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Printable Handouts
Navigable Slide Index
- Introduction
- Epigenetic marks are retained during meiosis
- Inheritance of epigenetic marks
- Example of epigenetic inheritance: odor
- Example of epigenetic inheritance: stress
- Epigenetic mechanisms
- Epigenetics and evolution
- Darwinian inheritance
- Lamarckian inheritance
- Conventional way of thinking about the life cycle
- Example: food restriction
- What epigenetics tells us about the life cycle
- Redefining classic concepts in evolution theory
- Great "Ah Ha" moments in scientific history
- The zygote is the primary level of selection
- Role of epigenetics in gastrulation
- Predictive value of the cell biologic approach
- Endocrinology and epigenetic mark acquisition
Topics Covered
- Select epigenetic ‘marks’ are retained from generation to generation
- Inter- and transgenerational transmission of epigenetic marks is via germline cells
- ~97% of human genetic diseases are likely caused by epigenetic inheritance
- Epigenetics allows for redefinition of terms in descriptive biology
- Epigenetic inheritance leads to the zygote as the primary level of selection
- The cellular-molecular approach to biology is predictive
Talk Citation
Torday, J.S. (2016, October 20). The dynamic interactions between cellular-molecular physiology and the environment - The unicellular state as the level of selection - epigenetics [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 21, 2024, from https://doi.org/10.69645/NTXL8826.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.
The dynamic interactions between cellular-molecular physiology and the environment - The unicellular state as the level of selection - epigenetics
Published on October 20, 2016
10 min
A selection of talks on Genetics & Epigenetics
Transcript
Please wait while the transcript is being prepared...
0:00
My name is John Torday.
I'm a Professor of Evolutionary
Medicine at UCLA.
This is a lecture
in a lecture series entitled
"Evolutionary Physiology".
This lecture is entitled
"The Unicellular State
as the Level
of Selection-Epigenetics".
0:16
It had long been thought
that epigenetic marks
that are acquired
during the life cycle
by the ovaries and testes,
DNA methylation, ubiquitination,
phosphorylation,
acetylation, ribosylation
were erased during meiosis.
It is now known that some
of those marks are retained
during meiosis
and further tested
for their functional fidelity,
during embryogenesis
and during the life cycle
of the organism.
0:42
Inheritance of epigenetic marks
can occur via the germline,
shown on the right.
Or via effects
of the environment
on hypothalamic DNA methylation
affecting maternal behavior,
being passed onto the next
several generations.
0:57
For example,
an odorant in the environment
can methylate sperm cells
causing a startle response
in the offspring.
1:06
Similarly, it has been shown
that a physiologic stress
to the pregnant mother rat
can be passed
on transgenerationally
due to epigenetic modification
of both somatic and germ cells.
1:17
There are several ways
in which epigenetic marks
are generated
to modify DNA readout.
Methylation, acetylation,
phosphorylation,
and ubiquitination
are all depicted in this slide.
1:30
Only about 3% of human
genetic disease is Mendelian.
Therefore, 97% of human
genetic disease is epigenetic.
Epigenetic inheritance affects
the offspring, not the adults.
The significance
of this to evolution theory
is that it represents
Lamarckian inheritance.
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