Small RNA.

The illustration that accompanied the review by C. C. Albritton, Jr., of W. H. Goetzmann and K. Sloan's Looking Far North (Viking, New York, 1982) in the issue of 10 December, page 1109, should have been credited to the Bancroft Library, University of California, Berkeley, as well as to the book under review.

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. The resulting duplex DNA fragments containing random single-base substitutions are cloned, amplified as a population, and isolated from wild-type DNA by preparative denaturing gradient gel electrophoresis. The physical separation of mutant DNA fragments makes it possible to isolate and characterize large numbers of site-directed single-base substitutions in the absence of a phenotypic selection. This procedure should be generally applicable to the fine-structure genetic analysis of regulatory and protein-coding sequences.

A mitochondrial DNA deletion in normally aging and in Alzheimer brain tissue.

By quantitative polymerase chain reaction (PCR) of total cellular DNA, the known 4977 bp deletion in human mitochondrial DNA (mtDNA delta 4977) was not detected in rapidly dividing tissue such as placenta and lymphocytes, nor in brain tissue from fetuses and in frontal cortex from two individuals 24 and 56 years old. However, in frontal cortex from individuals 71-95 years 0.13% deleted/undeleted mtDNA was found, with no significant difference between Alzheimer patients (0.14%) and age-matched controls (0.12%). We hypothesize that the age-related accumulation of this deletion (and other expected deletions) contributes to the down-regulation of adenosine triphosphate (ATP) production in neurons and other non-dividing cells, a fundamental mechanism common to aging and Alzheimer's disease.

The effects of lithium, rubidium, cesium and magnesium ions on the close packing of persistence-length DNA fragments.

By application of scaled particle theory to persistence-length DNA fragments in sedimentation-equilibrium at speeds high enough to maintain close packing, the range of interhelical electrostatic repulsion was evaluated with LiCl, RbCl, CsCl, and MgCl2 as supporting electrolytes. Analysis of the data in terms of the Zimm cluster function confirmed that the net interaction between helices is purely repulsive in all cases. At constant ionic strength the electrostatic radius of the rod-like DNA decreases as the counterion changes from Li+ to Rb+ to Cs+. In contrast to univalent counterions, electrostatic radius increases with Mg2+ concentration, except at very low (mM) MgCl2 concentrations. All solutions undergo a reversible transition to a turbid, optically anisotropic phase at a slightly salt-dependent, critical DNA concentration, as observed previously for NaDNA.

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.

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.

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. Fragments carrying substitutions in domains melting at a higher temperature reach final gel positions indistinguishable from wild type. The gradient data and the sites of substitution bracket the boundary between the first domain and its neighboring higher-melting domain within eight base pairs or fewer, in agreement with the calculated boundary. The correspondence between the gradient displacement of the mutants and the calculated change in helix stability permits substantial inference as to the type of substitution. Excision of the lowest melting domain allows recognition of mutants in the next ranking domain.

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. The sudden retardation of fragments moving toward higher denaturant concentration in the gradient results in a pattern of sharpened zones in order depending upon nucleotide sequence, rather than size, and only very slightly dependent upon the time after the last fragment has been retarded. When combined with length-dependent electrophoresis in agarose in the perpendicular direction, this system provides a two-dimensional separation of fragments. The resolving power of the system is demonstrated by the clear resolution of over 250 fragments of the Eco RI digest of E. coli DNA. Corresponding fragments from an isogenic lambda lysogen of E. coli are found in the same positions, and additional fragments unique to the lysogen are evident.

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. A unique set of bands is produced from the electrophoresis of randomly fragmented DNA; this would be expected if there were a limited number of melting centers occupying discrete genetic loci. An intact DNA molecule penetrates about as deeply into the gel as the uppermost band after fragmentation; this would be expected only if the least-stable sequence controls the final depth of the whole molecule.

Preferential isolation of DNA fragments associated with CpG islands.

We describe a procedure for preferential isolation of DNA fragments with G+C-rich portions. Such fragments occur in known genes within or adjacent to CpG islands. Since about 56% of human genes are associated with CpG islands, isolation of these fragments permits detection and probing of many genes within much larger segments of DNA, such as cosmids or yeast artificial chromosomes, which have not been sequenced. Cloned DNA fragments digested with four restriction endonucleases were subjected to denaturing gradient gel electrophoresis. Long G+C-rich sections in fragments inhibit strand dissociation after the fragments reach retardation level in the gradient; such fragments are retained in the gel after most others disappear. Nucleotide sequences of the retained fragments show that about half of these fragments appear to be derived from CpG islands. Northern analysis indicated the presence of RNA complementary to most of the retained fragments. A heuristic approach to the relation between base sequence and the kinetics of strand dissociation of partly melted molecules appears to account for retention and nonretention. The expectation that CpG island fragments will be enriched among fragments retained in a denaturing gradient is supported by rate estimates based on melting theory applied to known sequences. This method, designated SPM for segregation of partly melted molecules, is expected to provide a means for convenient and efficient isolation of genes from unsequenced DNA.

Relaxation effects in the gel electrophoresis of DNA in intermittent fields.

The electrophoretic mobility of restriction fragments of lambda DNA in agarose gels declines if the field is intermittent rather than continuous, with a greater effect on the longer fragments. The changes are compatible with the assumption of two exponential relaxation processes for field-dependent configurational changes, one when the field is turned on and another when it terminates. The length dependence at the extrapolated limit of mobility for short pulses with long intervals corresponds closely to the simple inverse proportionality to length expected from theoretical considerations when the molecular configuration is not affected by the electric field. Simple intermittent fields would allow separation of longer molecules than can ordinarily be resolved. The relaxation times for both the change in conformation imposed by the field and the return to field-free conformation vary as approximately the second power of the length of the molecule, independent of the salt concentration or field strength and varying only slightly with gel density. These relations are not in good agreement with properties expected from reputation theory, and they suggest that a different mechanism must be invoked for the electrophoretic migration of long DNA molecules at ordinary values of field strength.