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7.3: Disease

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    A disease is just what it says: a “dis” - “ease”; meaning something is keeping you from being at ease, or your normal state. From a system theory approach, disease is a stressor that moves the body out of homeostasis. There are many kinds of diseases that are important to human evolutions. We've already discussed genetic diseases in section 2, but here we are going to look at human variation as a response to infectious disease.

    via GIPHY

    With infectious diseases, the concept of coevolution is important to understand. While humans are evolving, our diseases are also evolving (and unfortunately, usually faster than we do).

    The study of diseases on a large scaled is called epidemiology.

    * Article on the epidemiological transition

    Looking at the history of humanity most of our genetic diseases were dealt with through natural selection. For most of history the most important disease we suffered from was malnutrition. People were more worried about starving to death than anything else. If a small band of hunter-gatherers got a bad infectious disease, they just all died, and took the disease with them. As population density increases we are are exposed to more diseases.

    Most of the selection for disease resistance is at the molecular level. * Watch this example of evolution of immunity:

    Paleopathology

    Paleopathology is the study of the effects of disease on human remains from archaeological sites.

    * “Black death skeletons reveal pitiful life of 14th-century Londoners”

    Altitude Sickness

    Anything that takes us out of our biological comfort zone can cause natural selection. High altitude is associated with several stressors including less available oxygen, cold, and resource scarcity. Highlanders tend to be different than lowlanders, both genetically and culturally.

    Exercise \(\PageIndex{1}\)

    Read Wikipedia's description of altitude sickness

    * Genes found in Tibetans that help them survive high altitude shared with Denisovians

    The Epidemiological Transition

    We can see human history as changes in the prevalence from one class of diseases to another.

    Starvation to Infectious Disease

    As hunter-gatherers the main thing that killed us was starvation. If a typical isolated band of 25-50 people caught a nasty disease, the entire band would die, and the disease would die with it.

    When we started agriculture we increased population density, and became sedentary, and basically started living in our own shit, not to mention that of all our domesticated animals. Agriculture was a big trade off: we had more food and didn't starve as much, but we had to deal with more infectious diseases. Most archaeological research shows that when agriculture was introduced the population went up, but the health and life expectancy of the individual went down.

    * "The Worst Mistake In The History Of The Human Race" by Jared Diamond, Prof. UCLA School of Medicine Discover-May 1987, pp. 64-66

    Zoonosis

    A vector in epidemiology refers to something that transfers the disease to the human. Many infectious diseases are transferred to humans through other animals.

    image233.gif

    Figure \(\PageIndex{1}\) - "Little Boy & Pig"

    One reason bats have been an important vector in diseases like Ebola is because they can fly long distances and spread the pathogens to a wide geographic area. The other reason has to do with understanding our taxonomy, our place in the animal kingdom. As mammals, bats are so similar to us that they provide almost identical environments for the pathogens to live, evolve, and then easily cross over to humans, with only small modifications necessary. This is same reason why it's especially bad for humans to eat primates. For example, earthworms get all kinds of diseases, but their anatomy is so different from ours, that you can eat a worm and the pathogens that have evolved to live in earthworms won't be able to live inside of you.

    Mosquitos don't get the same diseases as we do, they function like a shared needle, in passing blood and pathogens from one person to another.

    * Mosquitos decide who to bite based on your genetics

    Aedes_aegypti.jpg

    Figure \(\PageIndex{2}\) - Female Aedes aegypti mosquito used in the experiment to test attractiveness to odors from the hands of identical and non-identical twins. doi:10.1371/journal.pone.0122716.g001 (CC BY)

    Infection to Lifestyle Diseases

    We didn't evolve to sit motionless at a computer screen for hours a day. Millions of years of evolution set us up to be climbing or running around gathering and hunting for food. And for most of that time there wasn't enough food to go around. When food is too fast and too cheap we get fat. High density calories were once rare and expensive.

    Most hunter-gatherers were getting most of their calories from fruits and vegetables. Meat was scarce, and the rest hadn't been invented yet.

    When medicine and abundant food kept us fed and free of infectious disease, we started dying from type II diabetes and heart disease.

    The idea of a "paleo diet" is to try to recreate the pre-agriculture diet.

    * Too tired to chew; meat and evolution

    * Article on Paleo diet

    * Graph of relative cost of food worldwide

    The Evolution of Infectious Disease: Pathogens Evolve Too

    Remember that when we take antibiotics, we don't kill everything, and when the new population multiplies, natural selections means that they tend to have the variations that make them resistant to the antibiotics. You might expect this evolution to be slow because the variation from sexual reproduction (meiosis) is mostly absent, but you have to take into account the length of time of each generation. Human evolution is slow because it takes about 20 years from when you're born to when you reproduce, whereas baby E. coli bacteria are fissioning (mitosis) about 20 minutes after their born. Go back and watch the video of bacteria evolving resistance in the Mutation section.

    AntibioticsNationalGoalsinfo.png

    Figure \(\PageIndex{3}\) - "National Goals for Reducing Inappropriate Antibiotic Use in Outpatient Settings" 2016 Pew Charitable Trust, Antibiotic Resistance Project

    * 2014 World Health Organization report on antimicrobial resistance

    * New Type of Antibiotic Resistance Raises Alarm

    * Understanding sex, drugs and HIV

    But not all pathogens are evolving faster that our culture can keep up with. Many viruses are slow to change, and we can actually get ahead of them if we all work together.

    Should you vaccinate your child?

    YES!

    It's amazing to think of humans actually driving some viruses into extinction. Let's pat ourselves on the back! Vaccines have an exponential effect because of a phenomenon known as "herd immunity". When the percentage of immunized people reaches a critical level, there is hardly anyone around to spread the disease to.

    330px-Herd_immunity.svg.png

    Figure \(\PageIndex{4}\) - Herd Immunity by Tkarcher (CC BY-SA 4.0)

    * Vaccines and Autism: A Tale of Shifting Hypotheses

    Pharmagenomics

    Even though pathogens continue to evolve, medicine seems to be getting better because our cultural progress continues at a fast pace too. One area of growth is applying our understanding of genetics to medicine and develop individualized treatments based on a patient's genome.

    * Pharmagenomics and personalized medicine

    * Obama's initiative for Precision Medicine

    Lactose Intolerance

    Look back at our discussion of lactase persistence as a Mendelian trait. Lactase persistence means you keep producing lactase as an adult, lactose intolerance is the opposite, you can't digest milk In this section we are examining the same trait, except that we are trying to explain how natural selection may have caused it. What are the selective advantages and disadvantages to being able to digest milk as an adult? How does culture effect our biology? It's amazing to think of Nigeria the different rates of lactose tolerance of different people within the same country.

    Notes

    DENNIS O'NEIL ON Nutritional Adaptation

    Article on the genetics of smell

    Article on European Lactose Intolerance

    Third epidemiological transition: new infectious diseases

    New diseases are coming back with a vengeances.

    Imagination Action

    • Tell MacDonalds to stop overusing antibiotics
    • Tell the FDA to ensure appropriate antibiotic use in animal agriculture

    Vocabulary

    • endemic
    • epidemic
    • epidemiological
    • dizygotic
    • infectious
    • lactase
    • lactose
    • lifestyle disease
    • monozygotic
    • pandemic
    • pathogen
    • vector
    • zoonotic

    This page titled 7.3: Disease is shared under a CC BY-NC-ND 4.0 license and was authored, remixed, and/or curated by Arnie Daniel Schoenberg via source content that was edited to the style and standards of the LibreTexts platform.

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