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Electrophoretic Analysis of Replication Through Structure-Prone DNA Repeats Within the SV40-Based Human Episome

Published: September 13, 2024
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Summary

Here, we outline the procedure for analyzing replication progression through pathogenic, structure-prone repeats using 2-dimensional gel electrophoresis.

Abstract

Two-dimensional neutral/neutral gel-electrophoresis (2DGE) emerged as a benchmark technique to analyze DNA replication through natural impediments. This protocol describes how to analyze replication fork progression through structure-prone, expandable DNA repeats within the simian virus 40 (SV40)-based episome in human cells. In brief, upon plasmid transfection into human cells, replication intermediates are isolated by the modified Hirt protocol and treated with the DpnI restriction enzyme to remove non-replicated DNA. Intermediates are then digested by appropriate restriction enzymes to place the repeat of interest within the origin-distal half of a 3-5 kb-long DNA fragment. The replication intermediates are separated into two perpendicular dimensions, first by size and then by shape. Following Southern blot hybridization, this approach allows researchers to observe fork stalling at various structure-forming repeats on the descending half of the replication Y-arc. Furthermore, this positioning of the stall site allows the visualization of various outcomes of repeat-mediated fork stalling, such as fork reversal, the advent of a converging fork, and recombinational fork restart.

Introduction

Short tandem repeats (STR) are small, typically 2-9 base pairs (bp), repetitive sequences of DNA that constitute around 3% of the human genome1. STR play an important role in gene regulation2; however, their repetitive composition leaves them prone to non-canonical DNA secondary structure formation and subsequent genetic instability3,4. From left-handed helices to hairpins/cruciforms, to three and four-stranded helices, these alternative DNA structures cause intrinsic challenges for the replisome. A natural prerequisite for secondary structure formation is DNA unwinding, which is a prerequisite for DNA replication. This presents a unique conundrum for genome functioning as many of these structures can form during replication, hindering replisome progression and ultimately causing replication fork stalling5,6,7, or in severe cases, fork collapse and DNA breakage8,9. Both the restart of stalled forks and DNA repair pathways have been shown to lead to repeat instability, such as repeat expansions10,11 and complex genome rearrangements (CGR)12,13. These events can result in the development of roughly 60 human diseases known as repeat expansion disorders, including Fragile X syndrome, Huntington's disease, Friedreich's ataxia, and others14,15 as well as CGR diseases, such as Emmanuel syndrome16. Therefore, to better understand the mechanisms of human disease driven by repeat instability, it is imperative to study the details of replication fork progression through those repeats.

A technique for studying replication progression emerged in the mid-1980s when Brewer and Fangman sought to provide direct evidence that replication initiation in Saccharomyces cerevisiae occurs at autonomous replication sequence (commonly known as ARS) elements17. In doing so, they separated structures of yeast replication intermediates in agarose, adapting an earlier method from Bell and Byers known as 2-dimensional Neutral/Neutral gel-electrophoresis (2DGE)18. This technique utilized the fact that nonlinear DNA travels differently in agarose gel than its linear equivalent of the same mass. More specifically, in 2DGE, isolated DNA is separated in two perpendicular dimensions, first primarily by size and then primarily by shape, to create a comprehensive map of replication at a particular region of interest. In their original paper, Brewer and Fangman demonstrated this as an arc composed of "simple Y" structures or replication forks bridging unreplicated DNA to their replicated counterparts. They further describe other observed intermediates as "bubbles" and "double Ys," representing replication origins and converging forks, respectively.

2DGE can be used to study the relative populations of DNA replication intermediates at a given time. Therefore, if one population of intermediates is more prevalent than another, this would be evident upon visualization. This makes 2DGE an especially useful tool for studying replication progression through challenging sequences, like structure-forming repeats. For example, if the region analyzed contains a sequence capable of inducing replication fork stalling, this would present as a bulge on the arc (Figure 1A), indicating an accumulation of replication forks at that locus. This can be seen with the replication of both hairpin-forming repeat sequences in yeast19,20,21 and triplex-forming repeats in human cells22,23,24. In addition to stalling, 2DGE can be used to observe DNA structures that do not conform to the standard simple Ys formed during replication, as in the case of recombinant intermediates25. These intermediates have a heavier and more branched X-shaped structure and, therefore, travel slower in both the first- and second dimensions than standard replication forks. Similar results can also be observed with regards to replication fork reversal20,24,26. In response to strong replication stress, eukaryotic cells have been shown to utilize replication fork reversal to rescue stalled forks. These reversed forks have similar molecular weight to stalled forks; yet their chicken-foot structure results in slower electrophoretic mobility in the second dimension relative to their Y-shaped complements, resulting in an extension up and out from the arc.

Figure 1
Figure 1: 2D Gel electrophoresis analysis of DNA replication. (A) Schematic of a typical 2DGE depicting replication through a structure-forming repeat capable of inducing fork stalling. Intermediate size and structure will influence electrophoretic mobility. (B) Sample Y-arc with ascending and descending arms respectively labeled. Abbreviation: 2DGE = Two-dimensional neutral/neutral gel-electrophoresis. Please click here to view a larger version of this figure.

Naturally, one of the most important aspects of 2DGE concerns the quality and quantity of replication intermediates. However, the resolution of 2DGE analysis of replication through endogenous loci in mammalian cells is insufficient for a single copy target sequence within the 6 × 109 bp diploid human genome, though it has been done for multi-copy genes, such as heavily amplified DHFR locus27 or ribosomal RNA28. SV40-based replication is an efficient and well-characterized means of studying replication in eukaryotic cells29. It provides a reliable model of eukaryotic replication that utilizes most of the host replisome machinery to replicate the viral genome, which is parceled into nucleosomes upon infection30,31. Two notable exceptions from the mammalian replisome are that the T-antigen (Tag), instead of the host CMG complex, serves as replicative DNA helicase, and DNA polymerase delta synthesizes both leading and lagging DNA strands32. We have taken advantage of this system by placing pathogenic stretches of structure-forming repeats downstream from an SV40 origin of replication within a plasmid that was originally created in the Massimo Lopes lab22. Importantly, this plasmid also contains the gene encoding for Tag itself, thus resulting in its constitutive and extremely potent replication upon transfection into a variety of cultured human cells. This feature gives rise to a large quantity of products, ideal for 2DGE analysis of the intermediates formed during and in response to the replication of pathogenic repeats in human cells. Here, we describe a detailed method of visualizing the replication of structure-forming repeats within the SV40-based human episome using 2-dimensional gel electrophoresis.

Protocol

NOTE: The plasmid designed for our outlined 2DGE analysis in mammalian cells should contain an SV40 origin of replication several kb upstream of structure-prone repeats (Figure 2). Leading and lagging synthesis should be kept in mind when choosing what orientation relative to the origin the repeats should be cloned into the plasmid. …

Representative Results

If successful, upon visualization, a sharp arc of replication forks can be observed extending up and out from the massive 1n spot (Figure 5A). The size of a fragment, or percentage that is replicated, determines the fragment's mobility in the first dimension. As the intermediates develop a more jointed structure, they will begin to travel more slowly in the second dimension. Therefore, if an intermediate has traveled slowly in both dimensions, it can be asserted that it is a highly repli…

Discussion

2DGE provides a semi-quantitative and comprehensive image of the relative populations of intermediates that arise during the replication of a particular sequence. Given that the fragile molecular structures of replication forks must be maintained throughout this procedure, great care should be implemented to prevent physical shearing and chemical denaturation. Therefore, it is highly recommended that any alkaline treatment be avoided during plasmid isolation. To avoid this, we and others have implemented a modified form …

Disclosures

The authors have nothing to disclose.

Acknowledgements

We thank Jorge Cebrian and Anastasia Rastokina who started developing this approach in our lab, Massimo Lopes for providing us with pML113 plasmid and invaluable advice, Ylli Doksani for insightful discussions, and members of the Mirkin lab for their support. The work in the Mirkin lab is supported by the National Institute of General Medical Sciences [R35GM130322] and NSF-BSF [2153071].

Materials

10x TBE Buffer Bio Rad 1610733
20x SSC Buffer Fisher Scientific BP1325-1
293T cells ATCC CRL-3216
a-32P dATP, 3000 Ci/mmol  Revvity BLU512H250UC
Agarose Fisher Scientific BP160-500
Amersham Hybond-N+ Fisher Scientific RPN303B
BAS Storage Phosphor Screens Fisher Scientific 28956482
Church and Gibert's hybriddization buffer Fisher Scientific 50-103-5408
DecaLabel DNA labeling kit ThermoFisher Scientific K0622
DMEM, high gluctose, GltaMAX Supplement, pyruvate ThermoFisher Scientific 10569010
DpnI New England Biolabs R0176S Additional restriction enzymes will need to be purchased as well
EDTA 0.5 M, pH 8 Fisher Scientific BP2482500
Ethanol, 70% Fisher Scientific BP82031GAL
Fetal Bovine Serum  VWR 97068-085
Hydrochloric acid solution, 12 M Millipore Sigma 13-1683
Isopropanol Fisher Scientific BP26184
jetPRIME DNA and siRNA Transfection Reagent with Buffer VWR 101000027
MycoZap Plus-CL VWR 75870-448
NaCl Millipore Sigma 746398-500G
Nalgene Oak Ridge High-Speed Centrifuge Tubes ThermoFisher Scientific 3139-0050
Phosphate Buffer Saline, pH 7.4 ThermoFisher Scientific 10010023
Phosphate Buffer Saline, pH 7.5 ThermoFisher Scientific 10010024
Proteinase K ThermoFisher Scientific EO0491
Proteinase K ThermoFisher Scientific EO0492
Pure Cellulose Chromatography Paper Fisher Scientific 05-714-4
Pure Cellulose Chromatography Paper Fisher Scientific 05-714-5
Ruler Fisher Scientific 09-016
Scalpel Fisher Scientific 12-460-451
Sodium dodecyl sulfate Millipore Sigma 436143-25G
Sodium hydroxide Fisher Scientific S25548
Sorval LYNX 4000 Superspeed Centrifuge ThermoFisher Scientific 75006580
Sub-cell Horizontal Electrophoresis System Bio Rad 1704401
TH13-6 x 50 Swinging Bucket Rotor ThermoFisher Scientific 75003010
Tris-HCl 1 M, pH 7.5 Fisher Scientific BP1757-500
Trypsin-EDTA (0.25%), phenol red ThermoFisher Scientific 25200056

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Cite This Article
Mandel, N. H., Mirkin, S. M. Electrophoretic Analysis of Replication Through Structure-Prone DNA Repeats Within the SV40-Based Human Episome. J. Vis. Exp. (211), e67229, doi:10.3791/67229 (2024).

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