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- All Subjects: tissue regeneration
- Creators: Bond, Angela
- Creators: Gile, Gillian
- Member of: Barrett, The Honors College Thesis/Creative Project Collection
Description
The non-native mosquito Aedes aegypti has become a common nuisance in Maricopa county. Associated with human settlement, Ae. aegypti is known to reproduce in standing water sources both indoors and outdoors, within vessels such as tires, flowerpots, and neglected swimming pools (Jansen & Beebe, 2010). Ae. aegypti and the related Ae. albopictus are the primary vectors of the arboviral diseases chikungunya, Zika, yellow fever and dengue. Ae. aegypti tends to blood feed multiple times per gonotrophic cycle (cycle of feeding and egg laying) which, alongside a preference for human blood and close association with human habitation, contributes to an increased risk of Ae. aegypti borne virus transmission (Scott & Takken, 2012). Between 2010-2017, 153 travel-associated cases of dengue were reported in the whole of Arizona (Rivera et al., 2020); while there have been no documented locally transmitted cases of Aedes borne diseases in Maricopa county, there are no apparent reasons why local transmission can’t occur in the future via local Aedes aegypti mosquitoes infected after feeding from travelling viremic hosts. Incidents of local dengue transmission in New York (Rivera et al., 2020) and Barcelona (European Center for Disease Control [ECDC], 2019) suggest that outbreaks of Aedes borne arbovirus’ can occur in regions more temperate than the current endemic range of Aedes borne diseases. Further, while the fact that Ae. aegypti eggs have a high mortality rate when exposed to cold temperatures limits the ability for Ae aegypti to establish stable breeding populations in temperate climates (Thomas, Obermayr, Fischer, Kreyling, & Beierkuhnlein, 2012), global increases in temperature will expand the possible ranges of Ae aegypti and Aedes borne diseases.
ContributorsHon, Ruiheng (Author) / Paaijmans, Krijn (Thesis director) / Bond, Angela (Committee member) / Angilletta, Michael (Committee member) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2020-05
Description
Tissue regeneration is a complex process that activates both developmental and metabolic signaling pathways (Kashio & Miura, 2020). The wing imaginal disc in Drosophila melanogaster has been invaluable in discerning what pathways are activated during tissue regeneration, which is typically done by genetically or physically wounding the wing disc and using fluorescent markers to track different signals. However, despite its importance in other regeneration contexts (Tafesh-Edwards & Eleftherianos, 2020), immune signaling has not been well studied in this tissue. Furthermore, what we do know about tissue regeneration and immune signaling is specific to apoptotic cellular death, less is known about other types of cellular death, such as necrotic cellular death and the consequent signaling systems that result from necrosis. Drosophila have an open immune system and only possess innate immunity (Pastor-Pareja et al., 2008), making them an ideal model to study hemocyte involvement in tissue regeneration. Hemocytes are equivalent to blood cells in vertebrates, and are involved in immunological response (Kurucz et al., 2003). In this work, we observed hemocyte accumulation during injury-induced regeneration. Cellular damage was induced using a genetic ablation system known as DUAL Control, with hemipterous CA and GluR1 used to induce apoptotic and necrotic cell death respectfully. We have discovered that while hemocytes are recruited to the wing disc upon both apoptotic and necrotic injury, necrotic tissue has more hemocytes adhered than apoptotic tissue. The difference in adherence could be due to basement membrane integrity being damaged more severely in necrotic discs than apoptotic discs. Our results show that hemocytes are attracted to wing discs that have undergone necrotic damage, indicating that the immune system plays some sort of role in necrotic cellular death. Though the immune response to different types of tissue damage in Drosophila is much simpler than in vertebrate models, there are many similarities between the two, and could lead to research involving human immune signaling as it pertains to regeneration.
ContributorsZustra, Ayla (Author) / Harris, Robin (Thesis director) / Gile, Gillian (Committee member) / Barrett, The Honors College (Contributor) / School of Life Sciences (Contributor)
Created2022-05