In Speculative Evolution, we envisioned how species could be further developed to increase their resilience based on scientific publications on synthetic biology, genetic engineering and robotics, and formulated text prompts to create AI-generated images using DALL-E. As a result, each speculative species in the environment has a backstory rooted in real-life scenarios.
| Wheat | |
| 2019 | genetic modification for wheat improvement International trade by Borisjuk et al., 2019 |
| 2054 | 1 |
Lineage of the 31 species from a total of 44
Samsung G955F, Android 9, Zurich, Switzerland (54-1)
Samsung S928B, Android 14, Belo Horizonte, Brazil (54-1-1)
, Android 9, London, Canada (54-12)
, Android 9, London, Canada (54-12-1)
Samsung G955F, Android 9, Zurich, Switzerland (54-2)
Samsung G955F, Android 9, Stuttgart, Germany (54-2-1)
, Android 13, Statesville, United States (54-2-1-1)
, Android 11, Alor Star, Malaysia (54-2-1-1-1)
Samsung G986U1, Android 13, Monterrey, Mexico (54-2-1-1-1-1)
Samsung G955U, Android 9, Basel, Switzerland (54-2-1-2)
Samsung G955F, Android 9, Limassol, Cyprus (54-2-1-3)
Samsung G955F, Android 9, Lucerne, Switzerland (54-2-1-3-1)
Samsung G990E, Android 14, Gravataí, Brazil (54-2-2)
Samsung A336M, Android 13, Santiago, Chile (54-2-3)
Samsung G955U, Android 9, Xi'an, China (54-2-3-1)
Samsung G955U, Android 9, Xi'an, China (54-2-3-1-1)
Samsung G955F, Android 9, Zurich, Switzerland (54-3)
Samsung A546W, Android 14, Belleville, Canada (54-3-1)
Samsung G955F, Android 9, Lucerne, Switzerland (54-3-1-1)
Samsung G955F, Android 9, Lucerne, Switzerland (54-3-2)
Samsung G955F, Android 9, Lucerne, Switzerland (54-3-2-1)
Samsung G955F, Android 9, Zurich, Switzerland (54-4)
, Android 13, Statesville, United States (54-4-1)
Samsung A546E, Android 14, Jundiaí, Brazil (54-4-2)
Huawei HRY-LX1T, Android 10, Rome, Italy (54-4-3)
Samsung G955U, Android 9, Basel, Switzerland (54-4-3-1)
Samsung G955F, Android 9, Berlin, Germany (54-5)
Samsung G955U, Android 9, , China (54-5-1)
Samsung G955F, Android 9, Lucerne, Switzerland (54-5-1-1)
, Android 14, Bauru, Brazil (54-7)
Samsung G955U, Android 9, , China (54-7-1)
Genetic Modification for Wheat Improvement: From Transgenesis to Genome Editing.
Borisjuk N, Kishchenko O, Eliby S, Schramm C, Anderson P, Jatayev S, Kurishbayev A, Shavrukov Y. Biomed Res Int. 2019 Mar 10;2019:6216304. doi: 10.1155/2019/6216304. PMID: 30956982; PMCID: PMC6431451.
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6431451/
Abstract
To feed the growing human population, global wheat yields should increase to approximately 5 tonnes per ha from the current 3.3 tonnes by 2050. To reach this goal, existing breeding practices must be complemented with new techniques built upon recent gains from wheat genome sequencing, and the accumulated knowledge of genetic determinants underlying the agricultural traits responsible for crop yield and quality. In this review we primarily focus on the tools and techniques available for accessing gene functions which lead to clear phenotypes in wheat. We provide a view of the development of wheat transformation techniques from a historical perspective, and summarize how techniques have been adapted to obtain gain-of-function phenotypes by gene overexpression, loss-of-function phenotypes by expressing antisense RNAs (RNA interference or RNAi), and most recently the manipulation of gene structure and expression using site-specific nucleases, such as CRISPR/Cas9, for genome editing. The review summarizes recent successes in the application of wheat genetic manipulation to increase yield, improve nutritional and health-promoting qualities in wheat, and enhance the crop's resistance to various biotic and abiotic stresses.
Comparison of parameters of agrobacterial and biolistic transformation.
| Parameters | Agrobacterium-mediated transformation | Biolistic transformation | References |
|---|---|---|---|
| Genotype dependency | High | Less | 5 |
|
| |||
| Stability of expression of transgenes | High | High for Minimal Expression Cassettes (MEC), lower for plasmids | 6,7 |
|
| |||
| Copy number of inserts | Around 50% single copy; Depends on the strain and transformation conditions | <50%; Depends on the amount of DNA/shot. More multicopy inserts | 7,8 |
|
| |||
| Integration of the new genes | Random. More than one locus | Random. Often many at the same locus | 6 |
|
| |||
| Maximum transformation frequency (TF) for wheat (per 100 embryos treated) | Up to 90% | >70% | 8,9 |
|
| |||
| Complexity of the transformation procedure in wheat | Simpler. Usually requires aseptic conditions | More complex. Requires aseptic conditions and a Biolistic Gun | 8,10 |
|
| |||
| Main explants in wheat | Immature embryos | Immature embryos | 8,10 |
|
| |||
| Complexity of vector construct preparation, co-transformation | More complex | Simpler | 11 |
|
| |||
| Maximum sizes of transferred inserts published | Up to 200 Kb | 150–164 Kb | 12,14 |
|
| |||
| Transfer of Т-DNA borders | Yes | No (for MEC) | 15 |
|
| |||
| Transfer of vector DNA | Possible | No (for MEC); Yes (for plasmids) | 15 |
|
| |||
| Transfer of bacterial chromosomal DNA | Possible | No (for MEC) | 16 |
|
| |||
| Marker free transformation in wheat | Possible | Possible | 17,19 |
|
| |||
| In planta transformation in wheat | Possible | Possible | 20,22 |
|
| |||
| Delivery of RNA, proteins, nanoparticles and dyes | No | Possible | 23 |
|
| |||
| Transformation of chloroplasts and mitochondria | No | Possible | 24,25 |
|
| |||
| Transient gene expression in different tissues and organs of plants | Efficient for limited number of plant species | Efficient | 26,28 |