Separation of protein charge variants by ultrafiltration

The removal of product variants that form during downstream processing remains a challenge in the purification of recombinant therapeutic proteins. We examined the feasibility of separating variants with slightly different net charge using high-performance membrane ultrafiltration. A myoglobin variant was formed by reaction of the lysine epsilon-amino group with succinic anhydride. Sieving data were obtained over a range of solution conditions using commercial polyethersulfone ultrafiltration membranes. Maximum selectivity of about 7-fold was obtained at very low conductivity due to the strong electrostatic repulsion of the more negatively charged variant. Protein separations were performed by diafiltration. A two-stage process generated solutions of the normal myoglobin (in the permeate) and the charge variant (in the retentate), both at greater than 9-fold purification and 90% yield. These results provide the first demonstration that membrane systems can be used to separate proteins that differ by only a single charged amino acid residue.     

DNA bending by the bulge defect

Comparative gel electrophoresis measurements were used to characterize DNA bending in molecules containing an extra adenosine on one strand, the so-called bulge defect. We used oligomers containing A6 tracts separated from the bulged base by varying numbers of nucleotides to determine the direction and magnitude of the bulge bend. Helix unwinding by the bulge was determined from the electrophoretic anomaly as a function of the size of the repeated monomers. We conclude that the bulge bend is 21 degrees +/- 3 degrees, primarily in the direction of tilt away from the bulged base. The total helical advance of the DNA at the bulge site is smaller than would be the case if the complementary T were present, corresponding to an unwinding by 25 degrees +/- 6 degrees. These values are in good agreement with the results of NMR and energy minimization studies of the bulged base in double-helical deoxyoligonucleotides [Woodson, S. A., & Crothers, D.M. (1988) Biochemistry 27, 3130-3141]     

Supercoiling-induced DNA bending

Local DNA bending is a critical factor for numerous DNA functions including recognition of DNA by sequence-specific regulatory binding proteins. Negative DNA supercoiling increases both local and global DNA dynamics, and this dynamic flexibility can facilitate the formation of DNA-protein complexes. We have recently shown that apexes of supercoiled DNA molecules are sites that can promote the formation of an alternative DNA structure, a cruciform, suggesting that these positions in supercoiled DNA are under additional stress and perhaps have a distorted DNA geometry. To test this hypothesis, we used atomic force microscopy to directly measure the curvature of apical positions in supercoiled DNA. The measurements were performed for an inherently curved sequence formed by phased A tracts and a region of mixed sequence DNA. For this, we used plasmids in which an inverted repeat and A tract were placed at precise locations relative to each other. Under specific conditions, the inverted repeat formed a cruciform that was used as a marker for the unambiguous identification of the A tract location. When the A tract and cruciform were placed diametrically opposite, this yielded predominantly nonbranched plectonemic molecules with an extruded cruciform and A tract localized in the terminal loops. For both the curved A tract and mixed sequence nonbent DNA, their localization to an apex increased the angle of bending compared to that expected for DNA unconstrained in solution. This is consistent with increased helical distortion at an apical bend.     

DNA bending induced by DNA (cytosine-5) methyltransferases

DNA bending induced by six DNA (cytosine-5) methyltransferases was studied using circular permutation gel mobility shift assay. The following bend angles were obtained: M.BspRI (GG^m5CC), 46–50°; M.HaeIII (GG^m5CC), 40–43°; M.SinI (GGW^m5CC), 34–37°; M.Sau96I (GGN^m5CC), 52–57°; M.HpaII (C^m5CGG), 30°; and M.HhaI (G^m5CGC), 13°. M.HaeIII was also tested with fragments carrying a methylated binding site, and it was found to induce a 32° bend. A phase-sensitive gel mobility shift assay, using a set of DNA fragments with a sequence-directed bend and a single methyltransferase binding site, indicated that M.HaeIII and M.BspRI bend DNA toward the minor groove. The DNA curvature induced by M.HaeIII contrasts with the lack of DNA bend observed for a covalent M.HaeIII–DNA complex in an earlier X-ray study. Our results and data from other laboratories show a correlation between the bending properties and the recognition specificities of (cytosine-5) methyltransferases: enzymes recognizing a cytosine 3′ to the target cytosine tend to induce greater bends than enzymes with guanine in this position. We suggest that the observed differences indicate different mechanisms employed by (cytosine-5) methyltransferases to stabilize the helix after the target base has flipped out.     

Analysis of DNA bending by transient electric birefringence

Transient electric birefringence has been used to analyze DNA bending in six restriction fragments containing 171, 174, 207, 263, 289, and 471 bp in three different low ionic strength buffers. The target fragments contain sequences corresponding to the apparent bend centers in pUC19 and Litmus 28, previously identified by the circular permutation assay (Strutz, K.; Stellwagen, N. C. Electrophoresis 1996, 17, 989-995). The target fragments migrate anomalously slowly in polyacrylamide gels and exhibit birefringence relaxation times that are shorter than those of restriction fragments of the same size, taken from nonbent regions of the same plasmids. Apparent bend angles ranging from 30 degrees to 41 degrees were calculated for the target fragments by tau-ratio method. The bend angles of four of the target fragments were independent of temperature from 4 degrees C to 20 degrees C, but decreased when the temperature was increased to 37 degrees C. The bend angles of the other two target fragments were independent of temperature over the entire range examined, 4 degrees -37 degrees C. Hence, the thermal stability of sequence-dependent bends in random-sequence DNA is variable. The bend angles of five of the six target fragments were independent of the presence or absence of Mg2+ ions in the solution, indicating most of the target fragments were stably bent or curved, rather than anisometrically flexible. Restriction fragments containing 219 and 224 bp, with sequences somewhat offset from the sequence of the 207 bp fragment, were also studied. Comparison of the tau-ratios of these overlapping fragments allowed both the bend angle and bend position to be independently determined. These methods should be useful for analyzing sequence-dependent bending in other random-sequence DNAs.     

DNA oxidation by charge transport in mitochondria

Sites of oxidative DNA damage in functioning mitochondria have been identified using a rhodium photooxidant as a probe. Here we show that a primer extension reaction can be used to monitor oxidative DNA damage directly in functioning mitochondria after photoreaction with a rhodium intercalator that penetrates the intact mitochondrial membrane. The complex [Rh(phi)2bpy]Cl3 (phi = 9,10-phenanthrenequinonediimine) binds to DNA within the mitochondria and, upon irradiation, initiates DNA oxidation reactions. Significantly, piperidine treatment of the mitochondria leads to protein-dependent primer extension stops spaced every approximately 20 base pairs. Hence, within the mitochondria, the DNA is well covered and packaged by proteins. Photolysis of the mitochondria containing [Rh(phi)2bpy]3+ leads to oxidative DNA damage at positions 260 and 298; both are mutational hot spots associated with cancers. The latter position is the 5'-nucleotide of conserved sequence block II and is critical to replication of the mitochondrial DNA. The oxidative damage is found to be DNA-mediated, utilizing a charge transport mechanism, as the Rh binding sites are spatially separated from the oxidation-prone regions. This long-range DNA-mediated oxidation occurs despite protein association. Indeed, the oxidation of the mitochondrial DNA leads not only to specific oxidative lesions, but also to a corresponding change in the protein-induced stops in the primer extension. Mitochondrial DNA damage promotes specific changes in protein-DNA contacts and is thus sensed by the mitochondrial protein machinery.     

Mechanisms of DNA bending

Genome packaging and gene regulation require DNA bending. Recent developments in the elucidation of the mechanisms involved in DNA bending include new X-ray structures (most notably that of the mammalian nucleosome) wherein DNA is bent, controversy surrounding interpretation of DNA-bending experiments with basic-leucine zipper proteins, studies of electrostatic effects in DNA bending, and the design of artificial DNA-bending ligands.     

In vivo DNA protection by relaxed-specificity SinI DNA methyltransferase variants

The SinI DNA methyltransferase, a component of the SinI restriction-modification system, recognizes the sequence GG(A/T)CC and methylates the inner cytosine to produce 5-methylcytosine. Previously isolated relaxed-specificity mutants of the enzyme also methylate, at a lower rate, GG(G/C)CC sites. In this work we tested the capacity of the mutant enzymes to function in vivo as the counterpart of a restriction endonuclease, which can cleave either site. The viability of Escherichia coli cells carrying recombinant plasmids with the mutant methyltransferase genes and expressing the GGNCC-specific Sau96I restriction endonuclease from a compatible plasmid was investigated. The sau96IR gene on the latter plasmid was transcribed from the araBAD promoter, allowing tightly controlled expression of the endonuclease. In the presence of low concentrations of the inducer arabinose, cells synthesizing the N172S or the V173L mutant enzyme displayed increased plating efficiency relative to cells producing the wild-type methyltransferase, indicating enhanced protection of the cell DNA against the Sau96I endonuclease. Nevertheless, this protection was not sufficient to support long-term survival in the presence of the inducer, which is consistent with incomplete methylation of GG(G/C)CC sites in plasmid DNA purified from the N172S and V173L mutants. Elevated DNA ligase activity was shown to further increase viability of cells producing the V173L variant and Sau96I endonuclease.     

The DNA bending by acetylaminofluorene residues and by apurinic sites

We have studied the distortions induced in double-stranded oligonucleotides by covalently bound acetylaminofluorene residues and by apurinic sites. Within the acetylaminofluorene-modified oligonucleotide three base-pairs are unpaired as detected by the chemical probes chloroacetaldehyde and osmium tetroxide. These two probes reveal that the bases adjacent to the apurinic site are paired. In both the modified double-stranded oligonucleotides, the backbone on the 5' side of the modification is more reactive with 1,10-phenanthroline copper than the backbone on the 3' side. On polyacrylamide gels, the ligated multimers of acetylaminofluorene or apurinic site-modified oligonucleotides migrate slower than the multimers of the unmodified oligonucleotides. It is suggested that the acetylaminofluorene-modified guanine residues and the apurinic sites behave more as hinge joints than as the centres of directed bends.     

Mapping the transition state for DNA bending by IHF

How DNA-bending proteins recognize their specific sites on DNA remains elusive, particularly for proteins that use indirect readout, which relies on sequence-dependent variations in DNA flexibility/bendability. The question remains as to whether the protein bends the DNA (protein-induced bending) or, alternatively, "prebent" DNA conformations are thermally accessible, which the protein captures to form the specific complex (conformational capture). To distinguish between these mechanisms requires characterization of reaction intermediates and, in particular, snapshots of the transition state along the recognition pathway. We present such a snapshot, from measurements of DNA bending dynamics in complex with Escherichia coli integration host factor (IHF), an architectural protein that bends specific sites on λ-DNA in a U-turn by creating two sharp kinks in DNA. Fluorescence resonance energy transfer measurements in response to laser temperature-jump perturbation monitor DNA bending. We find that nicks or mismatches that enhance DNA flexibility at the site of the kinks show 3- to 4-fold increase in DNA bending rates that reflect a 4- to 11-fold increase in binding affinities, while sequence modifications away from the kink sites, as well as mutations in IHF designed to destabilize the complex, have negligible effect on DNA bending rates despite >250-fold decrease in binding affinities. These results support the scenario that the bottleneck in the recognition step for IHF is spontaneous kinking of cognate DNA to adopt a partially prebent conformation and point to conformational capture as the underlying mechanism of initial recognition, with additional protein-induced bending occurring after the transition state.     

DNA bending by small, mobile multivalent cations.

We propose a purely electrostatic mechanism by which small, mobile, multivalent cations can induce DNA bending. A multivalent cation binds at the entrance to the B-DNA major groove, between the two phosphate strands, electrostatically repelling sodium counterions from the neighboring phosphates. The unscreened phosphates on both strands are strongly attracted to the groove-bound cation. This leads to groove closure, accompanied by DNA bending toward the cationic ligand. We explicitly treat the dynamic character of the cation-DNA interaction using an adiabatic approximation, noting that DNA bending is much slower than the diffusion of nonspecifically bound, mobile cations. We make semiquantitative estimates of the free energy components of bending-electrostatic (with a sigmoidal distance-dependent dielectric function), elastic, and entropic cation localization-and find that the equilibrium state is bent B-DNA stabilized with a self-localized cation. This is a bending polaron, formation of which should be critically dependent on the strength of electrostatic interaction and the concentration of highly mobile cations available for self-localization. We predict that the resultant bend will be large (approximately 20-40 degrees), smooth (because it is spread over 6 bp), and infrequent. The stability of such a bend can be variable, from transient to highly stable (static) bending, observable with standard curvature-measuring techniques. We further predict that this bending mechanism will have an unusual sequence dependence: sequences with less binding specificity will be more bent, unless the specific binding site is in the major groove.     

DNA sequence determinant for Flp-induced DNA bending

The Flp site-specific recombinase from Saccharomyces cerevisiae induces DNA bending upon interaction with the Flp recognition target (FRT) site. The minimal FRT site comprises the inverted a and b binding elements, which flank a central 8 bp core region. The DNA bend in a complex of two Flp monomers bound to the FRT site is located in the middle of the core region. When the central AT basepair was replaced with a CG, the DNA bend was positioned at the outside end of the core region adjacent to the a binding element. The other basepairs surrounding the central AT basepair were not important to the position of Flp-induced bends. The change also decreased Flp-mediated cleavage of the top strand of the FRT site and increased Flp-mediated cleavage of the bottom strand. The overall recombination proficiency of the site was impaired. We conclude that the central AT basepair provides a point of flexure in the FRT site, which Flp uses to position the bend in dimeric Flp–DNA complexes, and that the structure of the core DNA influences the functionality of the site.     

DNA bending and twisting properties of integration host factor determined by DNA cyclization

The binding of many proteins to DNA is profoundly affected by DNA bending, twisting, and supercoiling. When protein binding alters DNA conformation, interaction between inherent and induced DNA conformation can affect protein binding affinity and specificity. Integration host factor (IHF), a sequence-specific, DNA-binding protein of Escherichia coli, strongly bends the DNA upon binding. To assess the influence of inherent DNA bending on IHF binding, we took advantage of the high degree of natural static curvature associated with an IHF site on a 163-bp minicircle and measured the binding affinity of IHF for its recognition site contained on this DNA in both circular and linear form. IHF showed a higher affinity for the circular form of the DNA when compared to the linear form. In addition, the presence of IHF during DNA cyclization changed the topology of cyclization products and their ability to bind IHF, consistent with IHF untwisting DNA. These results show that inherent DNA conformation anisotropy is an important determinant of IHF binding affinity and suggests a mechanism for modulation of IHF activity by local DNA conformation.     

Replacement of integration host factor protein-induced DNA bending by flexible regions of DNA

The Escherichia coli integration host factor (IHF) protein is required for site-specific recombination of bacteriophage lambda DNA. Previously, we had shown that alternative modules of static DNA curvature could partially replace IHF in recombination. Now we use regions of single-stranded DNA as a flexible tether to address whether the function of IHF in recombination is simply to reduce persistence length. Although we find that these modules clearly enhance recombination in the absence of IHF, they are not perfect replacements. In addition, evidence is presented that the efficacy of a flexibility swap is specific to a particular IHF site. This may indicate that additional functions beyond simple deformation of DNA are required of IHF. During the course of these experiments we discovered that these flexible sequences are still specific sites for IHF binding and function.