The lac operon is a well known example of gene expression regulation, based on the specific interaction of Lac repressor protein (LacI) with its target DNA sequence (operator). LacI and other DNA-binding proteins bind their specific target sequences with rates higher than allowed by 3D diffusion alone. Generally accepted models predict a combination of free 3D diffusion and 1D sliding along non-specific DNA. We recently developed an ultrafast force-clamp laser trap technique capable of probing molecular interactions with sub-ms temporal resolution, under controlled pN-range forces. With this technique, we tested the interaction of LacI with two different DNA constructs: a construct with two copies of the O1 operator separated by 300 bp and a construct containing the native E. coli operator sequences. Our measurements show at least two classes of LacI-DNA interactions: long (in the tens of s range) and short (tens of ms). Based on position along the DNA sequence, the observed interactions can be interpreted as specific binding to operator sequences (long events) and transient interactions with nonspecific sequences (short events). Moreover, we observe continuous sliding of the protein along DNA, passively driven by the force applied with the optical tweezers.
Mechanics of protein-DNA interaction studied with ultra-fast optical tweezers / Carina Monico; Alessia Tempestini; Francesco Vanzi; Francesco Saverio Pavone; Marco Capitanio. - ELETTRONICO. - (2014), pp. 91291X-91291X. (Intervento presentato al convegno Conference on Biophotonics - Photonic Solutions for Better Health Care IV tenutosi a Brussels, BELGIUM nel 14-17 Aprile 2014) [10.1117/12.2052545].
Mechanics of protein-DNA interaction studied with ultra-fast optical tweezers
VANZI, FRANCESCO;PAVONE, FRANCESCO SAVERIO;CAPITANIO, MARCO
2014
Abstract
The lac operon is a well known example of gene expression regulation, based on the specific interaction of Lac repressor protein (LacI) with its target DNA sequence (operator). LacI and other DNA-binding proteins bind their specific target sequences with rates higher than allowed by 3D diffusion alone. Generally accepted models predict a combination of free 3D diffusion and 1D sliding along non-specific DNA. We recently developed an ultrafast force-clamp laser trap technique capable of probing molecular interactions with sub-ms temporal resolution, under controlled pN-range forces. With this technique, we tested the interaction of LacI with two different DNA constructs: a construct with two copies of the O1 operator separated by 300 bp and a construct containing the native E. coli operator sequences. Our measurements show at least two classes of LacI-DNA interactions: long (in the tens of s range) and short (tens of ms). Based on position along the DNA sequence, the observed interactions can be interpreted as specific binding to operator sequences (long events) and transient interactions with nonspecific sequences (short events). Moreover, we observe continuous sliding of the protein along DNA, passively driven by the force applied with the optical tweezers.
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