Pablo Hernandez

Conserved features in the mode of replication of eukaryotic ribosomal RNA genes.

It was previously shown that a 1.5 kb fragment located in the non‐transcribed spacer (NTS) is the earliest replicating region of pea (Pisum sativum) rDNA in synchronized root cells. In the present report the structure of this region was characterized. It contains a cluster of four 11 bp near matches to the Saccharomyces cerevisiae ARS consensus sequence (ACS). These near matches are embedded in an A+T rich domain located upstream from the transcription initiation site. We identified and mapped an intrinsic DNA bending locus 5′ to the cluster of near matches. Several eukaryotic origins including the ARS from the budding yeast show very similar structural features. This observation strengthens the notion that pea rDNA replication initiates at or near this region. Replication of the entire pea rDNA repeat was analysed by two‐dimensional (2D) agarose gel electrophoresis. The results obtained indicate that only a small fraction of the potential origins is used in each replication round. Forks moving in the direction opposite to rRNA transcription are stalled at a polar replication fork barrier (RFB), which mapped near the 3′ end of the transcription unit. Consequently, most of pea rDNA appears to replicate in a unidirectional manner. These results show that the strategy used to replicate pea and yeast rRNA genes is very similar, suggesting that it has been conserved and might be common to most eukaryotes.

DNA knotting caused by head-on collision of transcription and replication.

Collision of transcription and replication is uncommon, but the reason for nature to avoid this type of collision is still poorly understood. In Escherichia coli pBR322 is unstable and rapidly lost without selective pressure. Stability can be rescued if transcription of the tetracycline-resistance gene (Tet(R)), progressing against replication, is avoided. We investigated the topological consequences of the collision of transcription and replication in pBR322-derived plasmids where head-on collision between the replication fork and the RNA polymerase transcribing the Tet(R) gene was allowed or avoided. The results obtained indicate that this type of collision triggers knotting of the daughter duplexes behind the fork. We propose this deleterious topological consequence could explain the instability of pBR322 and could be also one of the reasons for nature to avoid head-on collision of transcription and replication.

Unidirectional replication as visualized by two-dimensional agarose gel electrophoresis☆

Two-dimensional (2D) agarose gel electrophoresis is progressively replacing electron microscopy as the technique of choice to map the initiation and termination sites for DNA replication. Two different versions were originally developed to analyze the replication of the yeast 2 microns plasmid. Neutral/Neutral (N/N) 2D agarose gel electrophoresis has subsequently been used to study the replication of other eukaryotic plasmids, viruses and chromosomal DNAs. In some cases, however, the results do not conform to the expected 2D gel patterns. In order to better understand this technique, we employed it to study the replication of the colE1-like plasmid, pBR322. This was the first time replicative intermediates from a unidirectionally replicated plasmid have been analyzed by means of N/N 2D agarose gel electrophoresis. The patterns obtained were significantly different from those obtained in the case of bidirectional replication. We showed that identification of a complete are corresponding to molecules containing an internal bubble is not sufficient to distinguish a symmetrically located bidirectional origin from an asymmetrically located unidirectional origin. We also showed that unidirectionally replicated fragments containing a stalled fork can produce a pattern with an inflection point. Finally, replication appeared to initiate at only some of the potential origins in each multimer of pBR322 DNA.

Transcription Termination Factor reb1p Causes Two Replication Fork Barriers at Its Cognate Sites in Fission Yeast Ribosomal DNA In Vivo

ABSTRACT Polar replication fork barriers (RFBs) near the 3′ end of the rRNA transcriptional unit are a conserved feature of ribosomal DNA (rDNA) replication in eukaryotes. In the mouse, in vivo studies indicate that the cis-acting Sal boxes required for rRNA transcription termination are also involved in replication fork blockage. On the contrary, in the budding yeast Saccharomyces cerevisiae, the rRNA transcription termination factors are not required for RFBs. Here we characterized the rDNA RFBs in the fission yeast Schizosaccharomyces pombe. S. pombe rDNA contains three closely spaced polar replication barriers named RFB1, RFB2, and RFB3 in the 3′ to 5′ order. The transcription termination protein reb1 and its two binding sites, present at the 3′ end of the coding region, were required for fork arrest at RFB2 and RFB3 in vivo. On the other hand, fork arrest at the strongest RFB1 barrier was independent of the above transcription termination factors. Therefore, RFB2 and RFB3 resemble the barriers present in the mouse rDNA, whereas RFB1 is similar to the budding yeast RFBs. These results suggest that during evolution, cis- and trans-acting factors required for rRNA transcription termination became involved in replication fork blockage also. S. pombe is suggested to be a transitional species in which both mechanisms coexist.

The Mating Type Switch-Activating Protein Sap1 Is Required for Replication Fork Arrest at the rRNA Genes of Fission Yeast

ABSTRACT Schizosaccharomyces pombe rRNA genes contain three replication fork barriers (RFB1-3) located in the nontranscribed spacer. RFB2 and RFB3 require binding of the transcription terminator factor Reb1p to two identical recognition sequences that colocalize with these barriers. RFB1, which is the strongest of the three barriers, functions in a Reb1p-independent manner, and cognate DNA-binding proteins for this barrier have not been identified yet. Here we functionally define RFB1 within a 78-bp sequence located near the 3′ end of the rRNA coding region. A protein that specifically binds to this sequence was purified by affinity chromatography and identified as Sap1p by mass spectrometry. Specific binding to RFB1 was confirmed by using Sap1p expressed in Escherichia coli. Sap1p is essential for viability and is required for efficient mating-type switching. Mutations in RFB1 that precluded formation of the Sap1p-RFB1 complex systematically abolished replication barrier function, indicating that Sap1p is required for replication fork blockage at RFB1.

Interplay of DNA supercoiling and catenation during the segregation of sister duplexes

The discrete regulation of supercoiling, catenation and knotting by DNA topoisomerases is well documented both in vivo and in vitro, but the interplay between them is still poorly understood. Here we studied DNA catenanes of bacterial plasmids arising as a result of DNA replication in Escherichia coli cells whose topoisomerase IV activity was inhibited. We combined high-resolution two-dimensional agarose gel electrophoresis with numerical simulations in order to better understand the relationship between the negative supercoiling of DNA generated by DNA gyrase and the DNA interlinking resulting from replication of circular DNA molecules. We showed that in those replication intermediates formed in vivo, catenation and negative supercoiling compete with each other. In interlinked molecules with high catenation numbers negative supercoiling is greatly limited. However, when interlinking decreases, as required for the segregation of newly replicated sister duplexes, their negative supercoiling increases. This observation indicates that negative supercoiling plays an active role during progressive decatenation of newly replicated DNA molecules in vivo.

Knotting dynamics during DNA replication

The topology of plasmid DNA changes continuously as replication progresses. But the dynamics of the process remains to be fully understood. Knotted bubbles form when topo IV knots the daughter duplexes behind the fork in response to their degree of intertwining. Here, we show that knotted bubbles can form during unimpaired DNA replication, but they become more evident in partially replicated intermediates containing a stalled fork. To learn more about the dynamics of knot formation as replication advances, we used two‐dimensional agarose gel electrophoresis to identify knotted bubbles in partially replicated molecules in which the replication fork stalled at different stages of the process. The number and complexity of knotted bubbles rose as a function of bubble size, suggesting that knotting is affected by both precatenane density and bubble size.

Replication termini in the rDNA of synchronized pea root cells (Pisum sativum).

In synchronized root cells of Pisum sativum (cv. Alaska) the joining of nascent replicons is delayed until cells reach the S–G2 boundary or early G2 phase. To determine if the delayed ligation of nascent chains occurs at specific termination sites, we mapped the location of arrested forks in the ribosomal DNA (rDNA) repeats from cells in late S and G2 phases. Two‐dimensional (neutral‐alkaline) agarose electrophoresis and Southern blot hybridization with specific rDNA sequences show that only cells located at the S–G2 boundary and early G2 phase produce alkali‐released rDNA fragments of discrete size. The released fragments are from a particular restriction fragment, demonstrating that the replication forks stop non‐randomly within the rDNA repeats. Indirect end‐labeling with probes homologous to one or the other end of the fork‐containing restriction fragment shows that there are two termination regions, T1 and T2, where forks stop. T1 is located in the non‐transcribed spacer and T2 is at the junction between the non‐transcribed spacer and the 18S gene. The two termini are separated by ˜1.3 kb. Replication forks stop at identical sites in both the 8.6‐ and 9.0‐kb rDNA repeat size classes indicating that these sites are sequence determined.

Topo IV is the topoisomerase that knots and unknots sister duplexes during DNA replication

DNA topology plays a crucial role in all living cells. In prokaryotes, negative supercoiling is required to initiate replication and either negative or positive supercoiling assists decatenation. The role of DNA knots, however, remains a mystery. Knots are very harmful for cells if not removed efficiently, but DNA molecules become knotted in vivo. If knots are deleterious, why then does DNA become knotted? Here, we used classical genetics, high-resolution 2D agarose gel electrophoresis and atomic force microscopy to show that topoisomerase IV (Topo IV), one of the two type-II DNA topoisomerases in bacteria, is responsible for the knotting and unknotting of sister duplexes during DNA replication. We propose that when progression of the replication forks is impaired, sister duplexes become loosely intertwined. Under these conditions, Topo IV inadvertently makes the strand passages that lead to the formation of knots and removes them later on to allow their correct segregation.

Replication Fork Reversal Occurs Spontaneously after Digestion but Is Constrained in Supercoiled Domains

Replication fork reversal was investigated in undigested and linearized replication intermediates of bacterial DNA plasmids containing a stalled fork. Two-dimensional agarose gel electrophoresis, a branch migration and extrusion assay, electron microscopy, and DNA-psoralen cross-linking were used to show that extensive replication fork reversal and extrusion of the nascent-nascent duplex occurs spontaneously after DNA nicking and restriction enzyme digestion but that fork retreat is severely limited in covalently closed supercoiled domains.