What is the Difference Between Cisgenesis and Intragenesis?
🆚 Go to Comparative Table 🆚Cisgenesis and intragenesis are genetic modification techniques that involve the transfer of genetic material within the same species or between crossable species. They were developed as alternatives to conventional transgenesis, which involves the transfer of genes between different species, to address safety concerns, environmental risks, and health issues associated with the presence of foreign DNA. The key differences between cisgenesis and intragenesis are:
- Cisgenesis: In this technique, a complete copy of a natural gene with its native promoter, introns, and terminator sequences is introduced into a plant from a crossable species. The original genetic makeup is maintained, and the gene of interest has its own promoter and terminator.
- Intragenesis: This technique involves the transfer of a gene with combined regulatory elements from the same species or a closely related species into the target plant. In contrast to cisgenesis, intragenesis can change the vigor of the new plant. Intragenesis allows for the use of new gene combinations created by in vitro rearrangements of functional genetic elements.
Both cisgenesis and intragenesis rely on genetic material from members of the same gene pool or genes from sexually compatible species, which is less likely to trigger public concern compared to transgenesis. However, future laws for cisgenic and intragenic crops may need to be clarified, as public acceptance of these techniques is currently higher than that of transgenic crops.
Comparative Table: Cisgenesis vs Intragenesis
Cisgenesis and intragenesis are two alternative concepts to transgenesis, both taking place between crossable species. Here is a table comparing the differences between the two:
| Feature | Cisgenesis | Intragenesis |
|---|---|---|
| Definition | Cisgenesis refers to the genetic modification in which a native gene is introduced from a crossable species with its own promoter and terminator. | Intragenesis refers to the genetic modification in which a gene with combined regulatory elements is introduced from a crossable species. |
| Gene Modification | Genes are introduced without any change to the DNA sequence, and the genes have their native promoter, introns, and terminator sequences. | Genes can be designed using genetic elements from other plants with the same sexually compatible species, or even from the species itself. |
| Original Genetic Makeup | The original genetic makeup is maintained. | The original genetic makeup is not maintained or retained. |
| Environmental and Health Concerns | There are lesser concerns about the safety of the environment and human health compared to intragenesis. | There are deep concerns about the safety of the environment and human health due to the modification of regulatory elements. |
| Vigor of the New Plant | The vigor of the new plant is not changed. | The vigor of the new plant can be changed due to gene influx from wild relatives. |
In summary, cisgenesis involves introducing genes without altering their DNA sequence and maintaining the original genetic makeup, while intragenesis allows for the combination of regulatory elements from different species or even from the same species itself, potentially altering the plant's vigor and raising concerns about environmental and human health safety.
- Cisgenesis vs Transgenesis
- Gametogenesis vs Embryogenesis
- Metagenesis vs Metamorphosis
- Anagenesis vs Cladogenesis
- Meiosis vs Gametogenesis
- Sporogenesis vs Gametogenesis
- Cytogenetics vs Molecular Genetics
- Transgenesis vs Selective Breeding
- Genetic Engineering vs Cloning
- Interchromosomal vs Intrachromosomal Recombination
- Genetics vs Embryology
- Chimeric vs Transgenic Organisms
- Gene Conversion vs Crossover
- Introns vs Exons
- Neoteny vs Progenesis
- Histogenesis vs Morphogenesis
- Cytoplasmic Inheritance vs Nuclear Inheritance
- Intragenic vs Extragenic Suppressor Mutation
- Transformation vs Transduction