Nicholas Luzzietti scite author profile

Twisting a DNA molecule held under constant tension is accompanied by a transition from a linear to a plectonemic DNA configuration, in which part of the applied twist is absorbed in a superhelical structure. Recent experiments revealed the occurrence of an abrupt extension change at the onset of this transition. To elucidate its origin we study this abrupt DNA shortening using magnetic tweezers. We find that it strongly depends on the length of the DNA molecule and the ionic strength of the solution. This behavior can be well understood in the framework of a model in which the energy per writhe for the initial plectonemic loop is larger than for subsequent turns of the superhelix. By quantitative data analysis, relevant plectoneme energies and other parameters were extracted, providing good agreement with a simple theory. As a direct confirmation of the initial-loop model, we find that for a kinked DNA molecule the abrupt extension change occurs at significantly lower twist than the subsequent superhelix formation. This should allow pinning of the plectoneme position within supercoiled DNA if a kinked substrate is used, and enable the detection of enzymes and proteins which, themselves, bend or kink DNA.

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Nicking enzyme–based internal labeling of DNA at multiple loci

Luzzietti

Knappe

Richter

et al. 2012

Nat Protoc

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The labeling of biomolecules has become standard practice in molecular biosciences. Modifications are used for detection, sorting and isolation of small molecules, complexes and entire cells. We have recently reported a method for introducing internal chemical and structural modifications into kbp-sized DNA target substrates that are frequently used in single-molecule experiments. It makes use of nicking enzymes that create single-stranded DNA gaps, which can be subsequently filled with labeled oligonucleotides. Here we provide a detailed protocol and further expand this method. We show that modifications can be introduced at distant loci within one molecule in a simple one-pot reaction. In addition, we achieve labeling on both strands at a specific locus, as demonstrated by Förster resonance energy transfer (FRET) experiments. The protocol requires an initial cloning of the target substrate (3-5 d), whereas the labeling itself takes 4-6 h. More elaborate purification and verification of label incorporation requires 2 h for each method.

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Efficient preparation of internally modified single-molecule constructs using nicking enzymes

Luzzietti¹,

Brutzer²,

Klaue³

et al. 2010

Nucleic Acids Research

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Investigations of enzymes involved in DNA metabolism have strongly benefited from the establishment of single molecule techniques. These experiments frequently require elaborate DNA substrates, which carry chemical labels or nucleic acid tertiary structures. Preparing such constructs often represents a technical challenge: long modified DNA molecules are usually produced via multi-step processes, involving low efficiency intermolecular ligations of several fragments. Here, we show how long stretches of DNA (>50 bp) can be modified using nicking enzymes to produce complex DNA constructs. Multiple different chemical and structural modifications can be placed internally along DNA, in a specific and precise manner. Furthermore, the nicks created can be resealed efficiently yielding intact molecules, whose mechanical properties are preserved. Additionally, the same strategy is applied to obtain long single-strand overhangs subsequently used for efficient ligation of ss- to dsDNA molecules. This technique offers promise for a wide range of applications, in particular single-molecule experiments, where frequently multiple internal DNA modifications are required.

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The Role of H2A-H2B Dimers in the Mechanical Response of Single Nucleosomes

Luzzietti

Seidel

2013

Biophysical Journal

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Single-molecule FRET has become a powerful tool to study conformational changes in cellular machines and many other biomolecules. Labeled with fluorophores at specific positions, distance changes can be tracked with high temporal and spatial resolution. Correspondingly, magnetic tweezers have evolved into an important force-based single-molecule technique that allows the manipulation of molecules through piconewton forces in combination with torques. The control over molecular twist is particularly interesting for the study of chiral biomolecules such as double-stranded DNA (dsDNA). Most single-molecule experiments, however, are limited to one of these dimensions of molecular characteristics at a time, leaving some questions unanswered. Simultaneously controlling force and distance in a molecular frame promises to provide a more complete picture of biomolecular interactions. Here, we present a hybrid instrument, combining these two techniques, smFRET and magnetic tweezers, and its application to model systems, such as dsDNA and DNA hairpins. Our experiments demonstrate a parallel force manipulation of several individual biomolecules with forces ranging from 100 fN to 20 pN, while simultaneously recording single fluorophores, leading to an expansion of the available information space.

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