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Printable Handouts
Navigable Slide Index
- Introduction
- Pleiotropy as a Biologic Rubik’s Cube
- The origins of life (1)
- The origins of life (2)
- Role of cholesterol in eukaryotic cell membranes
- From a unicellular state to Einstein
- Astronomy before and after relativity theory
- The ups and downs of oxygen over time
- Examples of pleiotropy
- Rat alpha-tropomyosin heterogeneity
- PTHrP pleiotropy
- Lipodystrophies of skin and brain
- Homologies in skin and lung cell physiology
- Host defense, coat color and asthma
- Type IV collagen pleiotropy
- Common gene for lung, thyroid and pituitary
- Apo E4, diarrhea and Alzheimer’s disease
- Aging as antagonistic pleiotropy
- The alveolus and glomerulus are homologous
- Integration of lung, pituitary, adrenal physiology
- Phylogenetic parallelisms
Topics Covered
- Pleiotropy as a Rubik’s Cube ('Repurposing' of genes in response to evolution)
- Complex physiologic phenotypes as homologs of the unicellular cell membrane
- Driving factors for 'repurposing' of genes
- Examples of pleiotropic 'repurposing' of genes
- Aging vs. ‘antagonistic pleiotropy’
- Pleiotropy as the basis for endothermy
Talk Citation
Torday, J.S. (2016, October 31). Pleiotropy - cellular-molecular evolution in action [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 21, 2024, from https://doi.org/10.69645/LFAV7219.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. John S. Torday has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Other Talks in the Series: Evolutionary Physiology
Transcript
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0:00
Pleiotropy: Cellular-Molecular
Evolution in Action.
My name is John Torday.
This lecture is one
in the series of lectures
on evolutionary physiology.
0:11
Pleiotropy occurs
when one gene is used
for several seemingly
unrelated purposes,
not unlike manipulating
a Rubik's cube
with a gear pictured
on one of its faces,
showing up on other faces
of the cube as shown here.
0:27
Yet we know that all the genes
of the organism
are present in the zygote
and are distributed throughout
during embryogenesis.
So there are underlined
principles
that may account
for the pleiotropisms.
Shown here are the origins
for the first principles
of evolution,
which could
hypothetically dictate
where in house
such pleiotropy genes
would be located.
0:51
Such evolved pleiotropic traits
had their mechanistic origins
in such first principles
and then progressed
to form the various complex
traits of physiology
with reference to those
principles as evolution.
1:05
At the molecular level,
the functional evolution
of such traits
can be traced in a way
that cholesterol
has been exploited
by eukaryotes.
Starting with its synthesis
in response
to the rising levels of oxygen
in the atmosphere shown in A,
generating cholesterol
by a biogenetic pathway
require 11 molecules of oxygen
for 1 molecule of cholesterol
shown in B.
The integration of cholesterol
into the cell membranes
of eukaryotes
facilitated evolution
due to the thinning
of the cell membrane.
Increasing oxygenation,
metabolism, and locomotion,
the three principles
of vertebrate evolution.
Subsequently, cholesterol
evolved to form lipid rafts
in the cell membrane
as the infrastructure
of cell surface receptors
which ultimately evolved
the endocrine system.
Cholesterol being the substrate
for the steroid hormones
and vitamin D.