Properties of enzymes that recognize modified structures in DNA

The properties of the major classes of DNA repair enzymes, such as DNA glycosylases, AP-endonucleases, incision nucleases, and alkyl transferases, are reviewed. With the exceptions of the incision nucleases, the properties of the enzymes are quite similar in prokaryotic and eukaryotic cells. The incision nucleases probably do not recognize the modified base residues as such, but rather helical distortion brought about by the modifying agents. The other classes of enzymes are more or less specific for certain modified structures.     

Pulsed-field gel electrophoresis analysis of higher-order chromatin structures of Zea mays. Highly methylated DNA in the 50 kb chromatin structure

We have investigated the presence of higher-order chromatin structures in different maize tissues. Taking advantage of the pulsed-field gel electrophoresis technique to analyse large DNA fragments from intact nuclei and cells, we have determined the size distribution of the high-molecular-weight DNA fragments obtained from chromatin degradation by endogenous nucleases in isolated nuclei. Chromatin digestion leads to the appearance of stable DNA fragments of about 50 kb in all the tissues examined, suggesting the folding of DNA in higher-order chromatin domain structures. It has been reported that such chromatin domains are formed by loops of the 30 nm fibres anchored to the nuclear matrix by a complex set of proteins, including DNA topoisomerase II. Treatment of maize protoplasts with the calcium ionophore A23187 and the antitumour drug VM-26, which specifically inhibit the religation of the cleaved DNA in the topoisomerase II reaction, also produces the 50 kb structure. Analysis of the DNA contained in the 50 kb chromatin structure shows a higher degree of methylation than in bulk maize chromosomal DNA. The role of methylated DNA in the chromatin folding is discussed.     

DNA Segments Sensitive to Single-Strand-Specific Nucleases Are Present in Chromatin of Mitotic Cells

It was observed before that DNAin situin chromatin of mitotic cells is more sensitive to denaturation than DNA in chromatin of interphase cells. DNA sensitivity to denaturation, in these studies, was analyzed by exposing cells to heat or acid and using acridine orange (AO), the metachromatic fluorochrome which can differentially stain double-stranded (ds) vs single-stranded (ss) nucleic acids, as a marker of the degree of DNA denaturation. However, without prior cell treatment with heat or acid no presence of single-stranded DNA in either mitotic or interphase cells was detected by this assay. In the present experiments we demonstrate that DNAin situin mitotic cells, without any prior treatment that can induce DNA denaturation, is sensitive to ss-specific S1 and mung bean nucleases. Incubation of permeabilized human T cell leukemic MOLT-4, promyelocytic HL-60, histiomonocytic lymphoma U937 cells, or normal PHA-stimulated lymphocytes with S1 or mung bean nucleases generated extensive DNA breakage in mitotic cells. DNA strand breaks were detected using fluorochrome-labeled triphosphonucleotides in the reaction catalyzed by exogenous terminal deoxynucleotidyl transferase. Under identical conditions of the cells’ exposure to ss-specific nucleases, DNA breakage in interphase cells was of an order of magnitude less extensive compared to mitotic cells. The data indicate that segments of DNA in mitotic chromosomes, in contrast to interphase cells, may be in a conformation which is sensitive to ss nucleases. This may be a reflection of the differences in the torsional stress of DNA loops between interphase and mitotic chromatin. Namely, greater stress in mitotic loops may lead to formation of the hairpin-loop structures by inverted repeats; such structures are sensitive to ss nucleases. The present method of detection of such segments appears to be more sensitive than the use of AO. The identification of mitotic cells based on sensitivity of their DNA to ss nucleases provides an additional method for their quantification by flow cytometry.     

An archaeal endonuclease displays key properties of both eukaryal XPF-ERCC1 and Mus81

Structure-specific nucleases of the XPF/Mus81 family function in several DNA recombination and repair pathways in eukaryotes, cleaving a variety of flap and branched DNA substrates. Mus81 and XPF are clearly related evolutionarily but differ markedly in their substrate specificity and protein partners. We demonstrate that the XPF endonuclease from Sulfolobus solfataricus, which is dependent on the sliding clamp proliferating cell nuclear antigen for activity, represents an ancestral form of the XPF/Mus81 family, with key properties in common with both enzymes. The archaeal XPF has a domain organization and sequence preference very similar to eukaryal XPF-ERCC1. However, the archaeal enzyme has a pronounced preference for Mus81-type substrates such as D loops, nicked four-way junctions, and 3' flaps. These all have in common a 5'-DNA end next to the cleavage site. The availability of the sliding clamp proliferating cell nuclear antigen may dictate the activity of Sulfolobus XPF in vivo.     

Chimeric restriction enzymes: what is next?

Chimeric restriction enzymes are a novel class of engineered nucleases in which the non-specific DNA cleavage domain of Fokl (a type IIS restriction endonuclease) is fused to other DNA-binding motifs. The latter include the three common eukaryotic DNA-binding motifs, namely the helix-turn-helix motif, the zinc finger motif and the basic helix-loop-helix protein containing a leucine zipper motif. Such chimeric nucleases have been shown to make specific cuts in vitro very close to the expected recognition sequences. The most important chimeric nucleases are those based on zinc finger DNA-binding proteins because of their modular structure. Recently, one such chimeric nuclease, Zif-QQR-F(N) was shown to find and cleave its target in vivo. This was tested by microinjection of DNA substrates and the enzyme into frog oocytes (Carroll et al., 1999). The injected enzyme made site-specific double-strand breaks in the targets even after assembly of the DNA into chromatin. In addition, this cleavage activated the target molecules for efficient homologous recombination. Since the recognition specificity of zinc fingers can be manipulated experimentally, chimeric nucleases could be engineered so as to target a specific site within a genome. The availability of such engineered chimeric restriction enzymes should make it feasible to do genome engineering, also commonly referred to as gene therapy.     

Structural and functional insight into sugar-nonspecific nucleases in host defense

In prokaryotes, sugar-nonspecific nucleases that cleave DNA and RNA in a sequence-independent manner take part in host defense, as well as site-specific restriction enzymes. Examples include the periplasmic nuclease Vvn and the secreted nuclease ColE7, which degrade foreign nucleic acid molecules in the host periplasm and in the cytoplasm of foreign cells, respectively. Recently determined crystal structures of Vvn and ColE7 in complex with double-stranded DNA provide structural insight into nonspecific DNA interactions and cleavage by sugar-nonspecific nucleases. Both nucleases bind DNA at the minor groove through a common 'betabetaalpha-metal' endonuclease motif and primarily contact the DNA phosphate backbone, probably to avoid sequence-dependent base recognition. In eukaryotes, several apoptotic endonucleases that are responsible for DNA degradation in programmed cell death also contain a betabetaalpha-metal fold at the active site, suggesting that they may recognize and cleave DNA in a comparable way.     

Creating highly specific nucleases by fusion of active restriction endonucleases and catalytically inactive homing endonucleases

Zinc-finger nucleases and TALE nucleases are produced by combining a specific DNA-binding module and a non-specific DNA-cleavage module, resulting in nucleases able to cleave DNA at a unique sequence. Here a new approach for creating highly specific nucleases was pursued by fusing a catalytically inactive variant of the homing endonuclease I-SceI, as DNA binding-module, to the type IIP restriction enzyme PvuII, as cleavage module. The fusion enzymes were designed to recognize a composite site comprising the recognition site of PvuII flanked by the recognition site of I-SceI. In order to reduce activity on PvuII sites lacking the flanking I-SceI sites, the enzymes were optimized so that the binding of I-SceI to its sites positions PvuII for cleavage of the composite site. This was achieved by optimization of the linker and by introducing amino acid substitutions in PvuII which decrease its activity or disturb its dimer interface. The most specific variant showed a more than 1000-fold preference for the addressed composite site over an unaddressed PvuII site. These results indicate that using a specific restriction enzyme, such as PvuII, as cleavage module, offers an alternative to the otherwise often used catalytic domain of FokI, which by itself does not contribute to the specificity of the engineered nuclease.     

A histidine in the β-CASP domain of Artemis is critical for its full in vitro and in vivo functions

Artemis is a key factor of the nonhomologous end-joining (NHEJ) pathway, which is critical for DNA double-strand break (DSB) repair in eukaryotic cells. It belongs to the β-CASP family of nucleases, forming a distinct group within the metallo-β-lactamase superfamily. Proteins of this group are specific for nucleic acids and contain an original domain, the β-CASP domain, which serves as a cap covering the active site displayed by the metallo-β-lactamase domain.Here, we have identified in the highly divergent sequences of the β-CASP domains from DNA-specific nucleases two conserved residues (Artemis E213 and H254), which are not present in RNA-specific enzymes, and shown that H254 plays a key role in the Artemis function, as it is critical for its full activity in vitro. Moreover, inherited mutation of H254 results in radiosensitive severe combined immune deficiency (RS-SCID) in humans. This residue might play a key role in specificity towards DNA, if not directly in zinc binding.     

Retroviral integrase superfamily: the structural perspective

The retroviral integrase superfamily (RISF) comprises numerous important nucleic acid‐processing enzymes, including transposases, integrases and various nucleases. These enzymes are involved in a wide range of processes such as transposition, replication and repair of DNA, homologous recombination, and RNA‐mediated gene silencing. Two out of the four enzymes that are encoded by the human immunodeficiency virus—RNase H1 and integrase—are members of this superfamily. RISF enzymes act on various substrates, and yet show remarkable mechanistic and structural similarities. All share a common fold of the catalytic core and the active site, which is composed primarily of carboxylate residues. Here, I present RISF proteins from a structural perspective, describing the individual members and the common and divergent elements of their structures, as well as the mechanistic insights gained from the structures of RNase H1 enzyme complexes with RNA/DNA hybrids.     

A 140-Bp-Long Palindromic Sequence Induces Double-Strand Breaks during Meiosis in the Yeast Saccharomyces Cerevisiae

Palindromic sequences have the potential to form hairpin or cruciform structures, which are putative substrates for several nucleases and mismatch repair enzymes. A genetic method was developed to detect such structures in vivo in the yeast Saccharomyces cerevisiae. Using this method we previously showed that short hairpin structures are poorly repaired by the mismatch repair system in S. cerevisiae. We show here that mismatches, when present in the stem of the hairpin structure, are not processed by the repair machinery, suggesting that they are treated differently than those in the interstrand base-paired duplex DNA. A 140-bp-long palindromic sequence, on the contrary, acts as a meiotic recombination hotspot by generating a site for a double-strand break, an initiator of meiotic recombination. We suggest that long palindromic sequences undergo cruciform extrusion more readily than short ones. This cruciform structure then acts as a substrate for structure-specific nucleases resulting in the formation of a double-strand break during meiosis in yeast. In addition, we show that residual repair of the short hairpin structure occurs in an MSH2-independent pathway.     

Excision of amplified viral DNA at palindromic sequences from the adenovirus type 12-transformed hamster cell line T637.

In the DNA of the adenovirus type 12 (Ad12)-transformed hamster cell line T637 approximately 20-22 viral DNA molecules per cell are covalently linked to cellular DNA. Spontaneously arising morphological revertants of T637 cells have lost the bulk of the viral DNA. We have been able to mimic the excision event of viral DNA, as it occurs during reversion, by autoincubation of isolated nuclei from T637 cells. The same Ad12 DNA sequences, which had been deleted in morphological revertants, proved highly sensitive to endogenous nucleases in isolated nuclei of T637 cells. Viral DNA sequences, which persisted in the revertants, are resistant to endogenous nucleases in isolated T637 nuclei. All attempts to clone the nuclease-sensitive sites of Ad12 DNA in cell line T637 have so far failed. After denaturation and renaturation of T637 DNA followed by treatment with S1 nuclease, large fold-back structures of DNA have been found. These snap-back structures were derived from precisely those viral DNA restriction fragments which were uncloneable. The fragments containing palindromic sequences were both highly sensitive to endogenous nucleases in isolated T637 nuclei and were absent from the DNA of all revertant cell lines. Moreover, the palindromic sequences are susceptible to the phage T4-specific endonuclease VII which specifically attacks cruciform structures in DNA. The peculiar structures at the termini of integrated Ad12 DNA molecules are highly sensitive to endogenous nucleases in isolated nuclei. These nucleases may be related to the reversion event.     

Purification and properties of nuclease SP.

Single-strand-specific nucleases are a diverse and important group of enzymes that are able to cleave a variety of DNA structures present in duplex molecules. Nuclease SP, an enzyme from spinach, has been purified to apparent homogeneity, allowing for the unambiguous characterization of a number of its physical properties as well as its DNA strand cleavage specificities. The effects of ionic strength, pH, divalent metal cations, and temperature on nuclease SP activity have been examined in detail. Nuclease SP was found to be quite thermostable and could be stimulated by Co2+. In addition, the cleavage of UV-damaged and undamaged supercoiled plasmid substrates under a variety of conditions suggests that at least two types of structures are recognized and processed by nuclease SP: UV photoproduct-induced distortions and unwound "nuclease hypersensitive sites". These studies indicate that nuclease SP is functionally related to other single-strand-specific nucleases and is a potential enzymatic tool for probing and manipulating various types of DNA structures.     

Self-organization of domain structures by DNA-loop-extruding enzymes

The long chromosomal DNAs of cells are organized into loop domains much larger in size than individual DNA-binding enzymes, presenting the question of how formation of such structures is controlled. We present a model for generation of defined chromosomal loops, based on molecular machines consisting of two coupled and oppositely directed motile elements which extrude loops from the double helix along which they translocate, while excluding one another sterically. If these machines do not dissociate from DNA (infinite processivity), a disordered, exponential steady-state distribution of small loops is obtained. However, if dissociation and rebinding of the machines occurs at a finite rate (finite processivity), the steady state qualitatively changes to a highly ordered ‘stacked’ configuration with suppressed fluctuations, organizing a single large, stable loop domain anchored by several machines. The size of the resulting domain can be simply regulated by boundary elements, which halt the progress of the extrusion machines. Possible realizations of these types of molecular machines are discussed, with a major focus on structural maintenance of chromosome complexes and also with discussion of type I restriction enzymes. This mechanism could explain the geometrically uniform folding of eukaryote mitotic chromosomes, through extrusion of pre-programmed loops and concomitant chromosome compaction.     

SURVEY AND SUMMARY: holliday junction resolvases and related nucleases: identification of new families, phyletic distribution and evolutionary trajectories

Holliday junction resolvases (HJRs) are key enzymes of DNA recombination. A detailed computer analysis of the structural and evolutionary relationships of HJRs and related nucleases suggests that the HJR function has evolved independently from at least four distinct structural folds, namely RNase H, endonuclease, endonuclease VII-colicin E and RusA. The endonuclease fold, whose structural prototypes are the phage lambda exonuclease, the very short patch repair nuclease (Vsr) and type II restriction enzymes, is shown to encompass by far a greater diversity of nucleases than previously suspected. This fold unifies archaeal HJRs, repair nucleases such as RecB and Vsr, restriction enzymes and a variety of predicted nucleases whose specific activities remain to be determined. Within the RNase H fold a new family of predicted HJRs, which is nearly ubiquitous in bacteria, was discovered, in addition to the previously characterized RuvC family. The proteins of this family, typified by Escherichia coli YqgF, are likely to function as an alternative to RuvC in most bacteria, but could be the principal HJRs in low-GC Gram-positive bacteria and AQUIFEX: Endonuclease VII of phage T4 is shown to serve as a structural template for many nucleases, including MCR:A and other type II restriction enzymes. Together with colicin E7, endonuclease VII defines a distinct metal-dependent nuclease fold. As a result of this analysis, the principal HJRs are now known or confidently predicted for all bacteria and archaea whose genomes have been completely sequenced, with many species encoding multiple potential HJRs. Horizontal gene transfer, lineage-specific gene loss and gene family expansion, and non-orthologous gene displacement seem to have been major forces in the evolution of HJRs and related nucleases. A remarkable case of displacement is seen in the Lyme disease spirochete Borrelia burgdorferi, which does not possess any of the typical HJRs, but instead encodes, in its chromosome and each of the linear plasmids, members of the lambda exonuclease family predicted to function as HJRs. The diversity of HJRs and related nucleases in bacteria and archaea contrasts with their near absence in eukaryotes. The few detected eukaryotic representatives of the endonuclease fold and the RNase H fold have probably been acquired from bacteria via horizontal gene transfer. The identity of the principal HJR(s) involved in recombination in eukaryotes remains uncertain; this function could be performed by topoisomerase IB or by a novel, so far undetected, class of enzymes. Likely HJRs and related nucleases were identified in the genomes of numerous bacterial and eukaryotic DNA viruses. Gene flow between viral and cellular genomes has probably played a major role in the evolution of this class of enzymes. This analysis resulted in the prediction of numerous previously unnoticed nucleases, some of which are likely to be new restriction enzymes.     

Grouping together highly diverged PD-(D/E)XK nucleases and identification of novel superfamily members using structure-guided alignment of sequence profiles

The PD-(D/E)XK nuclease domains, initially identified in type II restriction enzymes, serve as models for studying aspects of protein-DNA interactions, mechanisms of phosphodiester hydrolysis, and provide indispensable tools for techniques in genetic engineering and molecular medicine. However, the low degree of amino acid conservation hampers the possibility of identification of PD-(D/E)XK superfamily members based solely on sequence comparisons. In several proteins implicated in DNA recombination and repair the restriction enzyme-like nuclease domain has been found only after the corresponding structures were determined experimentally. Here, we identified highly diverged variants of the PD-(D/E)XK domain in many proteins and open reading frames using iterative database searches and progressive, structure-guided alignment of sequence profiles. We predicted the possible cellular function for many hypothetical proteins based on their relative similarity to characterized nucleases or observed presence of additional domains. We also identified the nuclease domain in genuine recombinases and restriction enzymes, whose homology to other PD-(D/E)XK enzymes has not been demonstrated previously. The first superfamily-wide comparative analysis, not limited to nucleases of known structure, will guide cloning and characterization of novel enzymes and planning new experiments to better understand those already studied.     

Activation of DNA primer for DNA polymerase as an ultrasensitive assay for a subgroup of enzymes with deoxyribonuclease activity

Pretreatment of native DNA with nucleases which hydrolyze phosphodiester bonds with liberation of 3′-hydroxyl terminal groups is known to increase the rate of incorporation of nucleotides into DNA by E. coli DNA polymerase I and similar enzymes. Concentration ranges and conditions for this reaction have been established which allow specific detection and quantitative assay of such nucleases. The method permits detection of as little as 0.1 pg of pancreatic deoxyribonuclease, is simple, and requires only commercially available components. It has been utilized to monitor purification of a nuclease from HeLa cell nuclei at concentrations which could not be detected by other methods.     

Attachment of repeated sequences to the nuclear cage.

Nuclear DNA is probably organized into loops by attachment to a sub-structure in vivo. When HeLa cells are lysed in Triton and 2M NaCl the resulting nucleoids contain naked DNA which is supercoiled so the loops must remain intact. We have attempted to identify sequences responsible for attaching these loops to the nuclear sub-structure by progressively detaching DNA with various nucleases. Fragments at the 5' end of the ribosomal RNA locus, and a variety of transcribed and repeated sequences, are shown to lie relatively close to attachment points. This implies that sequences cannot be arranged randomly. However no "attachment sequence" could be identified.     

Expression, purification and characterization of cloning-grade zinc finger nuclease

The limited number of naturally occurring rare-cutting restriction enzymes and the slow and tedious engineering of existing restriction enzymes for novel specificities have prompted the design of new strategies for the development of restriction enzymes with specificities for long DNA sequences. One possibility is using zinc finger nucleases (ZFNs)—synthetic restriction enzymes that are custom-designed to target and cleave long DNA sequences and which have been recently shown useful for DNA cloning. Here we report on the purification and biochemical analysis of ZFN-10, a custom-made ZFN. We show that Ni-affinity and gel-filtration purification methods are sufficient to produce a cloning-grade enzyme. We show that ZFN-10 can function as an accurate and reliable ZFN using the same reagents and protocols used for naturally occurring and commercially available recombinant restriction enzymes. We also show that ZFN-10 tolerates a set of target-site substitutions which can be predicted from the specificities of recognition helices incorporated into the structure of its DNA-binding domain. The relative simplicity of ZFN-10 design, expression, purification and analysis suggests that novel ZFNs can potentially be designed and applied for various recombinant DNA applications.