There have been numerous arguments for and against the use of genetically modified organisms, GMOs, in many quarters. While genetic engineering has been part of drug manufacturing for a long time, it is the use of these techniques in food production that appears to be generating a lot of jitters. Transgenic organisms appear to generate even more controversy owing to the fact that they have genetic material obtained from other species. In a bid to get safer products, researchers are now considering using a genetically engineered organelle.
For a long time, nuclear transformation has been the main technique used in genetic modification. This is, however, now changing as researchers look away from this structure and consider other organelles within the plant cell. The most ideal alternatives that have emerged are mitochondria and chloroplasts. Mitochondria are found both in animal and plant cells while chloroplasts are only present in green plants.
Mitochondria are one of the most important organelles in a cell. Without them, cells can only survive for a limited duration of time. This is because they are the powerhouse of cells and provide energy required for various biochemical reactions that are needed by the cell. Just like the nucleus, mitochondria possess their own genome. This genome is smaller that what is found in the nucleus.
A popular theory that has been advanced to explain the existence of mitochondria proposes that before they evolved fully, mitochondria existed as independent, primitive, unicellular organisms. As evolution occurred over many years, part of they lost their genome and they could no longer exist on their own. They, therefore, entered the cell and established a symbiotic relationship. This theory also attempts to explain the presence of a genome in chloroplasts.
Chloroplasts are organelles found in green plants. They are mostly involved in a process known as photosynthesis which entails food production in the presence of energy derived from sunlight. Other important functions include synthesis of amino and fatty acids and mediation of cellular immune responses. Chloroplasts have a DNA that is often arranged in circular pattern. This DNA is usually inherited by daughter cells after cell division and thus modifications made on it are similarly inherited.
Genome modification involves several steps. The first is gene isolation. This is where the desired gene is identified and obtained either from another cell or by synthesis. Several copies of genes have been studied and isolated and are now available in the genetic library. This may serve as an alternative source. Addition of various elements such as promoter and terminator regions makes the gene active.
The next step involves insertion of the isolated gene into an organelle (mitochondria or chloroplast). If the targeted cell is a bacterium, processes such as electric shocking and thermal stimulation may be required. In animal cells, the most common technique is known as microinjection. Those used in plants include antibacterial mediated recombination, electroporation and biolistics among others.
Insertion of a genetic material into one cell only achieves a change in this cell. The next step is therefore to facilitate regeneration of the entire organism from this single cell. The process used for this in plants is known as tissue culture. In animals the cells used are usually stem cells so these would subsequently undergo cell division and cell growth.
For a long time, nuclear transformation has been the main technique used in genetic modification. This is, however, now changing as researchers look away from this structure and consider other organelles within the plant cell. The most ideal alternatives that have emerged are mitochondria and chloroplasts. Mitochondria are found both in animal and plant cells while chloroplasts are only present in green plants.
Mitochondria are one of the most important organelles in a cell. Without them, cells can only survive for a limited duration of time. This is because they are the powerhouse of cells and provide energy required for various biochemical reactions that are needed by the cell. Just like the nucleus, mitochondria possess their own genome. This genome is smaller that what is found in the nucleus.
A popular theory that has been advanced to explain the existence of mitochondria proposes that before they evolved fully, mitochondria existed as independent, primitive, unicellular organisms. As evolution occurred over many years, part of they lost their genome and they could no longer exist on their own. They, therefore, entered the cell and established a symbiotic relationship. This theory also attempts to explain the presence of a genome in chloroplasts.
Chloroplasts are organelles found in green plants. They are mostly involved in a process known as photosynthesis which entails food production in the presence of energy derived from sunlight. Other important functions include synthesis of amino and fatty acids and mediation of cellular immune responses. Chloroplasts have a DNA that is often arranged in circular pattern. This DNA is usually inherited by daughter cells after cell division and thus modifications made on it are similarly inherited.
Genome modification involves several steps. The first is gene isolation. This is where the desired gene is identified and obtained either from another cell or by synthesis. Several copies of genes have been studied and isolated and are now available in the genetic library. This may serve as an alternative source. Addition of various elements such as promoter and terminator regions makes the gene active.
The next step involves insertion of the isolated gene into an organelle (mitochondria or chloroplast). If the targeted cell is a bacterium, processes such as electric shocking and thermal stimulation may be required. In animal cells, the most common technique is known as microinjection. Those used in plants include antibacterial mediated recombination, electroporation and biolistics among others.
Insertion of a genetic material into one cell only achieves a change in this cell. The next step is therefore to facilitate regeneration of the entire organism from this single cell. The process used for this in plants is known as tissue culture. In animals the cells used are usually stem cells so these would subsequently undergo cell division and cell growth.
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