A general method for saturation mutagenesis of cloned DNA fragments.

A new procedure for generating and isolating random single-base substitutions in cloned DNA fragments is presented. The mutations are generated by treatment of single-stranded DNA with various chemicals, followed by the synthesis of the complementary strand with reverse transcriptase. Misincorporation frequently occurs when the enzyme encounters a damaged base in the mutagenized template DNA.

Nearly all single base substitutions in DNA fragments joined to a GC-clamp can be detected by denaturing gradient gel electrophoresis.

Duplex DNA fragments differing by single base substitutions can be separated by electrophoresis in denaturing gradient polyacrylamide gels, but only substitutions in a restricted part of the molecule lead to a separation (1). In an effort to circumvent this problem, we demonstrated that the melting properties and electrophoretic behavior of a 135 base pair DNA fragment containing a beta-globin promoter are changed by attaching a GC-rich sequence, called a 'GC-clamp' (2). We predicted that these changes should make it possible to resolve most, if not all, single base substitutions within fragments attached to the clamp.

Modification of the melting properties of duplex DNA by attachment of a GC-rich DNA sequence as determined by denaturing gradient gel electrophoresis.

The melting behavior of a DNA fragment carrying the mouse beta maj-globin promoter was investigated as a means of establishing procedures for separating DNA fragments differing by any single base substitution using the denaturing gradient gel electrophoresis procedure of Fischer and Lerman (1,2). We find that attachment of a 300 base pair GC-rich DNA sequence, termed a GC-clamp, to a 135 bp DNA fragment carrying the mouse beta-globin promoter significantly alters the pattern of DNA melting within the promoter. When the promoter is attached to the clamp, the promoter sequences melt without undergoing strand dissociation.

Detection of single base substitutions in total genomic DNA.

Certain single base substitutions causing genetic diseases or resulting in polymorphisms linked to mutant alleles, alter a restriction enzyme cleavage site and can therefore be detected in total genomic DNA using DNA blots. Many base substitutions do not lead to an altered restriction site, but these can be detected using synthetic oligonucleotides as hybridization probes if the DNA sequence surrounding the base substitution is known. In the case of beta-thalassaemia, where 22 different single base mutations have been identified, a large number of probes would be required for diagnosis.

Dependence of the electrophoretic mobility of DNA in gels on field intermittency.

The electrophoretic mobility of double helical DNA in agarose and polyacrylamide gels increases as a function of time after the electric field is applied to the gel and decreases after the field is terminated. The changes are large for long (more than 10 kb) molecules. The effects of other variables are indicated.

Scaling of the equilibrium sedimentation distribution in dense DNA solutions.

DNA molecules, several persistence lengths long in sedimentation equilibrium at speeds high enough to maintain fairly close packing, show a dense, sharply-bounded turbid phase and an isotropic phase (as with shorter fragments) and also an intermediate, somewhat turbid region. The concentration distribution in the isotropic phase is in satisfactory agreement with a simple extension of scaled particle theory in which semiflexible chains are equivalent to straight rods of the same length. The net intermolecular interactions, as inferred from the Zimm cluster integral, are purely repulsive.

Sequence-determined DNA separations.

The variation in electrophoretic mobility of DNA under conditions of marginal helix stability provides a useful means for investigation of the relation between the helix-random chain transition and base sequence in natural DNA and a powerful procedure for separation of DNA molecules according to sequence. The use of statistical mechanical theory for analysis of the transition equilibria together with new, simplified theoretical considerations on the effect of strand unravelling on mobility have shown that the gel behavior is predictable for known sequences. A number of the distinctive consequences of the theory and their correspondence with the properties of real molecules have been demonstrated.

DNA fragments differing by single base-pair substitutions are separated in denaturing gradient gels: correspondence with melting theory.

DNA fragments 536 base pairs long differing by single base-pair substitutions were clearly separated in denaturing gradient gel electrophoresis. Transversions as well as transitions were detected. The correspondence between the gradient gel measurements and the sequence-specific statistical mechanical theory of melting shows that mutations affecting final gradient penetration lie within the first cooperatively melting sequence.

Small RNA.

The illustration that accompanied the review by C. C. Albritton, Jr.

Torsional motion and elasticity of the deoxyribonucleic acid double helix and its nucleosomal complexes.

Torsional thermal oscillations of the DNA double helix within the electron paramagnetic resonance (EPR) time scale (10(-10)-10(-3) s) as indicated by a rigid, intercalating probe are much smaller in the spacer segment between nucleosomes in chromatin than in long, free DNA molecules. Still smaller DNA oscillation is indicated in intact nuclei and yet smaller if the nuclei have been treated with glutaraldehyde. The values of EPR measurements are not affected by the loading density of probe.

Separation of random fragments of DNA according to properties of their sequences.

The separation of DNA fragments by electrophoresis at high temperature in a denaturing gradient is independent of the length of the fragments. We have suggested that the basis of fragment separation is that each DNA molecule undergoes partial melting as it encounters a concentration of denaturants sufficient to melt its least stable sequence, while other sequences remain double stranded; in the partially melted configuration, DNA can continue migration only slowly. This model is consistent with the observation that fragments of lambda phage DNA cleaved by different restriction endonucleases reach the same final depth in the gel if they contain the same least-stable sequence.

Length-independent separation of DNA restriction fragments in two-dimensional gel electrophoresis.

When double helical DNA is exposed to conditions favoring partial melting in polyacrylamide gels, its electrophoretic mobility undergoes a sharp cooperative transition, resulting in a large reduction in mobility. In the present experiments, where the transition is effected at a uniform temperature of 60 degrees C in a concentration gradient of a urea-formamide mixture, each Eco RI fragment of lambda or E. coli DNA exhibits the mobility transition at a characteristic concentration of the denaturant.

A transition to a compact form of DNA in polymer solutions.

In the presence of over-threshold concentrations of simple neutral polymers and salts, DNA undergoes a cooperative change in its solution structure. Sedimentation studies at low DNA concentrations show that phage DNA molecules collapse into particles approaching the compactness of the contents of phage heads. The interaction between DNA and polymers is thought to be nonspecifically replusive.