The Skin Microbiome and Malaria: Difference between revisions
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<br> The skin is the largest organ in the body, and constitutes over 1.8 square meters of surface area in which microbes can form habitats <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. Bacteria, fungi, viruses, and microbial eukaryotes are all common inhabitants of this interface with the outside environment. Similar to any ecosystem, the skin microbiome contains symbiotic organisms of many different natures – many are harmless, others are beneficial to human health, and some are pathogenic and facilitate disease. <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref> <br> | <br> The skin is the largest organ in the body, and constitutes over 1.8 square meters of surface area in which microbes can form habitats <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. Bacteria, fungi, viruses, and microbial eukaryotes are all common inhabitants of this interface with the outside environment. Similar to any ecosystem, the skin microbiome contains symbiotic organisms of many different natures – many are harmless, others are beneficial to human health, and some are pathogenic and facilitate disease. <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref> <br> | ||
<br> The overall environment of the human skin is typically cool in temperature and slightly acidic <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. However, taking into account the many regions of folds, invaginations, and hair, specific habitats can vary widely between regions of the body. This is especially true in and around the sweat glands. For example, sebaceous glands promote growth of facultative anaerobes such as <i>Propionibacterium acnes</i> due to their oxygen-poor environment <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. <br> | <br> The overall environment of the human skin is typically cool in temperature and slightly acidic <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. However, taking into account the many regions of folds, invaginations, and hair, specific habitats can vary widely between regions of the body. This is especially true in and around the sweat glands. For example, sebaceous glands promote growth of facultative anaerobes such as <i>Propionibacterium acnes</i> due to their oxygen-poor environment <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. <br> | ||
<br> Relative humidity, temperature, and light also varies widely among body regions. Unsurprisingly, these effects can exert great influence on bacterial composition. The skin microbe <i>S. aureus</i> flourishes in the axillary and groin regions, both of which are high humidity and temperature, and low in light exposure <ref>[http://www.ncbi.nlm.nih.gov/pubmed/2064946 Rennie et al (1991). "In-vitro and in-vivo studies of human axillary odour and the cutaneous microflora."]</ref>. As such, <i>S. aureus</i> is able to grow in high proportions in these environments. On the other hand, most bacterial strains are not able to grow as successfully in dry and open regions such as the arms and legs. <br> | |||
<br>Considering the influence of topography, temperature, humidity, light, sweat gland, and washing, it is difficult to describe a single, overarching microbiome within an individual’s skin. Rather, the skin microbiome can be thought of as several smaller ecosystems, each of which applies its own specific selection pressures. For example, the scalp is high in proportions of sebaceous glands, which strongly selects for facultative anaerobes and lipophiles such as <i>Propionibacterium</i> <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. This strong selection pressure results in a relatively low species diversity around the sebaceous glands. In moist regions such as the gluteal crease or sole of the foot, <i>Staphylococcus</i> and <i>Corynebacterium</i> tend to dominate, as they are adept at metabolizing the lipids and proteins present in apocrine sweat <ref>[http://www.ncbi.nlm.nih.gov/pubmed/21407241 Grice, E & Segre, J (2016). "The skin microbiome."]</ref>. <br> | |||
<br> While dry, desiccated skin such as that of the arms or legs tends to support less-abundant microbial life than warm, moist regions, these areas provide the greatest levels of bacterial diversity throughout the human skin microbiome. One hypothesis for this phenomenon is that the lack of heat and humidity prevents any single bacterial species from flourishing and thus dominating other species, allowing for smaller proportions of many different bacteria to remain. <ref>[http://www.ncbi.nlm.nih.gov/pubmed/2064946 Rennie et al (1991). "In-vitro and in-vivo studies of human axillary odour and the cutaneous microflora."]</ref> <br> | |||
==Section 2== | ==Section 2== | ||
Revision as of 14:26, 25 April 2016
Introduction
By Aldis Petriceks
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Malaria is a deadly disease caused by the protozoan Plasmodium, and spread through mosquito bites. [1] The most common ailments are fever, chills, and flu-like symptoms which typically begin within a month of infection [2]. Other symptoms include headache, vomiting, jaundice, shivering, and joint pain. The most notable sign of a malaria infection is paroxysm – which includes cycles of cold and shivering followed by fever and sweating. While immediate treatment can typically facilitate a full recovery, those without access to medical care can fall fatal to the disease within days. There are currently 3.4 billion people living in high-risk areas, which led to 500,000 deaths from malaria in 2013 alone (CDC). The majority of these deaths occur in underdeveloped tropical and sub-tropical countries, which in turn incur the bulk of the $12 billion USD yearly cost associated with fighting the disease.
Malaria progresses in two stages. In the first stage, the Plasmodium parasite (in sporozoite form) is injected into the host bloodstream by a mosquito vector, where sporozoites then travel to the liver [3]. Once inside liver cells, these sporozoites spend the next 5-16 days dividing at rapid rates into haploid merozoites. Merozoites build-up in the liver cells causes cell rupture, which then releases the merozoites back into the bloodstream. This begins the second stage of the disease, where the parasites infect red blood cells, undergo many cycles of asexual reproduction, and cause their new host cells to rupture as well, further propagating merozoite production. Infection and rupture cycles repeat every 1-3 days, which manifest themselves in the shivering and fever cycles mentioned above [4].
While the most commonly-known risk factors for malaria are geographic location, socioeconomic level, and lack of proper medical care, research suggests that an individual’s skin microbiome can heavily influence attractiveness to malaria-carrying mosquitoes [5]. Odorous chemical cues are key to mosquito orientation and landing during host location, and skin flora play a large role in the process by affecting human odor production. Specifically, these microbes metabolize lipids and other compounds in naturally odorless sweat, producing volatile odor compounds attractive to anthropophilic mosquitoes [6]. Skin bacteria vary widely in their metabolic pathways, and thus have differing volatile odor productions. As such, composition of skin flora can have large effects on host location in such mosquitoes.
The Skin As An Ecosystem
The skin is the largest organ in the body, and constitutes over 1.8 square meters of surface area in which microbes can form habitats [7]. Bacteria, fungi, viruses, and microbial eukaryotes are all common inhabitants of this interface with the outside environment. Similar to any ecosystem, the skin microbiome contains symbiotic organisms of many different natures – many are harmless, others are beneficial to human health, and some are pathogenic and facilitate disease. [8]
The overall environment of the human skin is typically cool in temperature and slightly acidic [9]. However, taking into account the many regions of folds, invaginations, and hair, specific habitats can vary widely between regions of the body. This is especially true in and around the sweat glands. For example, sebaceous glands promote growth of facultative anaerobes such as Propionibacterium acnes due to their oxygen-poor environment [10].
Relative humidity, temperature, and light also varies widely among body regions. Unsurprisingly, these effects can exert great influence on bacterial composition. The skin microbe S. aureus flourishes in the axillary and groin regions, both of which are high humidity and temperature, and low in light exposure [11]. As such, S. aureus is able to grow in high proportions in these environments. On the other hand, most bacterial strains are not able to grow as successfully in dry and open regions such as the arms and legs.
Considering the influence of topography, temperature, humidity, light, sweat gland, and washing, it is difficult to describe a single, overarching microbiome within an individual’s skin. Rather, the skin microbiome can be thought of as several smaller ecosystems, each of which applies its own specific selection pressures. For example, the scalp is high in proportions of sebaceous glands, which strongly selects for facultative anaerobes and lipophiles such as Propionibacterium [12]. This strong selection pressure results in a relatively low species diversity around the sebaceous glands. In moist regions such as the gluteal crease or sole of the foot, Staphylococcus and Corynebacterium tend to dominate, as they are adept at metabolizing the lipids and proteins present in apocrine sweat [13].
While dry, desiccated skin such as that of the arms or legs tends to support less-abundant microbial life than warm, moist regions, these areas provide the greatest levels of bacterial diversity throughout the human skin microbiome. One hypothesis for this phenomenon is that the lack of heat and humidity prevents any single bacterial species from flourishing and thus dominating other species, allowing for smaller proportions of many different bacteria to remain. [14]
Section 2
Include some current research, with at least one figure showing data.
Mosquito-Attracting Skin Bacteria
Section 4
Conclusion
References
- ↑ CDC, (2016). "Malaria"
- ↑ Caraballo, H (2014). "Malaria, Dengue, and West Nile Virus"
- ↑ NIAID (2016). "Malaria"
- ↑ NIAID (2016). "Malaria"
- ↑ Carde, H & Gibson, G (2016). "Host finding by female mosquitoes: mechanisms of orientation to host odours and other cues."
- ↑ Olanga et al (2016). "Attraction of Anopheles gambiae to odour baits augmented with heat and moisture."
- ↑ Grice, E & Segre, J (2016). "The skin microbiome."
- ↑ Grice, E & Segre, J (2016). "The skin microbiome."
- ↑ Grice, E & Segre, J (2016). "The skin microbiome."
- ↑ Grice, E & Segre, J (2016). "The skin microbiome."
- ↑ Rennie et al (1991). "In-vitro and in-vivo studies of human axillary odour and the cutaneous microflora."
- ↑ Grice, E & Segre, J (2016). "The skin microbiome."
- ↑ Grice, E & Segre, J (2016). "The skin microbiome."
- ↑ Rennie et al (1991). "In-vitro and in-vivo studies of human axillary odour and the cutaneous microflora."
Authored for BIOL 238 Microbiology, taught by Joan Slonczewski, 2016, Kenyon College.
