FAQs about our Team
From 2008.igem.org
Q. How is control of gene
expression by chromatin different from control by transcription factors (and
what are its advantages)?
A.
Chromatin is a completely different level of gene expression control.
·
Dominant over
transcription factors (resistant to noise).
·
Regional –
silences domains, not individual genes (reduces the engineering required for
regulation of complex multi-gene systems).
·
Memory–Alteration
in gene expression lasts for multiple generations (epigenetic control).
·
Intrinsically bistable,
i.e. all-or-none expression (increases parameter space over which circuits are
predicted to be stable).
Q. What applications could this
type of synthetic chromatin control system be used for?
A. To
stably and permanently switch cells between different states characterized by
significant differences in gene expression (i.e. cellular differentiation).
·
In
bio-production–for coordinated switching between a growth phase and a
production phase.
·
In
bio-production–to differentiate a clonal population of cells into a
distribution of subtypes that function cooperatively (“factory” with different
specialized “workers”).
·
To reprogram cell fate
in a highly specific manner (e.g. stem cell engineering, correction of
epigenetic abnormalities in cancer cells).
·
To create cells with
highly digital computational capabilities.
·
To study chromatin
spreading mechanism in a quantitative and controlled way.
Q. Could
this type of yeast synthetic chromatin control system be utilized in other cell
types, including mammalian cells?
A. Yes,
the approach should be transferable.
·
Core elements of this
system are: initiator, covalent mark, spreading (polymerization).
·
In S. cerevisiae, covalent mark is deacetylation–we use an
initiator (LexA-Sir2) that when localized deacetylates adjacent histones. This leads to further recruitment of
Sir2, which propagates the mark outward. Deacetylated chromatin adopts a
“closed” conformation.
·
For higher eukaryotes,
from S. pombe to human, the
covalent mark is methylation, initiator is a histone methyltransferase. But in
principle, a similar system should work.
Same logical design, with different catalytic functions propagating
spread.
Home | The Team | The Project | Parts Submitted to the Registry | Modeling | Human Practices | Notebooks |
---|