Molecules that start transcription
Transcription is the first step in transformation of the DNA code into actual molecules. Nature has equipped DNA with a system of checks and balances to ensure that transcription is well-regulated, and scientists are elucidating relevant structures.
For a protein-coding gene to be expressed, the DNA is first transcribed
onto a messenger RNA molecule. From there, it is translated into the
amino acid sequence of the protein. This seemingly simple process is
quite complex and scientists have made amazing progress in identifying a
multitude of molecules and subunits that play important roles. In
essence, binding and formation of molecular complexes on the DNA itself
control and initiate transcription.
Upstream of the DNA sequence to be transcribed is a promoter region,
the TATA box (so-called because it contains a specific sequence of
thymine, T, and adenine, A). Binding of a specific protein there (the
TATA box-binding protein that is part of transcription factor IID
(TFIID)) initiates assembly of the pre-initiation complex (PIC) of which
it is a part and which also contains RNA polymerase II (RNAPII). This
initiates RNAPII transcription. Two more general transcription factors
play a role, IIA and IIB (TFIIA and TFIIB, respectively), stabilising
the PIC assembly.
To date, detailed structural information regarding DNA, TFIIA, TFIIB
and TFIID is limited. EU-funded scientists working on the project
PICENGINEERING created a DNA template for PIC assembly containing TFIID
recognition elements, including TATA box. They cloned it and produced it
in large-scale quantities for reconstitution of the PIC stage and
detailed analysis of the complexes and their interactions.
The experimental research was quite challenging. Crystallisation
studies aimed at determining the complex quaternary structure of a
sub-complex containing all the relevant transcription factors (QUART)
were laborious. However, they resulted in determination of the structure
of TFIIA in its apo (inactive or isolated) form for the first time.
PICENGINEERING made important progress in the unravelling of
structures and structural changes involved in the complex process of
RNAPII transcription. With creation of the necessary DNA template
including relevant sequences, the researchers are ready to embark on
extensive crystallisation trials to study the supramolecular
architecture of the PIC stage. Studies are expected to provide insight
into the long-sought 3D structure of QUART and reveal the network of
interactions involved in RNAPII transcription initiation.
published: 2015-03-18