Using Genetically Modified Insects to Combat Disease Transmission

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Added on 2023/06/04

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This essay explores the use of genetically modified (GM) insects as a method to inhibit the transmission of diseases such as malaria, Zika virus, dengue fever, and chikungunya. It compares GM techniques to other control methods like pesticides, vaccination, and sanitation, highlighting the environmental benefits of GM over pesticides. The essay details various GM techniques, including gene drive, CRISPR, Homing Endonuclease Genes, sterile insect technique, and RIDL (Release of Insects carrying a Dominant Lethal). It cites successful trials, such as the control of Aedes aegypti mosquitoes in the Cayman Islands and Brazil, while also acknowledging concerns about cost, time, potential mutations, and European perceptions of GM technology. The essay concludes by suggesting the need for further research to improve the viability of GM insect-based disease control.

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Genetically modifying insects to inhibit disease transmission
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Genetically modifying insects to inhibit disease transmission
Different insect spread diseases that can be targeted by GM
Genetic modifications of insects is a technique that involves altering genes of insects to introduce
certain characteristics .Insects have been known to transmit different diseases over the years.
Some of the notable diseases that are transmitted or spread by insects include malaria, Zika virus,
dengue fever and chikungunya virus. Majority of this diseases are spread through the bite of the
female Aedes Aegyptus mosquito since they can be found in blood after infection. Other diseases
caused by insects include tick borne encephalitis which is caused by ticks of the lxodes ricinus
species.
Where the disease occur and how the insects spread them
The Zika virus is one of the new diseases that is sweeping across Brazil. This disease is spread
by the female Aedes aegypti mosquito. This breed of mosquitoes usually lay their eggs near
pools of water, animal dishes and flower pots and they transmit the disease from one person to
another through bites. The Zika virus is usually found in blood one week after infection and this
is the reason why it is possible to be transmitted through the bite of a female Aedes Aegyptus
mosquito. Chikungunya is another disease that occur mainly in Africa and Asia though there
have been reported cases in America from 2000.Just like the Zika virus, this disease is spread by
bites from two species of mosquitoes which include the Aedes albopictus and the Aedes aegypti.
However, it is only the female mosquito of either of the species that spread the virus. Dengue
fever is a condition or disease that is caused by the dengue virus and it occurs in over 110
countries (Adelman, Pledger, & Myles, 2017, p.440). This virus is also spread from one person
to another through the bite of different types of mosquitoes though the principle is the female

Aedes aegypti. Malaria on the other hand is a disease that is found in tropical and sub-tropical
regions. It is spread from one person to another through the bite of the female anopheles
mosquito.
How GM technique compares to other options
There have been different options explored in the treatment of this conditions or diseases that are
spread from one person to another through bites from insects. The different techniques include
vaccination, sanitation and use of pesticides. When compared to use of pesticides, genetically
modification of mosquitoes is an environmental friendly option (Yakob & Walker, 2016,p e148).
Pesticides have been known to be toxic to both human beings and animals in case there is
contact.GM is also an effective method when compared to other physical methods such as use of
mosquito nets. This is because the mosquito nets only shields access of the mosquito to the
human beings but it does not eliminate the dangerous species as GM does. The GM insects have
some short comings when compared to other methods of preventing diseases (Adelman & Tu,
2016, p.220). This is a very expensive technique and wastes a lot of time. There also increased
concerns that GM can lead to mutation and form stronger insects that could pose a new threat of
the diseases. Majority of the governments have ruled pesticides as being safe and therefore there
would be no need of taking risks with genetically modified insects which could undergo
subsequent mutation and transmit other diseases.
What GM involves and what techniques are available
Genetic modification is simply the alteration of genes in the living organisms to come up with
certain desired characteristics. There are different techniques currently available for genetic
modification. Living organisms usually contain a barrier that protects introduction of new DNA

from opposite species (Araújo, Carvalho, Ioshino, Costa-da-Silva, & Capurro, 2015, p.580).
However, during genetic modification, the engineers or the scientists find a way of bridging this
barrier to force the DNA of another species into another the organism that want to be altered.
This can be done either by using bacteria or viruses to infect the insect of desire (Carvalho,
Costa-da-Silva, Lees, & Capurro, 2014, p.s176). Another technique is where the DNA is coated
with small tiny metals pellets and using a special gun to fire them into cells. The other technique
involves injection of the new DNA into the fertilized eggs by using a very fine needle.
There are other GM technologies that are utilized in creating genetically modified insects to
reduce spread of diseases. Gene drive is an example of the technique where modified genes are
introduced into the insect with DNA so that they are inherited by subsequent generations
(Gabrieli, Smidler, & Catteruccia, 2014, p.11). Gene drive also involve CRISPR which is a gene
editing technique that allows scientists to make necessary changes to DNA.
Homing Endonuclease Genes, sterile Insect technique and the release of insects carrying a
dominant lethal (RIDL) are other techniques that are currently available. RIDL was introduced
by British biotech company Oxitec and it involves inserting a lethal gene into an insect using
transgenic technology (Dantas-Torres & Otranto, 2016, p.52). The sterile technique on the other
hand involves the use of radiation sterilized male insects to mate with the female and this
eventually reduce reproduction of the target population thus reducing their population.
Examples of past successful trials and potential future scopes
There are different trials in which GM technique has been successful. One of the cases is the
control of the Aedes aegypti mosquitoes in Cayman Islands. In this exercise, the Release of
insects carrying a dominant lethal (RIDL) using male Aedes aegypti was conducted with the

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objective of preventing dengue fever in the region. The results were quite impressive since there
was 80% suppression of the mosquitoes. The same technique was also used in Brazil and the
population of Aedes aegypti reduced by between 81% and 91% (Taracena et al., 2015, p.3). The
future scope of GM insects looks a bit dim. This is because the European Nation perceives this to
be an expensive, slow and also deters innovation as well as technology transfer. Further research
ought to be carried out in future to make it a better option

. References
Adelman, Z. N., Pledger, D., & Myles, K. M. (2017). Developing standard operating procedures
for gene drive research in disease vector mosquitoes. Pathogens and Global Health, 111(8), 436-
447. doi:10.1080/20477724.2018.1424514
Adelman, Z. N., & Tu, Z. (2016). Control of Mosquito-Borne Infectious Diseases: Sex and Gene
Drive. Trends in Parasitology, 32(3), 219-229. doi:10.1016/j.pt.2015.12.003
Araújo, H., Carvalho, D., Ioshino, R., Costa-da-Silva, A., & Capurro, M. (2015). Aedes aegypti
Control Strategies in Brazil: Incorporation of New Technologies to Overcome the Persistence of
Dengue Epidemics. Insects, 6(2), 576-594. doi:10.3390/insects6020576
Carvalho, D. O., Costa-da-Silva, A. L., Lees, R. S., & Capurro, M. L. (2014). Two step male
release strategy using transgenic mosquito lines to control transmission of vector-borne diseases.
Acta Tropica, 132, S170-S177. doi:10.1016/j.actatropica.2013.09.023
Dantas-Torres, F., & Otranto, D. (2016). Best Practices for Preventing Vector-Borne Diseases in
Dogs and Humans. Trends in Parasitology, 32(1), 43-55. doi:10.1016/j.pt.2015.09.004
Gabrieli, P., Smidler, A., & Catteruccia, F. (2014). Engineering the control of mosquito-borne
infectious diseases. Genome Biology, 15(11). doi:10.1186/s13059-014-0535-7
Taracena, M. L., Oliveira, P. L., Almendares, O., Umaña, C., Lowenberger, C., Dotson, E. M.,
… Pennington, P. M. (2015). Genetically Modifying the Insect Gut Microbiota to Control
Chagas Disease Vectors through Systemic RNAi. PLOS Neglected Tropical Diseases, 9(2),
e0003358. doi:10.1371/journal.pntd.0003358

Yakob, L., & Walker, T. (2016). Zika virus outbreak in the Americas: the need for novel
mosquito control methods. The Lancet Global Health, 4(3), e148-e149. doi:10.1016/s2214-
109x(16)00048-6