Blunt-end Ligation Research Articles

JAZ Requires the Double-stranded RNA-binding Zinc Finger Motifs for Nuclear Localization

We have cloned and characterized a novel zinc finger protein, termed JAZ. JAZ contains four C(2)H(2)-type zinc finger motifs that are connected by long (28-38) amino acid linker sequences. JAZ is expressed in all tissues tested and localizes in the nucleus, primarily the nucleolus. JAZ preferentially binds to double-stranded (ds) RNA or RNA/DNA hybrids rather than DNA. Mutation of individual zinc finger motifs reveals that the zinc finger domains are not only essential for dsRNA binding but are also required for its nucleolar localization, which demonstrates a complex trafficking mechanism dependent on the nucleic acid-binding capability of the protein. Furthermore, forced expression of JAZ potently induces apoptosis in murine fibroblast cells. Thus, JAZ may belong to a class of zinc finger proteins that features dsRNA binding and may regulate cell growth via the unique dsRNA binding properties.

Cloning and Characterization of KCC3 and KCC4, New Members of the Cation-Chloride Cotransporter Gene Family

The K+-Cl- cotransporters (KCCs) belong to the gene family of electroneutral cation-chloride cotransporters, which also includes two bumetanide-sensitive Na+-K+-2Cl- cotransporters and a thiazide-sensitive Na+-Cl- cotransporter. We have cloned cDNAs encoding mouse KCC3, human KCC3, and human KCC4, three new members of this gene family. The KCC3 and KCC4 cDNAs predict proteins of 1083 and 1150 amino acids, respectively. The KCC3 and KCC4 proteins are 65-71% identical to the previously characterized transporters KCC1 and KCC2, with which they share a predicted membrane topology. The four KCC proteins differ at amino acid residues within key transmembrane domains and in the distribution of putative phosphorylation sites within the amino- and carboxyl-terminal cytoplasmic domains. The expression of mouse KCC3 in Xenopus laevis oocytes reveals the expected functional characteristics of a K+Cl- cotransporter: Cl--dependent uptake of 86Rb+ which is strongly activated by cell swelling and weakly sensitive to furosemide. A direct functional comparison of mouse KCC3 to rabbit KCC1 indicates that KCC3 has a much greater volume sensitivity. The human KCC3 and KCC4 genes are located on chromosomes 5p15 and 15q14, respectively. Although widely expressed, KCC3 transcripts are the most abundant in heart and kidney, and KCC4 is expressed in muscle, brain, lung, heart, and kidney. The unexpected molecular heterogeneity of K+-Cl- cotransport has implications for the physiology and pathophysiology of a number of tissues.

Neuronal differentiation factor TA20--homology with cytochrome b.

TA20 is a cDNA clone which was previously reported to encode a novel neuronal differentiation factor. However, the majority of this clone has near perfect DNA sequence homology with cytochrome b mitochondrial sequence and an additional 5' region which lacks homology with any previously reported sequence. Furthermore, careful study of the library construction method indicates that the full length TA20 clone is likely an artifact arising from the head-to-head blunt-ended ligation of two unrelated cDNAs. Thus, the effects on growth and neurite outgrowth observed in correlation with the overexpression of TA20 in neuronal cells, as well as its mRNA distribution in the developing rat brain require further study.

Gene assembly based on blunt-ended double-stranded DNA-modules

Gene synthesis of leucine zipper genes based on blunt end ligation of ds DNA modules was performed in several ligation steps on magnetic beads. A 3'-phosphate, which was removed by T4 polynucleotide kinase after each ligation step, was used to guarantee orientation and single addition of newly added modules. Not depending on sequence complementarity the method appears well suited for the generation of combinatorial libraries of heterologous molecules.

Mapping oxidative DNA damage at nucleotide level

DNA damage induced by reactive oxygen species (ROS) is considered an important intermediate in the pathogenesis of human conditions such as cancer and aging. By developing an oxidative-induced DNA damage mapping version of the Ligation-mediated polymerase chain reaction (LMPCR) technique, we investigated the in vivo and in vitro frequencies of DNA base modifications caused by ROS in the human p53 and PGK1 gene. Intact human male fibroblasts were exposed to 50 mM H2O2, or purified genomic DNA was treated with 5 mM H2O2, 100 μM Ascorbate, and 50 μM, 100 μM, or 100 μM of Cu(II), Fe(III), or Cr(VI) respectively. The damage pattern generated in vivo was nearly identical to the in vitro Cu(II) or Fe(III) damage patterns; damage was non-random with guanine bases heavily damaged. Cr(VI) generated an in vitro damage pattern similar to the other metal ions, although several unique thymine positions were damaged. Also, extra nuclear sites are a major contributor of metal ions (or metal-like ligands). These data show that the local probability of H2O2-mediated DNA damage is determined by the primary DNA sequence, with chromatin structure having a limited effect. The data suggest a model in which DNA-metal ion binding domains can accommodate different metalions. LMPCR's unique aspect is a blunt-end ligation of an asymmetric double-stranded linker, permitting exponential PCR amplification. An important factor limiting the sensitivity of LMPCR is the representation of target gene DNA relative to non-targeted genes; therefore, we recently developed a method to eliminate excess non-targeted genomic DNA. Restriction enzyme-digested genomic DNA is size fractionated by Continuous Elution Electrophoresis (CEE), capturing the target sequence of interest. The amount of target DNA in the starting material for LMPCR is enriched, resulting in a stronger amplification signal. CEE provided a 24-fold increase in the signal strength attributable to strand breaks plus modified bases created by ROS in the human p53 and PGK1 genes, detected by LMPCR. We are currently taking advantage of the enhanced sensitivity of target gene-enriched LMPCR to map DNA damage induced in human breast epithelial cells exposed to non-cytotoxic concentrations of H2O2.

Microisolation of the chicken Z chromosome and construction off microclone libraries

A simple method was used to adapt a standard light microscope for the collection of chicken Z chromosomes from mitotic-metaphase spreads. The DNA of the collected chromosomes was enzymatically amplified using a partially degenerate primer. The resulting sequences, within a size range of 200-800 bp, were cloned to produce a Z chromosome DNA library, using blunt-end ligation into a SmaI-digested pUC18 plasmid (the SureClone system; Pharmacia, U.S.A.). The microcloning experiments produced 1250 clones; the size range of the cloned inserts was 250-800 bp, with an average of 480 bp (176 clones examined). Using male chicken genomic DNA as a probe, 10 out of 17 randomly selected clones showed strong positive signals on Southern blots, confirming the origin of the inserts as chicken DNA. In addition, the Z-chromosome origin of a selected microclone was verified in a semiquantitative Southern blot hybridization that showed positive signals with intensities that were approximately twice as strong for male (ZZ) as for female (ZW) chicken genomic DNA when the clone was used as a probe. The value of these libraries in further analysis of the chicken Z chromosome is discussed.

Functional characterization of the T4 DNA ligase: a new insight into the mechanism of action.

ATP-dependent DNA ligases are essential enzymes in both DNA replication and DNA repair processes. Here we report a functional characterization of the T4 DNA ligase. One N-terminal and two C-terminal deletion mutants were expressed in Escherichia coli as histidine- tagged proteins. An additional mutant bore a substitution of Lys159 in the active site that abolished ATP binding. All the proteins were tested in biochemical assays for ATP-dependent self-adenylation, DNA binding, nick joining, blunt-end ligation and AMP- dependent DNA relaxation. From this analysis we conclude that binding to DNA is mediated by sequences at both protein ends and plays a key role in the reaction. The enzyme establishes two different complexes with DNA: (i) a transient complex (T.complex) involving the adenylated enzyme; (ii) a stable complex (S.complex) requiring the deadenylated T4 DNA ligase. The formation of an S. complex seems to be relevant during both blunt-end ligation and DNA relaxation. Moreover the inactive His-K159L substitution mutant, although unable to self-adenylate, still possesses AMP-dependent DNA nicking activity.

The RAD5 gene product is involved in the avoidance of non-homologous end-joining of DNA double strand breaks in the yeast Saccharomyces cerevisiae.

In wild-type yeast, the repair of a 169 bp double-strand gap induced by the restriction enzymes ApaI and NcoI in the URA3gene of the shuttle vector YpJA18 occurs with high fidelity according to the homologous chromosomal sequence. In contrast, only 25% of the cells of rad5-7 and rad5 Delta mutants perform correct gap repair. As has been proven by sequencing of the junction sites, the remaining cells recircularise the gapped plasmids by joining of the non-compatible, non-homologous ends. Thus, regarding the repair of DNA double-strand breaks, the rad5 mutants behave like mammalian cells rather than budding yeast. The majority of the end joined plasmids miss either one or both of the 3'and 5'protruding single-strands of the restriction ends completely and have undergone blunt-end ligation accompanied by fill-in DNA synthesis. These results imply an important role for the Rad5 protein (Rad5p) in the protection of protruding single-strand ends and for the avoidance of non-homologous end joining during repair of double-strand gaps in budding yeast. Alternatively, the Rad5p may be an accessory factor increasing the efficiency of homologous recombination in yeast, however, the molecular mechanism of Rad5p function requires further investigation.

Cloning PCR products utilizing the T/A overhang and a kit.

AbstractThe ever expanding identification of new gene family members in recent years has depended in large part on the use of the polymerase chain reaction (PCR) technique. Direct cloning of PCR products into an appropriate vector allows identification of the product by sequencing and characterization of the product’s transcript by Northern hybridization analysis or ribonuclease protection assay. Typically PCR products may be cloned into the vector by cohesive or blunt-end ligation. Cohesive-end ligation traditionally requires the addition of restriction sites to the PCR primers. This necessitates additional enzymatic manipulation and purification steps before the product may be cloned into the vector. Likewise, PCR products amplified with Tag polymerase must undergo further enzymatic manipulation before blunt-end ligation. In addition, blunt-end ligation is a less efficient process than cohesive-end ligation (1).KeywordsPolymerase Chain ReactionPolymerase Chain Reaction ProductPolymerase Chain Reaction ReactionLigation ReactionRibonuclease Protection AssayThese keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Cloning unmodified PCR products using engineered XcmI restriction sites in a portable cassette.

AbstractThe rapid amplification and isolation of specific DNA fragments made possible by the polymerase chain reaction (1,2) has become routine for a variety of molecular biology studies and applications. Taq DNA polymerase is still the most widely used enzyme for PCR amplifications, despite the fact that a number of other thermostable DNA polymerases are now available from commercial suppliers. Taq DNA polymerase is capable of catalyzing the addition of a single nucleotide, a deoxyadenosine (dA), to the 3′ ends of amplified PCR products (3), resulting in a single nucleotide 3′ overhang. This renders blunt-end ligation of such PCR products to cloning vectors inefficient.KeywordsLigation ReactionDideoxy ThymidineDeoxythymidine TriphosphateThymidine TriphosphateNominal Molecular Weight CutoffThese keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

The joining of non-complementary DNA double-strand breaks by mammalian extracts.

We have developed a high efficiency system in which mammalian extracts join DNA double-strand breaks with non-complementary termini. This system has been used to obtain a large number of junction sequences from a range of different break-end combinations, allowing the elucidation of the joining mechanisms. Using an extract of calf thymus it was found that the major mechanism of joining was by blunt-end ligation following removal or fill-in of the single-stranded bases. However, some break-end combinations were joined through an efficient mechanism using short repeat sequences and we have succeeded in separating this mechanism from blunt-end joining by the biochemical fractionation of extracts. Characterization of activities and sequence data in an extensively purified fraction that will join ends by the repeat mechanism led to a model where joining is initiated by 3' strand invasion followed by pairing to short repeat sequences close to the break site. Thus the joining of double-strand breaks by mammalian extracts is achieved by several mechanisms and this system will allow the purification of the factors involved in each by the judicial choice of the non-complementary ends used in the assay.

An alternative to blunt-end ligation for cloning DNA fragments with incompatible ends

An alternative to blunt-end ligation for cloning DNA fragments with incompatible ends

Increased cloning efficiency by temperature-cycle ligation.

Molecular cloning is a crucial, and often speed-limiting, step in many standard procedures of molecular biology. Ligation of cohesive DNA ends is normally carried out at 12–16 C to ensure a good balance between enzyme activity and stability of annealed DNA overhangs. Low temperatures generally reduce ligase activity, whereas too high temperatures may reduce cloning efficiencies by melting annealed DNA overhangs and increase overall molecular motion in the ligation reaction. Several procedures have been described to increase the efficiency ligation reactions, including the addition of condensing agents as polyethylene glycol (1) or hexamminedicobalt chloride (2). These approaches induce macromolecular crowding, and thus serve to mimic higher DNA concentrations in the ligation reaction. Other approaches seek to increase the efficiency of molecular cloning procedures by omitting the ligation step by generating long single-stranded DNA overhangs that can be annealed and transformed directly into an appropriate Escherichia coli host (3). Ligation of blunt-ended DNA fragments is normally carried out at room temperature using higher concentrations of T4 DNA ligase. We have devised a simple procedure in which high enzyme activity and DNA annealing is balanced by constant temperature cycling. We find temperature-cycle ligations (TCL) may increase the efficiency of staggered cut cloning ∼4–8-fold, while the efficiency of blunt-end clonings are increased ∼4–6-fold (see Table 1). The bacterial cloning vector pBluescript II KS+ was digested with AflIII and HindIII producing two cohesive end-fragments of 434 and 2526 bp respectively, or PvuII generating two blunt-end fragments of 448 and 2512 bp respectively. All enzymes were purchased from Amersham. Digested plasmid DNA was separated on 1% low-melting agarose (NuSieve) and purified as described by Sambrook et al. (1). For each digestion a ligation master mix was prepared containing 50 mM Tris–HCl (pH 7.6), 5 mM MgCl2, 5 mM DTT, 50 μg BSA/ml, 0.5 mM ATP, 200 ng DNA and 0.1 Weiss unit T4 DNA ligase/10 μl. The purified fragments were added in equimolar amounts. The master mix was divided into 10 μl ligation reactions and either incubated at 14 C, at room temperature (22 C), or subjected to temperature cycling. Temperature-cycle ligations were carried out for 12–16 h in a Perkin-Elmer-Cetus DNA Thermal Cycler 480 programmed indefinitely to cycle between 30 s at 10 C and 30 s at 30 C. In our setting, the machine performed 10 cycles/h. Competent XL1-Blue E.coli cells were transformed by electrotransformation according to manufacturer’s directions (BioRad), transferred to 1 ml LB medium and incubated at 37 C for 1 h. For enumeration of cloning efficiencies aliquots of 25–100 μl were spread onto LB plates containing 50 μg/ml ampicillin. The number of colonies appearing per transformation is shown in Table 1. We have tested the kinetics of temperature-cycle ligations over 12–16 h, and found them to be similar to those of ligations at constant temperatures resulting in a linear increase with time in the number of colonies appearing after transformation (data not shown). Furthermore, temperature-cycle ligation may be used together with hexamminedicobalt chloride in blunt-end ligations to give the combined effect.

Construction of mammalian genomic libraries using lambda replacement vectors.

The ideal genomic library should consist of a series of clones containing overlapping sequences that are representative of the entire genome. Such an ideal state can be approached by cutting the DNA randomly and cloning large pieces of this DNA into a suitable vector (1). The DNA can be cleaved either by mechanical shearing, in which case the DNA is fragmented in a truely random fashion, but with the introduction of problems associated with blunt end ligation, or better, by partial digestion with a restriction endonuclease such as Mbol or Sau3A. These enzymes recognize four base sequences that are predicted to occur on average (although in practice this is not the case) every 256 bases, and hence digestion results in cleavage of the DNA in a pseudorandom manner.

Construction of a vector containing a site-specific DNA double-strand break with 3'-phosphoglycolate termini and analysis of the products of end-joining in CV-1 cells.

Previous studies have shown that linearized SV40-based shuttle vectors transfected into mammalian cells are efficiently recircularized by an error-prone end-joining pathway. To determine whether and with what specificity free radical-mediated double-strand breaks are rejoined by this pathway, a structural mimic of such a break was introduced at a specific site in an SV40-based shuttle vector, by ligating purified 3'-phosphoglycolate-terminated oligonucleotides into 3' recessed ends generated in the linearized vector. These terminally blocked linear vectors were efficiently repaired and replicated when transfected into simian CV-1 cells. Sequencing across the repair joints in progeny plasmid indicated that, for a blunt-ended vector, the most frequent mechanism of rejoining was splicing at a terminal 4-base homology; however, a significant fraction of the joints retained all bases from both ends of the break, consistent with a mechanism involving simple 3'-phosphoglycolate removal, followed by blunt-end ligation. For the analogous 3'-hydroxyl terminated break, the fraction of simple blunt-end ligations was considerably higher. For a phosphoglycolate-terminated vector with cohesive ends the most frequent repair mechanism was simple ligation of the annealed cohesive ends, presumably preceded by phosphoglycolate removal. For all these substrates, the remaining repair joints showed small or large deletions from one or both of the ends, usually with apparent annealing at short (1-4-base) homologies. The results suggest that while breaks with 3'-phosphoglycolates can be repaired, these blocked termini represent a significant barrier to DNA end-joining, and can significantly alter its specificity. The presence of cohesive ends appears to improve markedly the fidelity of rejoining for terminally blocked double-strand breaks.

Ligation of Nonmatching DNA Molecule Ends

T4 DNA ligase can promote the in vitro ligation of blunt DNA ends to ends bearing a 2-nucleotide single-stranded protrusion. This was shown by digestion of plasmids pBR322 and pSP71 with the appropriate restriction enzymes followed by recircularization of the plasmids and transformation of Escherichia coli . It could be ruled out that such nonmatching ligations are due to the presence of contaminating nucleases. The efficiency of ligation is of the same order of magnitude as that obtained with blunt end ligations. The interaction of a number of different combinations of blunt and sticky ends, the latter bearing both 3′ and 5′ protrusions, was investigated. Ligation of nonmatching ends was shown to take place in all cases. Several ligation junctions were sequenced, showing that during the ligation process the 2-nucleotide protrusion is trimmed away. In two instances the ligation event was accompanied by the specific loss of either 3 or 15 nucleotide pairs as well as the protrusion. An intermolecular ligation involving nonmatching ends was also performed, demonstrating that this form of ligation can be usefully employed in molecular cloning experiments.

Expression and immunogenicity of an 18-residue epitope of HIV1 gp41 inserted in the flagellar protein of a Salmonella live vaccine

A synthetic oligonucleotide specifying residues 735–752 of the product of the env gene of HIV1 IIIB was inserted by blunt-end ligation at restriction sites in the hypervariabls, antigenically determinant region IV of two flagellin genes. Its integration, in name and correct orientation, into gene fliC(d) in plasmid pLS408 allowed production of functional flagella when the plasmid was placed in a flagellin-negative aroA live-vaccine Salmonella dublin strain, SL5928. Bacteria thus made motile were immobilized and agglutinated by anti-(735–752 peptide) serum; expression was also shown by immunoelectron-microscopy and by Western blot of whole-cell lysates. Enzyme immunoassay (EIA) of sera of mice given three doses by intraperitoneal injection of the live-vaccine strain producing chimeric flagellin, or of concentrated flagella from it showed production of antibody with affinity for the peptide, and in some sera, also for r-gp160. Pooled serum from mice given five i.p. doses of the live vaccine strain expressing the gp41 epitope at the surface of its flagellar filaments had higher titres of anti-peptide and anti-r-gp160 antibody and weak neutralizing activity on the IIIB isolate (90 % neutralization at 1 100 ). The sera of nine mice given two doses of the live vaccine by the oral route had either no or only very low titres of antibody to flagellar antigen d; they were therefore not tested for anti-peptide activity.

Introduction of double-strand breaks into the genome of mouse cells by expression of a rare-cutting endonuclease.

To maintain genomic integrity, double-strand breaks (DSBs) in chromosomal DNA must be repaired. In mammalian systems, the analysis of the repair of chromosomal DSBs has been limited by the inability to introduce well-defined DSBs in genomic DNA. In this study, we created specific DSBs in mouse chromosomes for the first time, using an expression system for a rare-cutting endonuclease, I-SceI. A genetic assay has been devised to monitor the repair of DSBs, whereby cleavage sites for I-SceI have been integrated into the mouse genome in two tandem neomycin phosphotransferase genes. We find that cleavage of the I-SceI sites is very efficient, with at least 12% of stably transfected cells having at least one cleavage event and, of these, more than 70% have undergone cleavage at both I-SceI sites. Cleavage of both sites in a fraction of clones deletes 3.8 kb of intervening chromosomal sequences. We find that the DSBs are repaired by both homologous and nonhomologous mechanisms. Nonhomologous repair events frequently result in small deletions after rejoining of the two DNA ends. Some of these appear to occur by simple blunt-ended ligation, whereas several others may occur through annealing of short regions of terminal homology. The DSBs are apparently recombinogenic, stimulating gene targeting of a homologous fragment by more than 2 orders of magnitude. Whereas gene-targeted clones are nearly undetectable without endonuclease expression, they represent approximately 10% of cells transfected with the I-SceI expression vector. Gene targeted clones are of two major types, those that occur by two-sided homologous recombination with the homologous fragment and those that occur by one-sided homologous recombination. Our results are expected to impact a number of areas in the study of mammalian genome dynamics, including the analysis of the repair of DSBs and homologous recombination and, potentially, molecular genetic analyses of mammalian genomes.

Introduction of Double-Strand Breaks into the Genome of Mouse Cells by Expression of a Rare-Cutting Endonuclease

To maintain genomic integrity, double-strand breaks (DSBs) in chromosomal DNA must be repaired. In mammalian systems, the analysis of the repair of chromosomal DSBs has been limited by the inability to introduce well-defined DSBs in genomic DNA. In this study, we created specific DSBs in mouse chromosomes for the first time, using an expression system for a rare-cutting endonuclease, I-SceI. A genetic assay has been devised to monitor the repair of DSBs, whereby cleavage sites for I-SceI have been integrated into the mouse genome in two tandem neomycin phosphotransferase genes. We find that cleavage of the I-SceI sites is very efficient, with at least 12% of stably transfected cells having at least one cleavage event and, of these, more than 70% have undergone cleavage at both I-SceI sites. Cleavage of both sites in a fraction of clones deletes 3.8 kb of intervening chromosomal sequences. We find that the DSBs are repaired by both homologous and nonhomologous mechanisms. Nonhomologous repair events frequently result in small deletions after rejoining of the two DNA ends. Some of these appear to occur by simple blunt-ended ligation, whereas several others may occur through annealing of short regions of terminal homology. The DSBs are apparently recombinogenic, stimulating gene targeting of a homologous fragment by more than 2 orders of magnitude. Whereas gene-targeted clones are nearly undetectable without endonuclease expression, they represent approximately 10% of cells transfected with the I-SceI expression vector. Gene targeted clones are of two major types, those that occur by two-sided homologous recombination with the homologous fragment and those that occur by one-sided homologous recombination. Our results are expected to impact a number of areas in the study of mammalian genome dynamics, including the analysis of the repair of DSBs and homologous recombination and, potentially, molecular genetic analyses of mammalian genomes.

Detection of HCV RNA by the asymmetric gap ligase chain reaction.

The ligase chain reaction (LCR) and the gap ligase chain reaction (gLCR) are exponential amplification techniques for the detection of DNA sequences in a sample. Both techniques depend on the enzyme, DNA ligase, to join adjacent probes annealed to a DNA molecule. However, DNA ligase joins DNA inefficiency on an RNA target. Consequently, LCR and gLCR cannot amplify RNA efficiency. RNA detection methods using LCR or gLCR require a cDNA synthesis step. The carryover of four dNTPs from the cDNA reaction inhibits gLCR. Although LCR can use cDNA reaction products directly, background generated by blunt-end ligation does not allow the high sensitivity typically needed for HIV or HCV detection. The asymmetric gap ligase chain reaction (AGLCR) is a modification of gLCR that allows for the detection of RNA by using < or = 3 of the 4 nucleotides in the cDNA step and the gLCR step. Fewer than 50 copies of synthetic RNA transcript can be reproducibly detected. HCV, an RNA virus with no DNA intermediate, was chosen as the initial RNA model system. HCV antibody-positive and normal samples were analyzed, and the results were found to correlate with the results obtained using nested RNA-PCR. AGLCR provides a new nucleic acid amplification technique that can aid in the diagnosis of disease when the detection of RNA is critical.