"DIROM"--an interactive system for planning experiments on directed mutagenesis and design of artificial genes]

We present a computer system "DIROM" for oligonucleotide-directed mutagenesis and artificial gene design experiments planning and support. "DIROM" allows to search for optimal oligonucleotides according to such parameters as sufficient energy of oligonucleotide-target hybridization, secondary structure of oligonucleotide and target DNA, presence of alternative attachment sites in target DNA, terminal G/C pairs presence. Both single-stranded and double-stranded vector mutagenesis methods are implemented. It can be also used for optimal primer selection for polymerase chain reaction, sequencing etc. "DIROM" can search for both existent and potential carry out vector+target sequence construction. Both amino acid and nucleotide sequences can be operated.     

Osprey: a comprehensive tool employing novel methods for the design of oligonucleotides for DNA sequencing and microarrays

We have developed a software package called Osprey for the calculation of optimal oligonucleotides for DNA sequencing and the creation of microarrays based on either PCR-products or directly spotted oligomers. It incorporates a novel use of position-specific scoring matrices, for the sensitive and specific identification of secondary binding sites anywhere in the target sequence. Using accelerated hardware is faster and more efficient than the traditional pairwise alignments used in most oligo-design software. Osprey consists of a module for target site selection based on user input, novel utilities for dealing with problematic sequences such as repeats, and a common code base for the identification of optimal oligonucleotides from the target list. Overall, these improvements provide a program that, without major increases in run time, reflects current DNA thermodynamics models, improves specificity and reduces the user's data preprocessing and parameterization requirements. Using a TimeLogic™ hardware accelerator, we report up to 50-fold reduction in search time versus a linear search strategy. Target sites may be derived from computer analysis of DNA sequence assemblies in the case of sequencing efforts, or genome or EST analysis in the case of microarray development in both prokaryotes and eukaryotes.     

Recombination by resolvase to analyse DNA communications by the SfiI restriction endonuclease.

The SfiI endonuclease differs from other type II restriction enzymes by cleaving DNA concertedly at two copies of its recognition site, its optimal activity being with two sites on the same DNA molecule. The nature of this communication event between distant DNA sites was analysed on plasmids with recognition sites for SfiI interspersed with recombination sites for resolvase. These were converted by resolvase to catenanes carrying one SfiI site on each ring. The catenanes were cleaved by SfiI almost as readily as a single ring with two sites, in contrast to the slow reactions on DNA rings with one SfiI site. Interactions between SfiI sites on the same DNA therefore cannot follow the DNA contour and, instead, must stem from their physical proximity. In buffer lacking Mg2+, where SfiI is inactive while resolvase is active, the addition of SfiI to a plasmid with target sites for both proteins blocked recombination by resolvase, due to the restriction enzyme bridging its sites and thus isolating the sites for resolvase into separate loops. The extent of DNA looping by SfiI matched its extent of DNA cleavage in the presence of Mg2+.     

Juxtaposition of two viral DNA ends in a bimolecular disintegration reaction mediated by multimers of human immunodeficiency virus type 1 or murine leukemia virus integrase.

Integration of retroviral DNA involves a coordinated joining of the two ends of a viral DNA molecule into precisely spaced sites on target DNA. In this study, we designed an assay that requires two separate oligonucleotides to be brought together via interactions between integrase promoters to form a "crossbones" substrate that mimics the integration intermediate. The crossbones substrate contains two viral DNA ends, each joined to one strand of target DNA and separated by a defined length of target DNA. We showed that purified integrases of human immunodeficiency virus type 1 (HIV-1) and murine leukemia virus (MLV) could mediate a concerted strand cleavage-ligation between the two half-substrates at one or both viral DNA joining sites (trans disintegration). Another major product, termed fold-back, resulted from an intramolecular attack on the phosphodiester bond at the viral-target DNA junction by the 3'-OH group of the same DNA molecule (cis disintegration). The activity of integrase on the crossbones substrate depended on the presence of viral DNA sequences. For trans disintegration, the optimal length of target DNA between the viral DNA joining sites of the crossbones substrate corresponded to the spacing between the staggered joints formed on two opposite strands of target DNA during retroviral DNA integration in vivo. The activity of integrases on crossbones did not require complementary base pairing between the two half-substrates, indicating that the half-substrates were juxtaposed solely through protein-DNA interactions. The crossbones assay, therefore, measures the ability of integrase to juxtapose two viral DNA ends, an activity which heretofore has been difficult to detect by using purified integrase in conventional assays. Certain mutant integrases that were otherwise inactive with the crossbones substrate could complement one another, indicating that no single protomer in the integrase multimer requires a complete set of functional domains either for catalytic activity or for juxtaposition of the two viral DNA ends by the active multimer.     

Functional significance of protein assemblies predicted by the crystal structure of the restriction endonuclease BsaWI

Type II restriction endonuclease BsaWI recognizes a degenerated sequence 5′-W/CCGGW-3′ (W stands for A or T, ‘/’ denotes the cleavage site). It belongs to a large family of restriction enzymes that contain a conserved CCGG tetranucleotide in their target sites. These enzymes are arranged as dimers or tetramers, and require binding of one, two or three DNA targets for their optimal catalytic activity. Here, we present a crystal structure and biochemical characterization of the restriction endonuclease BsaWI. BsaWI is arranged as an ‘open’ configuration dimer and binds a single DNA copy through a minor groove contacts. In the crystal primary BsaWI dimers form an indefinite linear chain via the C-terminal domain contacts implying possible higher order aggregates. We show that in solution BsaWI protein exists in a dimer-tetramer-oligomer equilibrium, but in the presence of specific DNA forms a tetramer bound to two target sites. Site-directed mutagenesis and kinetic experiments show that BsaWI is active as a tetramer and requires two target sites for optimal activity. We propose BsaWI mechanism that shares common features both with dimeric Ecl18kI/SgrAI and bona fide tetrameric NgoMIV/SfiI enzymes.     

Nucleotides flanking a conserved TAAT core dictate the DNA binding specificity of three murine homeodomain proteins.

Murine homeobox genes play a fundamental role in directing embryogenesis by controlling gene expression during development. The homeobox encodes a DNA binding domain (the homeodomain) which presumably mediates interactions of homeodomain proteins with specific DNA sites in the control regions of target genes. However, the bases for these selective DNA-protein interactions are not well defined. In this report, we have characterized the DNA binding specificities of three murine homeodomain proteins, Hox 7.1, Hox 1.5, and En-1. We have identified optimal DNA binding sites for each of these proteins by using a random oligonucleotide selection strategy. Comparison of the sequences of the selected binding sites predicted a common consensus site that contained the motif (C/G)TAATTG. The TAAT core was essential for DNA binding activity, and the nucleotides flanking this core directed binding specificity. Whereas variations in the nucleotides flanking the 5' side of the TAAT core produced modest alterations in binding activity for all three proteins, perturbations of the nucleotides directly 3' of the core distinguished the binding specificity of Hox 1.5 from those of Hox 7.1 and En-1. These differences in binding activity reflected differences in the dissociation rates rather than the equilibrium constants of the protein-DNA complexes. Differences in DNA binding specificities observed in vitro may contribute to selective interactions of homeodomain proteins with potential binding sites in the control regions of target genes.     

Subunit assembly for DNA cleavage by restriction endonuclease SgrAI

The SgrAI endonuclease usually cleaves DNA with two recognition sites more rapidly than DNA with one site, often converting the former directly to the products cut at both sites. In this respect, SgrAI acts like the tetrameric restriction enzymes that bind two copies of their target sites before cleaving both sites concertedly. However, by analytical ultracentrifugation, SgrAI is a dimer in solution though it aggregates to high molecular mass species when bound to its specific DNA sequence. Its reaction kinetics indicate that it uses different mechanisms to cleave DNA with one and with two SgrAI sites. It cleaves the one-site DNA in the style of a dimeric restriction enzyme acting at an individual site, mediating neither interactions in trans, as seen with the tetrameric enzymes, nor subunit associations, as seen with the monomeric enzymes. In contrast, its optimal reaction on DNA with two sites involves an association of protein subunits: two dimers bound to sites in cis may associate to form a tetramer that has enhanced activity, which then cleaves both sites concurrently. The mode of action of SgrAI differs from all restriction enzymes characterised previously, so this study extends the range of mechanisms known for restriction endonucleases.     

High efficiency, long-term clinical expression of cottontail rabbit papillomavirus (CRPV) DNA in rabbit skin following particle-mediated DNA transfer.

The ability of skin to support long lasting expression of genes delivered with a particle-mediated system was evaluated in rabbits inoculated with cottontail rabbit papillomavirus (CRPV) DNA. The optimal delivery force for maximal gene expression in rabbit skin was determined in transient beta-galactosidase assays. Forty-five sites in four rabbits were then inoculated at 350-400 p.s.i. with CRPV DNA. All sites (100%) formed papillomas with multiple papillomas at most sites. These results support the feasibility of using a particle-mediated delivery system for gene therapy and suggest that some papillomavirus features, such an origin of replication, may be well suited for use in vectors to target long term expression to skin.     

Thermodynamics of DNA target site recognition by homing endonucleases

The thermodynamic profiles of target site recognition have been surveyed for homing endonucleases from various structural families. Similar to DNA-binding proteins that recognize shorter target sites, homing endonucleases display a narrow range of binding free energies and affinities, mediated by structural interactions that balance the magnitude of enthalpic and entropic forces. While the balance of ΔH and TΔS are not strongly correlated with the overall extent of DNA bending, unfavorable ΔH_binding is associated with unstacking of individual base steps in the target site. The effects of deleterious basepair substitutions in the optimal target sites of two LAGLIDADG homing endonucleases, and the subsequent effect of redesigning one of those endonucleases to accommodate that DNA sequence change, were also measured. The substitution of base-specific hydrogen bonds in a wild-type endonuclease/DNA complex with hydrophobic van der Waals contacts in a redesigned complex reduced the ability to discriminate between sites, due to nonspecific ΔS_binding.     

Directly labeled DNA probes using fluorescent nucleotides with different length linkers.

Directly labeled fluorescent DNA probes have been made by nick translation and PCR using dUTP attached to the fluorescent label, Cy3, with different length linkers. With preparation of probes by PCR we find that linker length affects the efficiency of incorporation of Cy3-dUTP, the yield of labeled probe, and the signal intensity of labeled probes hybridized to chromosome target sequences. For nick translation and PCR, both the level of incorporation and the hybridization fluorescence signal increased in parallel when the length of the linker arm is increased. Under optimal conditions, PCR yielded more densely labeled probes, however, the yield of PCR labeled probe decreased with greater linear density of labeling. By using a Cy3-modified dUTP with the longest linker under optimal conditions it was possible to label up to 28% of the possible substitution sites on the target DNA with reasonable yield by PCR and 18% by nick translation. A mechanism involving steric interactions between the polymerase, cyanine-labeled sites on template and extending chains and the modified dUTP substrate is proposed to explain the inverse correlation between the labeling efficiency and the yield of DNA probe synthesis by PCR.     

Protein motion from non-specific to specific DNA by three-dimensional routes aided by supercoiling

DNA-binding proteins are generally thought to locate their target sites by first associating with the DNA at random and then translocating to the specific site by one-dimensional (1D) diffusion along the DNA. We report here that non-specific DNA conveys proteins to their target sites just as well when held near the target by catenation as when co-linear with the target. Hence, contrary to the prevalent view, proteins move from random to specific sites primarily by three-dimensional (3D) rather than 1D pathways, by multiple dissociation/re-association events within a single DNA molecule. We also uncover a role for DNA supercoiling in target-site location. Proteins find their sites more readily in supercoiled than in relaxed DNA, again indicating 3D rather than 1D routes.     

DNA microstructural requirements for neocarzinostatin chromophore-induced direct strand cleavage.

The microstructural requirements for optimal interaction of neocarzinostatin chromophore (NCS-C) with DNA have been investigated using a series of hexadeoxyribonucleotides with modified bases such as O6-methyl G (MeG), I, 5-methyl C (MeC), U, or 5-Bromo U (BrU) at specific sites in its preferred trinucleotide 5'GNaNb3':5'Na,Nb,C3' (Na = A, C, or T). Results show that MeG:C and G:MeC in place of G:C improve direct strand cleavage at the target Nb (Nb = T greater than A much greater than C greater than G), whereas MeC:G and C:MeG in place of Na:Nb, hinder cleavage. The optimal base target at Nb appears to be determined by its ability to form T:A type base pairing instead of C:G type. The observed differences in DNA strand cleavage patterns can be rationalized by induced changes in target site structure and are compatible with a model for NCS-C:DNA interaction in which the naphthoate moiety intercalates between 5'GNa3', and the activated tetrahydro-s-indacene, lying in the minor groove, abstracts a hydrogen atom from C-5' of Nb.     

A symmetrical six-base-pair target site sequence determines Tn10 insertion specificity

Transposon Tn10 inserts at many sites in the bacterial chromosome, but preferentially inserts at particular hotspots. We believe we have identified the target DNA signal responsible for this specificity. We have determined the DNA sequences of 11 Tn10 insertion sites and identified a particular 6 base pair (bp) symmetrical consensus sequence (GCTNAGC) common to those sites. The sequences at some sites differ from the consensus sequence but only in limited and well defined ways. The sequences at some sites differ from the consensus sequence than do sequences at other sites, and the consensus sequence and closely related sequences are generally absent from potential target regions where Tn10 is known not to insert. Other aspects of the target DNA can significantly influence the efficiency with which a particular target site sequence is used. The 6 bp consensus sequence is symmetrically located within the 9 bp target DNA sequence that is cleaved and duplicated during Tn10 insertion. This juxtaposition of recognition and cleavage sites plus the symmetry of the perfect consensus sequence suggest that the target DNA may be both recognized and cleaved by the symmetrically disposed subunits of a single protein, as suggested for type II restriction endonucleases. There is plausible homology between the consensus sequence and the very ends of Tn10, compatible with recognition of transposon ends and target DNA by the same protein. The sequences of actual insertion sites deviate from the perfect consensus sequence in a way which suggests that the 6 bp specificity determinant may be recognized through protein-DNA contacts along the major groove of the DNA double helix.     

Kinetics of target site localization of a protein on DNA: a stochastic approach

It is widely recognized that the cleaving rate of a restriction enzyme on target DNA sequences is several orders-of-magnitude faster than the maximal one calculated from the diffusion-limited theory. It was therefore commonly assumed that the target site interaction of a restriction enzyme with DNA has to occur via two steps: one-dimensional diffusion along a DNA segment, and long-range jumps coming from association-dissociation events. We propose here a stochastic model for this reaction which comprises a series of one-dimensional diffusions of a restriction enzyme on nonspecific DNA sequences interrupted by three-dimensional excursions in the solution until the target sequence is reached. This model provides an optimal finding strategy which explains the fast association rate. Modeling the excursions by uncorrelated random jumps, we recover the expression of the mean time required for target site association to occur given by Berg et al. in 1981, and we explicitly give several physical quantities describing the stochastic pathway of the enzyme. For competitive target sites we calculate two quantities: processivity and preference. By comparing these theoretical expressions to recent experimental data obtained for EcoRV-DNA interaction, we quantify: 1), the mean residence time per binding event of EcoRV on DNA for a representative one-dimensional diffusion coefficient; 2), the average lengths of DNA scanned during the one-dimensional diffusion (during one binding event and during the overall process); and 3), the mean time and the mean number of visits needed to go from one target site to the other. Further, we evaluate the dynamics of DNA cleavage with regard to the probability for the restriction enzyme to perform another one-dimensional diffusion on the same DNA substrate following a three-dimensional excursion.     

Characterization of recombinant murine leukemia virus integrase.

Retroviral integration involves two DNA substrates that play different roles. The viral DNA substrate is recognized by virtue of specific nucleotide sequences near the end of a double-stranded DNA molecule. The target DNA substrate is recognized at internal sites with little sequence preference; nucleosomal DNA appears to be preferred for this role. Despite this apparent asymmetry in the sequence, structure, and roles of the DNA substrates in the integration reaction, the existence of distinct binding sites for viral and target DNA substrates has been controversial. In this report, we describe the expression in Escherichia coli and purification of Moloney murine leukemia virus integrase as a fusion protein with glutathione S-transferase, characterization of its activity by using several model DNA substrates, and the initial kinetic characterization of its interactions with a model viral DNA substrate. We provide evidence for functionally and kinetically distinct binding sites for viral and target DNA substrates and describe a cross-linking assay for DNA binding at a site whose specificity is consistent with the target DNA binding site.