Pulsed-field electrophoresis: application of a computer model to the separation of large DNA molecules

Noise-Activated Fast Locomotion of DNA through the Frictional Landscape of Nanoporous Gels

It is hypothesized that nonlinear solid friction between the gel matrix and DNA molecules inhibits the motion of DNA through the nanopores of the gel during electrophoresis. In this article, it is demonstrated that external noise can alleviate the effect of solid friction, thus enhancing the mobility of DNA in an electrophoretic setting. In the presence of noise, the mobility of DNA increases by more than ∼113% compared to conventional electrophoresis. Although at a high power of noise, DNA exhibits Arrhenius kinetics, at a low power of noise, super-Arrhenius kinetics suggests the collective behavior of the activated motion of DNA molecules. A stochastic simulation following modified Langevin dynamics with the asymmetric pore size distribution of the agarose gel successfully predicts the mobility of DNA molecules and reveals the salient features of the overall dynamics. This "noise lubricity" may have a broader applicability from molecular to macroscopic locomotion.

Ultrafast, efficient separations of large-sized dsDNA in a blended polymer matrix by microfluidic chip electrophoresis: a design of experiments approach

Double-stranded (ds) DNA fragments over a wide size range were successfully separated in blended polymer matrices by microfluidic chip electrophoresis. Novel blended polymer matrices composed of two types of polymers with three different molar masses were developed to provide improved separations of large dsDNA without negatively impacting the separation of small dsDNA. Hydroxyethyl celluloses with average molar masses of ∼27  kDa and ∼1  MDa were blended with a second class of polymer, high-molar mass (∼7  MDa) linear polyacrylamide. Fast and highly efficient separations of commercially available DNA ladders were achieved on a borosilicate glass microchip. A distinct separation of a 1-kb DNA extension ladder (200-40,000  bp) was completed in 2  min. An orthogonal design of experiments was used to optimize experimental parameters for DNA separations over a wide size range. We find that the two dominant factors are the applied electric field strength and the inclusion of a high concentration of low-molar mass polymer in the matrix solution. These two factors exerted different effects on the separations of small dsDNA fragments below 1  kbp, medium dsDNA fragments between 1 and 10  kbp, and large dsDNA fragments above 10  kbp.

Dicentric breakage at telomere fusions

Nonhomologous end-joining (NHEJ) inhibition at telomeres ensures that native chromosome ends do not fuse together. But the occurrence and consequences of rare telomere fusions are not well understood. It is notably unclear whether a telomere fusion could be processed to restore telomere ends. Here we address the behavior of individual dicentrics formed by telomere fusion in the yeast Saccharomyces cerevisiae. Our approach was to first stabilize and amplify fusions between two chromosomes by temporarily inactivating one centromere. Next we analyzed dicentric breakage following centromere reactivation. Unexpectedly, dicentrics often break at the telomere fusions during progression through mitosis, a process that restores the parental chromosomes. This unforeseen result suggests a rescue pathway able to process telomere fusions and to back up NHEJ inhibition at telomeres.

Effect of the matrix on DNA electrophoretic mobility

DNA electrophoretic mobilities are highly dependent on the nature of the matrix in which the separation takes place. This review describes the effect of the matrix on DNA separations in agarose gels, polyacrylamide gels and solutions containing entangled linear polymers, correlating the electrophoretic mobilities with information obtained from other types of studies. DNA mobilities in various sieving media are determined by the interplay of three factors: the relative size of the DNA molecule with respect to the effective pore size of the matrix, the effect of the electric field on the matrix, and specific interactions of DNA with the matrix during electrophoresis.

Pulsed-field gel electrophoresis for long-range restriction mapping

This unit describes procedures for generating long-range restriction maps of genomic DNA and for analysis of large insert clones. The basic protocol details restriction digestion of agarose-embedded DNA, PFGE separation, Southern transfer, and hybridization. Support protocols describe the preparation of high-molecular-weight genomic DNA samples in agarose blocks and in agarose microbeads, respectively. Additional support protocols describe the preparation of DNA size standards from l phage and two yeast species, Saccharomyces cerevisiae and Schizosaccharomyces pombe. An alternative method of preparing S. cerevisiae size standards using lithium dodecyl sulfate (LiDS) solubilization is provided. The final protocol details the preparation of BAC DNA suitable for digestion, mapping, and sequencing.

Apoptotic death of human lympholeukemia HL-60 cells resultant from combined effect of cobalt octa-4,5-carboxyphthalocyanine propylenglycol ether and ascorbate

Cobalt octa-4,5-carboxyphthalocyanine propylenglycol ether proposed for antitumor therapy potentiates the cytotoxic effect of ascorbate on HL-60 human leukemia cells. Combination of these substances caused the formation of H2O2 in the medium and initiated apoptotic death of cells. Catalase abolished the cytotoxic effect of this combination. The results indicate that binary catalytic system of this combination can be regarded as a potential antitumor agent.

A reliable method to display authentic DNase I hypersensitive sites at long-ranges in single-copy genes from large genomes

The study of eukaryotic gene transcription depends on methods to discover distal cis-acting control sequences. Comparative bioinformatics is one powerful strategy to reveal these domains, but still requires conventional wet-bench techniques to elucidate their specificity and function. The DNase I hypersensitivity assay (DHA) is also a method to identify regulatory domains, but can also suggest their function. Technically however, the classical DHA is constrained to mapping gene loci in small increments of approximately 20 kb. This limitation hinders efficient and comprehensive analysis of distal gene regions. Here, we report an improved method termed mega-DHA that extends the range of existing DHAs to facilitate assaying intervals that approach 100 kb. We demonstrate its feasibility for efficient analysis of single-copy genes within a large and complex genome by assaying 230 kb of the human ADAMTS14-perforin-paladin gene cluster in four experiments. The results identify distinct networks of regulatory domains specific to expression of perforin and its two neighboring genes.

Nanoparticle-filled capillary electrophoresis for the separation of long DNA molecules in the presence of hydrodynamic and electrokinetic forces

We report the analysis of long DNA molecules by nanoparticle-filled capillary electrophoresis (NFCE) under the influences of hydrodynamic and electrokinetic forces. The gold nanoparticle (GNP)/polymer composites (GNPPs) prepared from GNPs and poly(ethylene oxide) were filled in a capillary to act as separation matrices for DNA separation. The separations of lambda-DNA (0.12-23.1 kbp) and high-molecular-weight DNA markers (8.27-48.5 kbp) by NFCE, under an electric field of -140 V/cm and a hydrodynamic flow velocity of 554 microm/s, were accomplished within 5 min. To further investigate the separation mechanism, the migration of lambda-DNA was monitored in real time using a charge-coupled device (CCD) imaging system. The GNPPs provide greater retardation than do conventional polymer media when they are encountered during the electrophoretic process. The presence of interactions between the GNPPs and the DNA molecules is further supported by the fluorescence quenching of prelabeled lambda-DNA, which occurs through an energy transfer mechanism. Based on the results presented in this study, we suggest that the electric field, hydrodynamic flow, and GNPP concentration are the three main determinants of DNA separation in NFCE.

Nanomaterials and chip-based nanostructures for capillary electrophoretic separations of DNA

Capillary electrophoresis (CE) and microchip capillary electrophoresis (MCE) using polymer solutions are two of the most powerful techniques for the analysis of DNA. Problems, such as the difficulty of filling polymer solution to small separation channels, recovering DNA, and narrow separation size ranges, have put a pressure on developing new techniques for DNA analysis. In this review, we deal with DNA separation using chip-based nanostructures and nanomaterials in CE and MCE. On the basis of the dependence of the mobility of DNA molecules on the size and shape of nanostructures, several unique chip-based devices have been developed for the separation of DNA, particularly for long DNA molecules. Unlike conventional CE and MCE methods, sieving matrices are not required when using nanostructures. Filling extremely low-viscosity nanomaterials in the presence and absence of polymer solutions to small separation channels is an alternative for the separations of DNA from several base pairs (bp) to tens kbp. The advantages and shortages of the use of nanostructured devices and nanomaterials for DNA separation are carefully addressed with respect to speed, resolution, reproducibility, costs, and operation.

Entropic recoil separation of long DNA molecules

A novel technique that can rapidly separate long-strand polymers according to length is presented. The separation mechanism is mediated by a confinement-induced entropic force at the abrupt interface between regions of vastly different configuration entropy. To demonstrate this technique, DNA molecules were partially inserted into a dense array of nanopillars (an entropically unfavorable region) using a pulsed electric field and allowed to relax to their natural state by removal of the field. Molecules of dissimilar lengths (T2 and T7 coliphage DNA) were inserted into this region in such a way that shorter molecules were fully inserted in this region, while longer molecules remained partially across the interface. The longer T2 molecules were observed to recoil entirely out of the pillar array, leaving the shorter T7 molecules inserted, and effecting separation of the two species in a single step. To show how this method can be used for separation of unknown samples, the inserting electric field was pulsed for progressively longer times, allowing passage of progressively longer molecules and producing the equivalent of a conventional electropherogram. The effects limiting resolution in this device are discussed, and the expected separating power of a multistage device is reported. The extracted resolution and running separation time compare favorably with current conventional separation techniques.

Mechanism of DNA hydrodynamic separation in chromatography

An alternative chromatographic procedure for the separation of large double-stranded DNA molecules was discovered recently and called "slalom chromatography". This fractionation is based on a new hydrodynamic process that is determined by the progression of the mobile-phase flow through the interstitial spaces created between the highly packed particles inside the column. Here, the separation is treated as the result of a slowing down of the large double-stranded DNA fragments in relation to their size with the flow direction changing around the particles. A model, based on the concept derived from the reorientation time of macromolecules, was adequate to describe the hydrodynamic phenomenon. This model constitutes an attractive tool to enhance the expansion of this chromatographic procedure and provide valuable information on the dynamic behavior of biological polymers.

Reptation theories of electrophoresis

In this review, we present the main aspects of the reptation theory, which has provided an essential insight into the processes at work during DNA electrophoretic separation in gels. We avoid mathematical developments, and rely as much as possible on an intuitive description. We first present the original biased reptation model, which assumes that the DNA threads its way as a "worm" of fixed length among the fibers of the gel. We then introduce a more recent version, the model of Biased Reptation with Fluctuations (BRF), which allows for longitudinal flexibility along the DNA. We then propose a quantitative comparison with experiments performed in constant field, and discuss the application of reptation theories to pulsed field techniques either with crossed fields or with field inversion. We also discuss at some length the different experiments that led to a criticism of reptation ideas, such as orientation measurements and videomicroscopy. Finally, we use these experiments together with various computer simulations developed recently for gel electrophoresis, to propose a more realistic qualitative description of DNA motion in gels, and we discuss what elements in this motion are relevant to reptation and what processes are not included in present analytical models.

Preparation, manipulation, and pulse strategy for one-dimensional pulsed-field gel electrophoresis (ODPFGE)

The underlying principles for zero-integrated-field electrophoresis (ZIFE) pulses and more general forward-biased pulse schemes are reviewed for one-dimensional pulsed-field gel electrophoresis (ODPFGE) separations of large DNA molecules. Detailed descriptions of materials, preparation protocols, hardware requirements, and procedures are given. A variety of gel pictures for known yeast DNA markers are shown.

DNA stability and survival of Bacillus subtilis spores in extreme dryness

The inactivation of Bacillus subtilis spores during long-term exposure (up to several months) to extreme dryness (especially vacuum) is strain-dependent, through only to a small degree. During a first phase (lasting about four days) monolayers of spores lose about 20% of their viability, regardless of the strain studied. During this phase loss in viability can be equally attributed both to damages of hydrophobic structures (membranes and proteins) and DNA. During a second phase lasting for the remaining time of experimental observation (weeks, months and years) the loss in viability is slowed. A viability of 55% to 75% (depending on the strain) is attained after a total exposure of 36 days. The loss in viability during the second phase can be correlated with the occurrence of DNA double strand breaks. Also covalent DNA-protein cross-links are formed by vacuum exposure. If the protein moiety of these cross-links is degraded by proteinase K-treatment in vitro additional DNA double strand breaks result. The data are also discussed with respect to survival on Mars and in near Earth orbits.

Arbitrarily primed polymerase chain reaction as a rapid method to differentiate crossed from independent Pseudomonas cepacia infections in cystic fibrosis patients

We used DNA fingerprinting by the arbitrarily primed polymerase chain reaction (AP-PCR) technique for an epidemiological investigation of 23 Pseudomonas cepacia isolates obtained from 11 cystic fibrosis (CF) patients attending our CF center. This approach was compared with ribotyping, pulsed-field gel electrophoresis (PFGE), and conventional phenotypic typing. AP-PCR and ribotyping were identical in resolving power, since the two methods generated four different profiles and identified the same group of strains. Six patients on the one hand and four on the other harbored strains of the same genotype, thus raising the possibility of either patient-to-patient transmission or acquisition from a common hospital environmental source. PFGE results were in good agreement with those of the other two methods, but PFGE seems more discriminative since it generated a fifth profile for a single strain in a group of four. Our results show in vivo stability for the three methods during a period extending from 3 to 41 months. These genotypic techniques are particularly promising for clinical laboratories to help to clarify the epidemiology of P. cepacia in CF patients. The AP-PCR method constitutes an easier alternative to the well-established ribotyping method. AP-PCR provides the quickest results with minimal technical complexity. However, our results suggest that it is less discriminative than the labor-intensive PFGE method.

Biased sinusoidal field gel electrophoresis for the separation of large DNA

In agarose gel electrophoresis, in a steady, continuous field, it is well known that the mobility mu, versus size M relation for linear DNAs (L-DNAs) can be divided into three regimes: Ogston regime I for small DNAs, where M dependence of mu, is weak; entangled but unstretched regime II for intermediate-size L-DNAs (of M < 20 kbp), where mu, sigma M-1 so that efficient fractionation is possible; and entangled and stretched regime III for large L-DNAs, where M dependence of mu s is again weak. Although mu s and the regimen boundaries can be altered by adjusting the gel concentration Cgel and/or the field strength E, the features of the M dependence of mu s are essentially unchanged. As to the effect of DNA topology on mu s, we found that in dilute gels (Cgel < 1.0 wt%) coiled, circular DNAs (C-DNAs) of 2-7 kbp size migrate faster than L-DNAs of comparable size, while in concentrated gels (Cgel > 1.5 wt%) C-DNAs migrate much slower than L-DNAs. To facilitate separation of large DNAs in the regime III range, we proposed biased sinusoidal field gel electrophoresis (BSFGE), which utilizes a sinusoidal field of strength Es and frequency f superposed on a steady bias field of strength Eb.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of irradiation conditions on the measurement of DNA double-strand breaks by pulsed-field gel electrophoresis

The induction of gamma-ray-induced DNA double-strand breaks (DSBs) determined by pulsed-field gel electrophoresis was compared in the DNA of intact Chinese hamster ovary (CHO) cells imbedded in agarose plugs, and in the isolated DNA of agarose-imbedded CHO cells that had been lysed before irradiation, to determine whether these irradiation conditions would influence their measurement. DSB-induction in irradiated cells or isolated DNA was measured as the loss of DNA from the plug compared with the unirradiated control. Chromatin protein was completely digested by the lysis buffer and as such did not affect DNA migration upon electrophoresis, whereas concentrations of EDTA as low as 10(-5) M affected the induction of DSBs in the isolated DNA. The gel plugs required several hours of washing with PBS to remove the contaminating EDTA from the lysis buffer. Once the residual EDTA was removed, DNA DSB induction as a function of dose was 70 times greater in isolated DNA than in the DNA of intact cells.

Methods for pulsed-field gel electrophoresis

The term pulsed-field gel electrophoresis (PFGE) is used as an acronym to indicate any technique that resolves (large) DNA molecules by continuous reorientation. It bridges the resolution gap between cytogenetic methods (> 5 Mb) and DNA analysis (< 50 kb). Initially, PFGE was used to study the chromosomal content of unicellular eukaryotic organisms of interest to genetic research and population health. Later, PFGE was used to construct megabase maps of segments of the human genome. Successfull utilization of PFGE requires the availability of very high-molecular weight DNA. This article describes the modification of standard DNA protocols necessary to handle large DNA molecules, based on its encapsidation in agarose.

DNA-strand breaks limit survival in extreme dryness

The inactivation of the anhydrobiotic organisms Bacillus subtilis (spores) and Deinococcus radiodurans during long-term exposure (up to several weeks) to extreme dryness (especially vacuum) is correlated with an increase in the number of DNA-strand breaks and other DNA lesions. Survival finally depends on the repair of DNA damages. Exposure of anhydrobiotic organisms to extreme dryness (e.g. on Mars or in space) for geological times will lead to so extended DNA lesions that recovery is extremely unlikely.

Microscopic behaviour of DNA during electrophoresis: electrophoretic orientation

The study of the behaviour of DNA when subjected to electric fields poses several intriguing problems of fundamental physico-chemical importance. Electric field (Kerr effect) orientation of DNA in free solution as well as migration of DNA in gel electrophoresis are two well-established, but so far rather separate, research fields. Whereas the first one has been generally concerned with basic structural and dynamical properties of DNA (Charney, 1988), the second is closely related to techniques of molecular biology (for a review on DNA electrophoresis, see stellwagen 1987).

Measurement of DNA double-strand breaks in CHO cells at various stages of the cell cycle using pulsed field gel electrophoresis: calibration by means of 125I decay

Experiments were performed to calibrate a recently developed pulsed field gel electrophoresis assay, the asymmetric field inversion gel electrophoresis (AFIGE), for the measurement of double-strand breaks (dsb) in the DNA of mammalian cells. Calibration was carried out by means of 125I decay accumulation under conditions preventing repair, and is based on the observation that each 125I decay in the DNA produces approximately one dsb. Iodine was incorporated into DNA in the form of 5'-iododeoxyuridine and decay accumulation was allowed in cells kept frozen at -80 degrees C. Since widely different DNA damage dose-response curves were obtained in cells exposed to X-rays in various phases of the cell cycle, calibration was performed using synchronized populations of cells that were allowed to accumulate DNA damage in G1, G1/S, mid-S, and G2 + M. For this purpose the fraction of activity (in DNA) released from the plug (FAR) was measured and correlated to the number of 125I decays accumulated during the elapsed period of time. Fluctuations in the FAR per 125I decay were observed throughout the cell cycle that were similar to those previously reported for the FAR per Gy of X-rays. Comparison of the FAR per 125I decay with the FAR per Gy gave an induction of 21 +/- 3, 31 +/- 3, 21 +/- 3 and 26 +/- 8 dsb per Gy per diploid DNA complement for G1, G1/S, S, and G2 + M cells, respectively. The results suggest that the observed fluctuations in the FAR per Gy throughout the cycle reflect cell-cycle-associated differences in the physicochemical properties of the DNA molecules that alter their electrophoretic mobility, rather than variations in the induction of dsb per Gy, i.e. the sensitivity of the assay fluctuates throughout the cycle. We propose that similar phenomena underlie the observed fluctuations throughout the cell cycle in the fraction of activity eluted per Gy in the non-unwinding filter elution assay. 125I decays accumulated at 4 degrees C in partly purified DNA from cells embedded in agarose plugs and lysed immediately, gave FAR identical to those obtained with cells kept frozen. This finding suggests that indirect effects do not significantly contribute to DNA damage induction by 125I decay, and indicate that calibration of electrophoresis techniques for dsb measurements can be carried out using this simplified protocol.

Detection of DNA double-strand breaks in synchronous cultures of CHO cells by means of asymmetric field inversion gel electrophoresis

A pulsed field gel electrophoresis technique, asymmetric field inversion gel electrophoresis (AFIGE), was used to evaluate induction by X-rays of DNA damage in CHO cells. The fraction of DNA activity released from the plug (FAR) was used as a measure for the amount of radiation-induced DNA damage, predominantly DNA double-strand breaks (dsb) (Stamato and Denko 1990), and was determined at various stages of growth and phases of the cell cycle in a range of doses between zero and 70 Gy. The FAR per unit dose fluctuated throughout the cell cycle and was high for cells irradiated in G1; it decreased as cells entered S and reached a minimum in the middle of this phase. The FAR per unit dose increased again as cells progressed towards the end of S, and reached values in G2 similar to those measured in G1. When damage was introduced into DNA by means of 125I decay similar fluctuations in the FAR per decay were observed throughout the cell cycle, suggesting that the variations in the FAR per unit of radiation dose observed throughout the cell cycle do not derive from alterations in the induction of dsb. The fluctuations in the FAR per unit dose throughout the cell cycle were quantitatively similar to the fluctuations in the fraction of activity eluted in irradiated cells assayed by the non-unwinding filter elution assay throughout the cycle (Okayasu et al. 1988), and suggest that both techniques respond to similar DNA replication-associated alterations of the biophysical and/or biochemical properties of the DNA molecule. It is concluded that caution needs to be exercised before differences observed in the FAR between different cell lines or between various phases of the cell cycle after exposure to a given dose of radiation are interpreted as suggesting differences in the induction of DNA dsb.

Physical analysis and mapping of the Mycoplasma pneumoniae chromosome

Field inversion gel electrophoresis was used for analysis of the chromosome of Mycoplasma pneumoniae. The restriction endonuclease SfiI (5'-GGCCNNNNNGGCC-3') generated 2 M. pneumoniae DNA fragments of approximately 437 and 357.5 kilobase pairs (kbp), whereas 13 restriction fragments ranging in size from 2.4 to 252.0 kbp resulted from digestion with ApaI (5'-GGGCCC-3'). Totaling the sizes of the individual restriction fragments from digestion with SfiI or ApaI yielded a genome size of 794.5 or 775.4 kbp, respectively. A physical map of the M. pneumoniae chromosome was constructed by using a combination of techniques that included analysis by sequential or partial restriction endonuclease digestions and use as hybridization probes of cloned M. pneumoniae DNA containing ApaI sites and hence overlapping adjacent ApaI fragments. Genetic loci for deoC, rrn, hmw3, and the P1 gene were identified by using cloned DNA to probe ApaI restriction fragment profiles.

Genome size of Myxococcus xanthus determined by pulsed-field gel electrophoresis

Genomic DNA of the myxobacterium Myxococcus xanthus was digested with the rare cutting restriction endonuclease AseI or SpeI, and the restriction products were separated by pulsed-field gel electrophoresis. Transposons Tn5-132 and Tn5 lac, which contain AseI restriction sites, were used to determine the number of restriction fragments in each band. The size of the genome was determined by adding the molecular sizes of the restriction products. The genomes of strains DK101, MD2, and DZF1 have identical restriction patterns and were estimated to be 9,454 +/- 101 kilobase pairs from the AseI digestions and 9,453 +/- 106 kilobase pairs from the SpeI digestions. DK1622, which was derived from DK101 by treatment with UV light, has suffered a 220- to 222-kilobase-pair deletion that removed an AseI and an SpeI restriction site. The deleted DNA may consist exclusively of Mx alpha-associated sequences.

Construction of the physical map for three loci in chromosome band 13q14: comparison to the genetic map

Pulsed-field gel electrophoresis (PFGE) and deletion mapping are being used to construct a physical map of the long arm of human chromosome 13. The present study reports a 2700-kilobase (kb) Not I long-range restriction map encompassing the 13q14-specific loci D13S10, D13S21, and D13S22, which are detected by the cloned DNA markers p7D2, pG24E2.4, and pG14E1.9, respectively. Analysis of a panel of seven cell lines that showed differential methylation at a Not I site between D13S10 and D13S21 proved physical linkage of the two loci to the same 875-kb Not I fragment. D13S22 mapped to a different Not I fragment, precluding the possibility that D13S22 is located between D13S10 and D13S21. PFGE analysis of Not I partial digests placed the 1850-kb Not I fragment containing D13S22 immediately adjacent to the 875-kb fragment containing the other two loci. The proximal rearrangement breakpoint in a cell line carrying a del13(q14.1q21.2) was detected by D13S21 but not by D13S10, demonstrating that D13S21 lies proximal to D13S10. Quantitative analysis of hybridization signals of the three DNA probes to DNA from the same cell line indicated that only D13S10 was deleted, establishing the order of these loci to be cen-D13S22-D13S21-D13S10-tel. Surprisingly, this order was estimated to be 35,000 times less likely than that favored by genetic linkage analysis.

Study of large DNA fragments in agarose gels by transient electric birefringence

The pulsed-field gel electrophoresis (PFG) is a newly developing technique used in the fractionation of large DNA fragments. Advances in PFG demand a better understanding in the corresponding mechanisms of DNA dynamics in the gel network. Detailed experiments are needed to verify and to extend existing theoretical predictions as well as to find optimum conditions for efficient separation of large DNA fragments. In the present study, deformation of large DNA fragments (40-70 kilobase pairs) imbedded in agarose gels were investigated by using the transient electric birefringence (TEB) technique under both singular polarity and bipolarity electric pulses at low applied electric field strengths (E less than or equal to 5 V/cm). The steady-state optical retardation (delta s) of DNA molecules is linearly proportional to E2. At a given E, the amplitude of optical retardation [delta(t)] increases monotonically with the pulse width (PW) and then reaches a plateau value [delta(t = 0) = delta s] where t = 0 denotes the time when the applied field is turned off or reversed. The field-free decay time (tau-a few minutes) is several orders of magnitudes slower than that from previous TEB observations using high electric field strengths (E-kV/cm) and short pulse widths (PW-ms). The degree of deformation (stretching and orientation) and the time of restoration to the equilibrium conformation of overall DNA chains have been related to delta and tau. In field inversion measurements, exponentially rising and linearly falling of birefringence signals in the presence of forward/inverse applied fields were observed. The rising and falling of birefringence signals were reproducible under a sequence of alternating pulses. Comparison of our results with literature findings and discussions with theories are presented.

Molecular detrapping and band narrowing with high frequency modulation of pulsed field electrophoresis

In high electric fields, megabase DNA fragments are found to be trapped, i.e. to enter or migrate in the gel only very slowly, if at all, leading to very broad electrophoretic bands and loss of separation. As a consequence, low electric fields are usually used to separate these molecules by pulsed field electrophoretic methods. We report here that high-frequency pulses eliminate the molecular trapping found in continuous fields. When high frequency pulses are used to modulate the longer pulses used in pulsed field electrophoresis, narrower bands result, and higher fields can be used. We suggest that this is due to effects that occur on the length scale of a single pore.

Genetic imprinting suggested by maternal heterodisomy in nondeletion Prader-Willi syndrome

Prader-Willi syndrome (PWS) is the most common form of dysmorphic genetic obesity associated with mental retardation. About 60% of cases have a cytological deletion of chromosome 15q11q13 (refs 2, 3). These deletions occur de novo exclusively on the paternal chromosome. By contrast, Angelman syndrome (AS) is a very different clinical disorder and is also associated with deletions of region 15q11q13 (refs 6-8), indistinguishable from those in PWS except that they occur de novo on the maternal chromosome. The parental origin of the affected chromosomes 15 in these disorders could, therefore, be a contributory factor in determining their clinical phenotypes. We have now used cloned DNA markers specific for the 15q11q13 subregion to determine the parental origin of chromosome 15 in PWS individuals not having cytogenetic deletions; these individuals account for almost all of the remaining 40% of PWS cases. Probands in two families displayed maternal uniparental disomy for chromosome 15q11q13. This is the first demonstration that maternal heterodisomy--the presence of two different chromosome 15s derived from the mother--can be associated with a human genetic disease. The absence of a paternal contribution of genes in region 15q11q13, as found in PWS deletion cases, rather than a mutation in a specific gene(s) in this region may result in expression of the clinical phenotype. Thus, we conclude that a gene or genes in region 15q11q13 must be inherited from each parent for normal human development.

CHEF electrophoresis, a sensitive technique for the determination of DNA double-strand breaks

It has been demonstrated that clamped homogeneous electrical field (CHEF) electrophoresis is a suitable method for the determination of DNA double-strand breaks in Chinese hamster ovary (CHO) cells. It allows the separation of DNA molecules up to 10 Mbp. The fraction of DNA fragments of this size is correlated with the number of radiation induced double-strand breaks. The resolution limit of the technique is equivalent to the effect of about 1 Gy (gamma-rays). Double-strand break repair was monitored after irradiation with Co-60 gamma rays and the repair time constant determined to t1/2 = 30-35 min. In combination with the detection of DNA by fluorescence, CHEF electrophoresis provides an easy and sensitive method for the determination of double-strand break repair which does not require the radioactive labelling of cells.

The biased reptation model of DNA gel electrophoresis: mobility vs molecular size and gel concentration

The biased reptation model provides a good framework for interpreting the results of continuous field DNA electrophoresis experiments performed in agarose gels. Here we discuss the main features of the mobility-molecular size and mobility-gel concentration diagrams as obtained from new extensive computer simulations of the model. Our aim is to suggest a global and coherent picture of this widely used yet poorly understood experimental technique, and to point out the areas where a systematic experimental study is still needed.

Orientational dynamics of T2 DNA during agarose gel electrophoresis: influence of gel concentration and electric field strength

The understanding, on a molecular level, of the mechanisms responsible for the improved separation in DNA gel electrophoresis when using modulated electric fields requires detailed information about conformational distribution and dynamics in the DNA/gel system. The orientational order due to electrophoretic migration ("electrophoretic orientation") is an interesting piece of information in this context that can be obtained through linear dichroism spectroscopy [M. Jonsson, B. Akerman, and B. Nordén, (1988) Biopolymers 27, 381-414]. The technique permits measurement of the orientation factor S of DNA (S = 1 corresponds to perfect orientation) within an electrophoretic zone in the gel during the electrophoresis. It is reported that the degree of orientation of T2 DNA [170 kilo base pairs (kpb)] is considerable (S = 0.17 in 1% agarose at 10 V/cm) compared to relatively modest orientations of short fragments found earlier (for 23-kbp DNA, S = 0.03 in 1% agarose at 10 V/cm), showing that large DNA coils are substantially deformed during the migration. Growth and relaxation dynamics of the orientational order of the T2 DNA are also reported, as functions of gel concentration (0.3-2%), electric field strength (0-40 V/cm), and pulse characteristics. The rise profile of the DNA orientation, when applying a constant field, is a nonmonotonic function that displays a pronounced overshoot, followed by a minor undershoot, before it reaches steady-state orientation (after 12 s in 1% agarose, 9 V/cm). The orientational relaxation in absence of field shows a multiexponential decay in a time region of some 10 s, when most of the DNA anisotropy has disappeared. A surprising phenomenon is a memory over minutes of the DNA/gel system to previous pulses: with two consecutive rectangular pulses (of the same polarity), the orientational overshoot and undershoot as a response to the second pulse are significantly reduced compared to the first pulse. The time required to recover 90% of their amplitudes is typically 1200 s (1% agarose, 9 V/cm), which may be compared to the time required to relax 90% of the DNA orientation, which is only 6 s. The major part of the over- and undershoot recovery is thus a reorganization of a system in which DNA is already randomly oriented. The different response amplitudes and relaxation times, including the amplitude and recovery time of the overshoot, of the orientational order of DNA in the electrophoretic gel have been studied as functions of gel concentration and field strength. The results are discussed against relevant theories of polymer dynamics.

A systematic study of field inversion gel electrophoresis

The mobilities of oligomers of phage lambda DNA and of yeast chromosomes in agarose gels during field inversion gel electrophoresis (FIGE) were measured at different pulse times and electric fields. Also the ratios between forward and backward pulse times and/or field gradients were varied. The problem of 'band inversion' during FIGE, leading to an ambiguity in the mobility of large DNA fragments, was solved by using two dimensional gel electrophoresis with different parameters in the first and second dimension. The results are compared with those obtained with other pulsed electrophoresis systems and with a theoretical model.

The acceleration of linear DNA during pulsed-field gel electrophoresis

The velocity and orientation of T4 and lambda DNA have been measured for the first 20 s during pulsed-field gel electrophoresis in order to clarify the DNA motions that occur. For a square pulse with field strength E = 10 V/cm, the velocity of lambda DNA increases gradually to 10.5 microns/s in 1.0 s, declines to 8.6 microns/s, and then rises to a plateau value of 9.3 microns/s after 4 s. T4 DNA behaves similarly, but more slowly. Parallel measurements of fluorescence-detected linear dichroism show that the DNA becomes substantially aligned with its chain axis parallel to the electrophoretic field E after the pulse is applied. The alignment also shows an overshoot, an undershoot, and a plateau comparable to those seen for velocity. When the field strength increases, both the velocity and the alignment reach their peaks more quickly. For all field strengths and both molecular weights, the velocity peak occurs when the molecular center of mass has moved 0.3 to 0.5 L, where L is the chain contour length. A qualitative model is provided.

Separation of large DNA molecules by pulsed-field gel electrophoresis. A review of the basic phenomenology

Pulsed-field gel electrophoresis is a method of separating large DNA molecules. The distinctive feature of this method is that the direction of the electric field is changed periodically. During the five years since Schwartz and Cantor introduced this technique, there has been dramatic progress in pulsed-field instrumentation and in associated electrophoretic methods. Progress has been driven by practical experience with little guidance from theory. In this review, the basic phenomenology of pulsed-field gel electrophoresis is summarized and some speculations are advanced about possible molecular mechanisms.

Monte Carlo simulation of DNA electrophoresis

This paper describes an attempt to study the electrophoresis mobility of a DNA molecule in a gel by means of a Monte Carlo simulation. We find that the electrophoresis mobility mu can be well described by the empirical equation mu v kappa 1/N + kappa 2E2 with N being the number of monomers of the model chain and E being the applied field. For small E the data can merge into the linear response result mu = kappa 1/N. The paper also discusses necessary extensions of the present approach.

Reptation-breathing theory of pulsed electrophoresis: dynamic regimes, antiresonance and symmetry breakdown effects

We apply the concepts of tube and reptation to the pulsed electrophoresis of DNA, considering both biased reptation and "breathing" modes (internal modes of the chain). Using suitable preaveraging approximations, analytical expressions are derived which relate displacement in crossed field electrophoresis to molecular weight, field strength, field period, pore size of the gel, and the angle between the field. These expressions provide scaling laws for the change of mobility when one (or more) of the parameters is varied as well as "universal" velocity versus molecular weight versus pulse time curves. These results are quantitatively compared with experiments. At some point which depends on field angle, field strength and chain length, however, we predict a failure of this model due to symmetry breakdown and loss of ergodicity. Qualitatively, this should lead to considerable band spreading and/or splitting of the highest DNA bands into two bands migrating sideways from the diagonal. The case of field inversion is also investigated. It is shown that only breathing modes can explain the strong differences in mobility experienced by chains of different length when opposite fields of equal amplitude are applied: the "trapping" of chains in conformations of low mobility is associated with an antiresonance-like coupling between the external field and the internal modes.

Molecular detection of chromosomal translocations that disrupt the putative retinoblastoma susceptibility locus

A candidate DNA sequence with many of the properties predicted for the retinoblastoma susceptibility (RB1) locus has been cloned (S. H. Friend, R. Bernards, S. Rogelj, R. A. Weinberg, J. M. Rapaport, D. M. Albert, and T. P. Dryja, Nature [London] 323:643-645, 1986). The large size of this gene (ca. 200 kilobases [kb]) and its multiple dispersed exons (Wiggs et al., N. Engl. J. Med. 318:151-157, 1988) complicate molecular screening strategies important in prenatal and presymptomatic diagnosis and in carrier detection. Here we used field inversion gel electrophoresis (FIGE) to construct a restriction map of approximately 1,000 kb of DNA surrounding the RB1 locus and to detect the translocation breakpoints in three retinoblastoma patients. DNA probes from either the 5' or 3' end of the gene were used to detect a 250-kb EagI restriction fragment in DNA from unaffected individuals. Both probes identified an additional hybridizing fragment in the DNA from each patient, permitting the breakpoints in all three to be mapped within the cloned RB1 gene. Analysis of the breakpoint in one translocation cell line allowed the RB1 gene to be oriented with its 5' end toward the centromere. The 5' end of the gene also appeared to be associated with a clustering of sites for several infrequently cleaving restriction enzymes, indicating the presence of an HpaII tiny fragment island. The detection and mapping of the translocation breakpoints of all three retinoblastoma patients to within the putative RB1 gene substantiated the authenticity of this candidate sequence and demonstrated the utility of FIGE in detecting chromosomal rearrangements affecting this locus.

Quantitative calibration and use of DNA probes for investigating chromosome abnormalities in the Prader-Willi syndrome

Ten genomic DNA probes, subcloned from inserts derived from a phage library constructed from the DNA of flow-sorted chromosomes, have now been mapped to locations within 15q11-15q13. By dosage blotting and densitometry, 5 of these probes map to the 15q11.2-15q12 segment missing in one 15 chromosome of a Prader-Willi syndrome (PWS) patient with a prominent cytological deletion. A sixth probe most likely maps to the same region. The other 4 probes map outside of this segment but within 15q11-15q13. Several of the 15q11.2-15q12 probes, and a cDNA probe homologous to one, have been used to test the DNA from 8 patients exhibiting a wide range of the clinical manifestations expected for PWS patients. DNA deletion was observed in all 3 patients with cytological 15q1 deletions as well as in a patient with an unbalanced (Y;15) translocation. DNA from 1 PWS patient with an unbalanced (5;15) translocation and an inverted duplication of the short arm and proximal long arm of 15 showed at least 1 and possibly 2 extra copies of each genomic probe tested. In the other 3 patients with no cytological deletions, no DNA deletions were found. Thus, the molecular probes described can be used in most PWS patients to analyze the region of proximal 15q implicated in this syndrome.

Sieving of double-stranded DNA during agarose gel electrophoresis

Agarose gel electrophoresis is used to fractionate linear, double-stranded DNA by its length. Sieving of the gel is the cause of this fractionation and has been investigated by developing theoretical models and by quantifying sieving observed during electrophoresis. Here are reviewed the following aspects of the fractionation of linear, double-stranded DNA by agarose gel electrophoresis: (1) the basic observations that qualitatively characterize these fractionations, (2) evidence for the deformation of DNA's random coil, (3) quantitative analysis of the relationship of observed electrophoretic mobility to the DNA's length, (4) theoretical models that have been developed to explain data presented in Sections 1-3, (5) observations not yet quantitatively explained by models, and (6) some aspects of the use of a variable electrical field (pulsed-field gel electrophoresis) to improve separations.

Effect of nonparallel alternating fields on the mobility of DNA in the biased reptation model of gel electrophoresis

Chromosome-size DNA molecules can now be separated using a variety of pulsed field gel electrophoresis techniques. In this article, we study the predictions of the biased reptation model concerning the effect of two pulsed fields, making an arbitrary angle, on the power of separation of gel electrophoresis. Separation is predicted to be largely enhanced for obtuse angles, in agreement with experiments. Interestingly, very large molecules, which are not separated by pulsed fields, are predicted not to migrate along the gel diagonal for fairly long periods of time. Finally, we discuss the optimization of these techniques using the results of the theory, and the limitations of the latter when fluctuations and intramolecular modes probably dominate the system.

Generalized tube model of biased reptation for gel electrophoresis of DNA

A theoretical analysis of the reptational motion of DNA in a gel that includes the effects of molecular fluctuations has been used to explain the main features found in experiments involving periodic inversion of the electric field. The resonance-like decrease of the electrophoretic mobility as a function of pulse duration is related to transient "undershoots" in the orientation of the molecule, in agreement with recent experimental data. These features arise from a delicate interplay of internal and center of mass motion of the molecules under pulsed field conditions, and are important for the separation of DNA molecules in the size range 0.2 to 10 million base pairs.

Preparation of megabase-sized tomato DNA and separation of large restriction fragments by field inversion gel electrophoresis (FIGE)

The Schwartz and Cantor technique for releasing and fractionating megabase-sized DNA from agarose-embedded cells is beginning to bridge the gap in resoluation between classical genetics and current molecular DNA techniques, particularly in mammalian systems. As yet no conditions have been described for preparing plant DNA that is of sufficient length to allow similar long-range restriction mapping experiments in plant systems. In this report, we describe the application of the Schwartz and Cantor technique for preparing high molecular weight DNA from embedded tomato leaf protoplasts, as well as conditions for generating and fractionating large restriction fragments, by field inversion gel electrophoresis (FIGE). The bulk of DNA released from lysed protoplasts was at least 2 Mb in size and amenable to restriction digestion as shown by hybridizing Southern blots with, among others, a probe for the Adh-2 gene of tomato. Restriction fragments as large as 700 kb were detected. Chloroplast DNA is isolated intact, amenable to restriction analysis and, in its native form, not mobile in FIGE.

Molecular detection of chromosomal translocations that disrupt the putative retinoblastoma susceptibility locus

A candidate DNA sequence with many of the properties predicted for the retinoblastoma susceptibility (RB1) locus has been cloned (S. H. Friend, R. Bernards, S. Rogelj, R. A. Weinberg, J. M. Rapaport, D. M. Albert, and T. P. Dryja, Nature [London] 323:643-645, 1986). The large size of this gene (ca. 200 kilobases [kb]) and its multiple dispersed exons (Wiggs et al., N. Engl. J. Med. 318:151-157, 1988) complicate molecular screening strategies important in prenatal and presymptomatic diagnosis and in carrier detection. Here we used field inversion gel electrophoresis (FIGE) to construct a restriction map of approximately 1,000 kb of DNA surrounding the RB1 locus and to detect the translocation breakpoints in three retinoblastoma patients. DNA probes from either the 5' or 3' end of the gene were used to detect a 250-kb EagI restriction fragment in DNA from unaffected individuals. Both probes identified an additional hybridizing fragment in the DNA from each patient, permitting the breakpoints in all three to be mapped within the cloned RB1 gene. Analysis of the breakpoint in one translocation cell line allowed the RB1 gene to be oriented with its 5' end toward the centromere. The 5' end of the gene also appeared to be associated with a clustering of sites for several infrequently cleaving restriction enzymes, indicating the presence of an HpaII tiny fragment island. The detection and mapping of the translocation breakpoints of all three retinoblastoma patients to within the putative RB1 gene substantiated the authenticity of this candidate sequence and demonstrated the utility of FIGE in detecting chromosomal rearrangements affecting this locus.