://static.igem.org/mediawiki/2018/d/d5/T--Hebrewu--Zuccini_info_1_0.jpeg" style="width:60%"> | ||
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> <br /> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> <br /> | ||
Fig. 1: | Fig. 1: | ||
− | Mean decreases in total and TEQ PCDD/PCDF concentrations in soil amended with different doses of sewage sludge (A1, A2) and urban sediments (B1–B2) before and after Cucurbita pepo L. cv ‘Atena Polka’ cultivation" | + | "Mean decreases in total and TEQ PCDD/PCDF concentrations in soil amended with different doses of sewage sludge (A1, A2) and urban sediments (B1–B2) before and after Cucurbita pepo L. cv ‘Atena Polka’ cultivation"<sup>3</sup> |
</p> | </p> | ||
<br /> <br /> | <br /> <br /> | ||
− | <h2 class="w3-center w3-panel w3-green"><span class="w3-badge w3-white">2</span> | + | <h2 class="w3-center w3-panel w3-green"><span class="w3-badge w3-white">2</span> Growth Conditions</h2> |
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
− | Zucchini and pumpkin are very sensitive to cold weather, requires warm temperatures of above 16 degrees Celsius to grow, but to warm of a climate (above 38 degrees) will harm the plant. | + | Zucchini and pumpkin are very sensitive to cold weather, requires warm temperatures of above 16 degrees Celsius to grow, but to warm of a climate (above 38 degrees) will harm the plant. Zucchini takes about 60 days to mature. By then it produces fruit as long as someone picks them before they rot. Pumpkin requires between 90 to 160 days to mature. They both grow relatively quickly and, as such, have high root-uptake of nutrition from the ground. Both require moderate quantities of water to grow, which may make it more difficult to grow in drier climates; however, pumpkins have been successfully grown in Iraq, for example. Zucchini roots generally extend deeply downward in a taproot formation, while pumpkin roots tend to spread horizontally as well as vertically - most of its nutrients are absorbed from the upper 1/2 meter of the soil. |
+ | |||
</p> | </p> | ||
Line 390: | Line 407: | ||
There are few different ways to create triploid plants: | There are few different ways to create triploid plants: | ||
<ul style="text-align:left;padding-left:150px;"> | <ul style="text-align:left;padding-left:150px;"> | ||
− | <li> Natural selection - triploid plants occur in nature, meaning it is possible to look for the desired plant in nature. | + | <li> - Natural selection - triploid plants occur in nature, meaning it is possible to look for the desired plant in nature. |
</li> | </li> | ||
− | <li> Artificial hybridization - by sexual hybridization of different ploidy, one can create a triploid offspring. | + | <li> - Artificial hybridization - by sexual hybridization of different ploidy, one can create a triploid offspring. |
</li> | </li> | ||
− | <li> Endosperm culture in vitro - endosperm is a triploid tissue. Successful regeneration of a plant from an endosperm tissue would result in triploid plant. | + | <li> - Endosperm culture in vitro - endosperm is a triploid tissue. Successful regeneration of a plant from an endosperm tissue would result in triploid plant. |
</li> | </li> | ||
</ul> | </ul> | ||
Line 431: | Line 448: | ||
<div class="w3-twothird"> | <div class="w3-twothird"> | ||
− | <h1>Brassica campestris (Chinese | + | <h1>Brassica campestris (Chinese cabbage) </h1> |
<br /><br /> | <br /><br /> | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
<div class="w3-container" style="width:60%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | <div class="w3-container" style="width:60%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | ||
− | | + | Uptake Rate</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | Roots | + | Roots do not extend deeply or widely relative to other plants. |
</li> | </li> | ||
<li> | <li> | ||
− | + | High uptake of dioxins in roots. | |
</li> | </li> | ||
<li> | <li> | ||
Line 453: | Line 470: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-green" style="width:85%"><span class="w3-badge w3-white">2</span> | + | <div class="w3-container w3-green" style="width:85%"><span class="w3-badge w3-white">2</span> Growth Conditions</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | + | Grows in most parts of the world, mostly in temperate-cold areas. | |
</li> | </li> | ||
<li> | <li> | ||
Line 466: | Line 483: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-red" style="width:90%"><span class="w3-badge w3-white">3</span> | + | <div class="w3-container w3-red" style="width:90%"><span class="w3-badge w3-white">3</span> Transformation</div> |
</div> | </div> | ||
Line 477: | Line 494: | ||
</li> | </li> | ||
<li> | <li> | ||
− | Susceptible | + | Susceptible to hybridization. |
</li> | </li> | ||
</ul><br /> | </ul><br /> | ||
Line 485: | Line 502: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-yellow" style="width:90%"><span class="w3-badge w3-white">4</span> | + | <div class="w3-container w3-yellow" style="width:90%"><span class="w3-badge w3-white">4</span> Sterilization</div> |
</div> | </div> | ||
Line 505: | Line 522: | ||
<br /> <br /> | <br /> <br /> | ||
− | <h2 class="w3-center w3-panel" style="width:100%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | + | <h2 class="w3-center w3-panel" style="width:100%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> Uptake Rate</h2> |
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
<br /> <br /> | <br /> <br /> | ||
− | Although zucchini and pumpkin have showed the best overall uptake of dioxins, primarily showing an extraordinary shoot uptake of dioxins, Chinese cabbage | + | Although zucchini and pumpkin have showed the best overall uptake of dioxins, primarily showing an extraordinary shoot uptake of dioxins, Chinese cabbage has shown an especially high uptake of dioxins in their roots only according to Table 2. Since our proposed method takes effect in roots as well as the shoots, a high enough root uptake should suffice. |
</p> | </p> | ||
Line 517: | Line 534: | ||
− | <h2 class="w3-center w3-panel w3-green"><span class="w3-badge w3-white">2</span> | + | <h2 class="w3-center w3-panel w3-green"><span class="w3-badge w3-white">2</span> Growth Conditions</h2> |
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
− | Chinese cabbage requires cool temperatures between 7-17 degrees Celsius to grow and takes between 50-85 days to mature. It`s roots grow in taproot formation, spreading about 30 cm | + | Chinese cabbage requires cool temperatures, between 7-17 degrees Celsius, to grow and it takes between 50-85 days to mature. It`s roots grow in taproot formation, spreading into about 30 cm radius and 75 cm deep. The deeper the roots are, the less branched they are. This plant doesn`t require a large amount of water and is able to keep growing without too much intervention. |
</p> | </p> | ||
Line 526: | Line 543: | ||
<h2 class="w3-center w3-panel w3-red"> <span class="w3-badge w3-white">3</span> Plant Transformation:</h2> | <h2 class="w3-center w3-panel w3-red"> <span class="w3-badge w3-white">3</span> Plant Transformation:</h2> | ||
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
− | An abundance of | + | An abundance of research exists that describes the transformation of Chinese cabbage using different agrobacterium strains, presenting 1-3% transformation rates. |
</p> | </p> | ||
<br /> <br /> | <br /> <br /> | ||
Line 532: | Line 549: | ||
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
<br /> <br /> | <br /> <br /> | ||
− | Both female and male sterile strains exist for the Chinese cabbage. | + | Both female and male sterile strains exist for the Chinese cabbage. The protocols for molecular techniques and the creation of hybrid strains are available for this plant. |
</p> | </p> | ||
<p class="w3-large w3-serif"> | <p class="w3-large w3-serif"> | ||
<i class="fa fa-quote-right w3-xxlarge w3-margin-right"></i> | <i class="fa fa-quote-right w3-xxlarge w3-margin-right"></i> | ||
− | " | + | "..…compared to the wild-type line ‘FT,’ the fsm plants exhibited pistil abortion. Whether the fsm mutant was self-pollinated or used as the female parent to accept foreign pollen (wild-type line ‘FT’), the seed setting rates of fsm were both zero. The results showed that the female sterility of fsm was stable." </p> |
<div style="text-align:center"> | <div style="text-align:center"> | ||
Line 547: | Line 564: | ||
</p> | </p> | ||
− | + | ***************************************************************************************** | |
+ | |||
<h2 align="left"> References: </h2> | <h2 align="left"> References: </h2> | ||
<p style="text-align:left"> | <p style="text-align:left"> | ||
Line 598: | Line 616: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
<div class="w3-container" style="width:30%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | <div class="w3-container" style="width:30%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | ||
− | | + | Uptake Rate</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | Roots | + | Roots grow deep and wide. |
</li> | </li> | ||
<li> | <li> | ||
Line 612: | Line 630: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-green" style="width:75%"><span class="w3-badge w3-white">2</span> | + | <div class="w3-container w3-green" style="width:75%"><span class="w3-badge w3-white">2</span> Growth Conditions</div> |
</div> | </div> | ||
<ul> | <ul> | ||
<li> | <li> | ||
− | + | Grows in most parts of the world, requires direct sunlight. | |
</li> | </li> | ||
<li> | <li> | ||
Line 628: | Line 646: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-red" style="width:96%"><span class="w3-badge w3-white">3</span> | + | <div class="w3-container w3-red" style="width:96%"><span class="w3-badge w3-white">3</span> Transformation</div> |
</div> | </div> | ||
Line 644: | Line 662: | ||
<div class="w3-light-grey"> | <div class="w3-light-grey"> | ||
− | <div class="w3-container w3-yellow" style="width:96%"><span class="w3-badge w3-white">4</span> | + | <div class="w3-container w3-yellow" style="width:96%"><span class="w3-badge w3-white">4</span> Sterilization</div> |
</div> | </div> | ||
Line 650: | Line 668: | ||
<li> Known male and female sterile mutants. | <li> Known male and female sterile mutants. | ||
</li> | </li> | ||
− | <li> Known | + | <li> Known CRISPR methods for seedless fruits. |
</li> | </li> | ||
− | <li> | + | <li> Problem of vegetative growths regarding the spread of transgenic plants. |
</li> | </li> | ||
</ul><br /> | </ul><br /> | ||
Line 669: | Line 687: | ||
<br /> <br /> | <br /> <br /> | ||
− | <h2 class="w3-center w3-panel" style="width:100%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> | + | <h2 class="w3-center w3-panel" style="width:100%;background-color:#2196f3a3"> <span class="w3-badge w3-white">1</span> Uptake Rate</h2> |
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
<br /> <br /> | <br /> <br /> | ||
− | Much like the Chinese cabbage, tomato plants have high dioxin uptake in their roots but very poor transfer to shoots through the xylem. | + | Much like the Chinese cabbage, tomato plants have high dioxin uptake in their roots but very poor transfer to shoots through the xylem. The main difference between the two [plants] is higher root uptake in Chinese cabbage, while tomatoes have an easier transformation and longer life expectancy. |
+ | |||
</p> | </p> | ||
Line 681: | Line 700: | ||
− | <h2 class="w3-center w3-panel w3-green"><span class="w3-badge w3-white">2</span> | + | <h2 class="w3-center w3-panel w3-green"><span class="w3-badge w3-white">2</span> Growth Conditions</h2> |
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
Tomato plants come in different sizes and varieties. Tomato plants are perennials, mostly requiring direct sunlight to grow and love warm temperatures, able to grow in most areas of the world. It`s roots form a taproot formation, reaching half a meter to a meter and a half deep and 1 meter in diameter. | Tomato plants come in different sizes and varieties. Tomato plants are perennials, mostly requiring direct sunlight to grow and love warm temperatures, able to grow in most areas of the world. It`s roots form a taproot formation, reaching half a meter to a meter and a half deep and 1 meter in diameter. | ||
Line 690: | Line 709: | ||
<h2 class="w3-center w3-panel w3-red"> <span class="w3-badge w3-white">3</span> Plant Transformation:</h2> | <h2 class="w3-center w3-panel w3-red"> <span class="w3-badge w3-white">3</span> Plant Transformation:</h2> | ||
<p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | <p style="padding-left:90px;padding-right:90px;text-align:justify;line-height:1.5"> | ||
− | Plant transformation using agrobacterium is considered robust, with transformation frequencies of 40%+. On top of that a whole genome sequence, being continuously studied for several decades now | + | Plant transformation using agrobacterium is considered robust, with transformation frequencies of 40%+. On top of that, a whole genome sequence, being continuously studied for several decades now, gives us superb knowledge of tomato transformation possibilities. |
</p> | </p> | ||
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− | A technique for promoting fruit formation without seed creation using | + | A technique for promoting fruit formation without seed creation using CRISPR/Cas9 exists as well as known male and female sterile strains. |
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Revision as of 17:39, 14 October 2018
We created an open source platform aimed at helping researchers and organizations worldwide tackle their dioxin pollution. In our open source page, we present the basic foundations necessary to create a viable transgenic plant based on our research and experiments.
Our open source page features two main programs: our synthetic enzymatic pathway (i.e. optimized gene sequences for each plant, including descriptions), and our proposed plants that are optimal for our pathway.
We chose the plants based on 4 categories: Transformation, dioxin uptake efficiency, sterilization methods and plant durability. We did our best to gather the necessary information to support it using both academic research and verified gardening sites.
Transformation - How many methods are known for the transformation of this plant? How easy and effective are they?
Dioxin uptake efficiency - How well does the plant absorb dioxin from the ground, compared to other plants?
Sterilization methods - With these types of solutions, it is important to be ecologically responsible; releasing genetically engineered plants into the environment is no trivial matter. The ability to sterilize the plants, along with short life expectancies in general, is key for the safe release of transformed plants.
Plant durability - Under what conditions do the plants grow? Where do they grow? Do they grow in regions that are in dire need of solutions to dioxin contaminations?
Cucurbita pepo L. (Pumpkin & Zucchini)
- Deep root systems.
- Zucchini roots grow mainly downward, while pumpkin`s grow mainly outward.
- High uptake values of nutrition from soil.
- Able to absorb dioxins through roots and deliver them throughout the plant (potential for high-speed degradation in the plant).
- Short-season plants, grown in hot seasons.
- Easily grown in most areas of the world.
- Existing transformation methods use agrobacterium.
- Whole-genome sequence doesn`t exist yet.
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1 Uptake Rate
Zucchini plants have been shown to have the most successful uptake mechanisms for PCDD/PCDF's of all plants tested. This includes mechanisms that can translocate dioxins from their roots to their shoot system (including flowers and fruits), as opposed to many other plants that can only absorb dioxins into their roots.
"Plants have been frequently shown to remove POPs from soils (Zhao et al. 2006; Susarla et al. 2002; Macek et al. 2000). The high propensity of selected Cucurbitaceae to extract PCDDs/PCDFs from soil was first reported by Hülster et al. (1994), who found that C. pepo L. fruits contained double the PCDD/PCDF concentrations of other examined plants."
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Fig. 1:
"Mean decreases in total and TEQ PCDD/PCDF concentrations in soil amended with different doses of sewage sludge (A1, A2) and urban sediments (B1–B2) before and after Cucurbita pepo L. cv ‘Atena Polka’ cultivation"3
2 Growth Conditions
Zucchini and pumpkin are very sensitive to cold weather, requires warm temperatures of above 16 degrees Celsius to grow, but to warm of a climate (above 38 degrees) will harm the plant. Zucchini takes about 60 days to mature. By then it produces fruit as long as someone picks them before they rot. Pumpkin requires between 90 to 160 days to mature. They both grow relatively quickly and, as such, have high root-uptake of nutrition from the ground. Both require moderate quantities of water to grow, which may make it more difficult to grow in drier climates; however, pumpkins have been successfully grown in Iraq, for example. Zucchini roots generally extend deeply downward in a taproot formation, while pumpkin roots tend to spread horizontally as well as vertically - most of its nutrients are absorbed from the upper 1/2 meter of the soil.
3 Plant Transformation:
Two-week-old in vitro grown Cucurbita pepo L. intact plants and cotyledons (detached and undetached from the mother-plant) were transformed by Agrobacterium rhizogenes strain NCPPB 1855, grown for 48 h at 25 °C on YMB medium. All infected material formed vigorous hairy roots in about seven days. The transformed roots were successfully grown in liquid MS medium without plant growth regulators for an indefinite number of transfers.
4 Plant Sterility
Triploid plants have larger organs, greater biomass, and strong stress resistance by preserving relatively larger amounts of photosynthetic energy. The undesirable spread of non-native invasive crop and horticultural plants into natural areas can also be reduced or eliminated by the use of triploids, because they tend to be sterile and seedless.
There are few different ways to create triploid plants:
- - Natural selection - triploid plants occur in nature, meaning it is possible to look for the desired plant in nature.
- - Artificial hybridization - by sexual hybridization of different ploidy, one can create a triploid offspring.
- - Endosperm culture in vitro - endosperm is a triploid tissue. Successful regeneration of a plant from an endosperm tissue would result in triploid plant.
References:
1. "Cucurbita pepo L. can be transformed by Agrobacterium rhizogenes" Luigi Sanità di Toppi et al. (1997).
2. "Breeding Triploid Plants: A Review"
Xiling Wang et al. (2016).
3. "Potential for Phytoremediation of PCDD/PCDF-Contaminated Sludge and Sediments Using Cucurbitaceae Plants: A Pilot Study" Magdalena Urbaniak et al. (2016).
4. "A simple method for transient transformation of pumpkin (Cucurbita maxima) seedlings" Francisco Arturo Ramírez-Ortega et al. (2015).
5. "Uptake by roots and translocation to shoots of polychlorinated dibenzo-p-dioxins and dibenzofurans in typical crop plants" Haijun Zhang et al. (2009).
6. "Planting, growing, and harvesting pumpking" The Old Farmer'S Almanac website (2010).
7. "How to Grow Zucchini: A Squash Vocabulary Lesson"
Charity Shumway (2012).
8. "What Is the Life Expectancy of Zucchini Plants?" Karen Carter.
Brassica campestris (Chinese cabbage)
- Roots do not extend deeply or widely relative to other plants.
- High uptake of dioxins in roots.
- Very low transfer of dioxins from roots to shoots.
- Grows in most parts of the world, mostly in temperate-cold areas.
- Grown all year round.
- Abundance of agrobacterium strains known to be effective.
- Whole genome sequenced.
- Susceptible to hybridization.
- Known male and female sterile mutants.
1 Uptake Rate
Although zucchini and pumpkin have showed the best overall uptake of dioxins, primarily showing an extraordinary shoot uptake of dioxins, Chinese cabbage has shown an especially high uptake of dioxins in their roots only according to Table 2. Since our proposed method takes effect in roots as well as the shoots, a high enough root uptake should suffice.
2 Growth Conditions
Chinese cabbage requires cool temperatures, between 7-17 degrees Celsius, to grow and it takes between 50-85 days to mature. It`s roots grow in taproot formation, spreading into about 30 cm radius and 75 cm deep. The deeper the roots are, the less branched they are. This plant doesn`t require a large amount of water and is able to keep growing without too much intervention.
3 Plant Transformation:
An abundance of research exists that describes the transformation of Chinese cabbage using different agrobacterium strains, presenting 1-3% transformation rates.
4 Plant Sterility
Both female and male sterile strains exist for the Chinese cabbage. The protocols for molecular techniques and the creation of hybrid strains are available for this plant.
"..…compared to the wild-type line ‘FT,’ the fsm plants exhibited pistil abortion. Whether the fsm mutant was self-pollinated or used as the female parent to accept foreign pollen (wild-type line ‘FT’), the seed setting rates of fsm were both zero. The results showed that the female sterility of fsm was stable."
** CMS - Cytoplasmic Male Sterility.
*****************************************************************************************References:
1. "Uptake by roots and translocation to shoots of polychlorinated dibenzo-p-dioxins and dibenzofurans in typical crop plants" Haijun Zhang et al. (2009).
2. "Interspecific hybridisation of cytoplasmic male-sterile rapeseed with Oguracytoplasm and Brassica rapa var. pekinensis as a method to obtain male-sterile Chinese cabbage inbred lines" Piotr Kamiński et al. (2016).
3. "Transcriptome Analysis of a Female-sterile Mutant (fsm) in Chinese Cabbage (Brassica campestris ssp. pekinensis)" Shengnan Huang et al. (2017).
4. "SSR and SCAR mapping of a multiple-allele male-sterile gene in Chinese cabbage (Brassica rapa L.)" Feng and Lim YP (2009).
5. "The genome of the mesopolyploid crop species Brassica rapa" Wang X and Zhang Z (Brassica rapa Genome Sequencing Project Consortium, 2011).
6. "Agrobacterium-mediated transformation and regeneration of fertile transgenic plants of chinese cabbage (brassica campestris ssp. pekinensis cv. 'spring flavor')" Jun S 2nd and Paek KH(1995).
7. "Successful genetic transformation of Chinese cabbage using phosphomannose isomerase as a selection marker" Min BW and Harn CH (2007).
9. "Agrobacterium-mediated transformation of cotyledonary explants of Chinese cabbage (Brassica campestris L. ssp. pekinensis)" F.-L, Zhang and M. Watanabe (2000).
9. "HOW TO GROW CHINESE CABBAGE" Steve Albert (2018).
10. "How Deep Do Lettuce Roots Grow?" Teo Spengler.
Lycopersicon esculentum (Tomato)
- Roots grow deep and wide.
- Very low transfer of dioxins from roots to shoots.
- Grows in most parts of the world, requires direct sunlight.
- Grown all year round.
- Perennial plant.
- Very effective agrobacterium transformation (40%+ transformation frequency).
- Whole genome sequenced.
- Known male and female sterile mutants.
- Known CRISPR methods for seedless fruits.
- Problem of vegetative growths regarding the spread of transgenic plants.