Gene machines

Assembling the μs-ALEX Setup.

Cold Spring Harbor protocols 2015:11 (2015) 1024-1026

Authors:

Achillefs Kapanidis, Devdoot Majumdar, Mike Heilemann, Eyal Nir, Shimon Weiss

Abstract:

This protocol describes the construction of a microsecond-alternating laser excitation (μs-ALEX) using two lasers, a green 532-nm acousto-optically modulated laser and a red 635-nm directly modulated laser.

Sample Preparation and Data Acquisition for μs-ALEX.

Cold Spring Harbor protocols 2015:11 (2015) 1029-1031

Authors:

Achillefs Kapanidis, Devdoot Majumdar, Mike Heilemann, Eyal Nir, Shimon Weiss

Abstract:

This protocol describes the preparation of samples and data acquisition for microsecond-alternating laser excitation. Sample preparation requires a dilution that ensures the detection of single events.

New technologies for DNA analysis – a review of the READNA Project

JournalName Elsevier 33:3 (2015) 311-330

Authors:

S McGinn, D Bauer, T Brefort, L Dong, A El-Sagheer, A Elsharawy, G Evans, E Falk-Sörqvist, M Forster, S Fredriksson, P Freeman, C Freitag, J Fritzsche, S Gibson, M Gullberg, M Gut, S Heath, I Heath-Brun, AJ Heron, J Hohlbein, R Ke, O Lancaster, L Le Reste, G Maglia, R Marie, F Mauger, F Mertes, M Mignardi, L Moens, J Oostmeijer, R Out, JN Pedersen, F Persson, V Picaud, D Rotem, N Schracke, J Sengenes, PF Stähler, B Stade, D Stoddart, X Teng, CD Veal, N Zahra, H Bayley, M Beier, Tom Brown, C Dekker, B Ekström, H Flyvbjerg, A Franke

Abstract:

The REvolutionary Approaches and Devices for Nucleic Acid analysis (READNA) project received funding from the European Commission for 4 1/2 years. The objectives of the project revolved around technological developments in nucleic acid analysis. The project partners have discovered, created and developed a huge body of insights into nucleic acid analysis, ranging from improvements and implementation of current technologies to the most promising sequencing technologies that constitute a 3rd and 4th generation of sequencing methods with nanopores and in situ sequencing, respectively.

Taking the ruler to the jungle: single-molecule FRET for understanding biomolecular structure and dynamics in live cells.

Current opinion in structural biology 34 (2015) 52-59

Authors:

Marko Sustarsic, Achillefs N Kapanidis

Abstract:

Single-molecule Förster resonance energy transfer (smFRET) serves as a molecular ruler that is ideally posed to study static and dynamic heterogeneity in living cells. Observing smFRET in cells requires appropriately integrated labeling, internalization and imaging strategies, and significant progress has been made towards that goal. Pioneering studies have demonstrated smFRET detection in both prokaryotic and eukaryotic systems, using both wide-field and confocal microscopies, and have started to answer exciting biological questions. We anticipate that future technical developments will open the door to smFRET for the study of structure, conformational changes and kinetics of biomolecules in living cells.

Assembly, translocation, and activation of XerCD-dif recombination by FtsK translocase analyzed in real-time by FRET and two-color tethered fluorophore motion.

Proceedings of the National Academy of Sciences of the United States of America 112:37 (2015) E5133-E5141

Authors:

Peter FJ May, Pawel Zawadzki, David J Sherratt, Achillefs N Kapanidis, Lidia K Arciszewska

Abstract:

The FtsK dsDNA translocase functions in bacterial chromosome unlinking by activating XerCD-dif recombination in the replication terminus region. To analyze FtsK assembly and translocation, and the subsequent activation of XerCD-dif recombination, we extended the tethered fluorophore motion technique, using two spectrally distinct fluorophores to monitor two effective lengths along the same tethered DNA molecule. We observed that FtsK assembled stepwise on DNA into a single hexamer, and began translocation rapidly (∼ 0.25 s). Without extruding DNA loops, single FtsK hexamers approached XerCD-dif and resided there for ∼ 0.5 s irrespective of whether XerCD-dif was synapsed or unsynapsed. FtsK then dissociated, rather than reversing. Infrequently, FtsK activated XerCD-dif recombination when it encountered a preformed synaptic complex, and dissociated before the completion of recombination, consistent with each FtsK-XerCD-dif encounter activating only one round of recombination.