Anomalies in sedimentation. V. Chains at high fields, practical consequences

Evaluation of DNA double-strand break repair capacity in human cells: Critical overview of current functional methods

DNA double-strand breaks (DSBs) are highly deleterious lesions, responsible for mutagenesis, chromosomal translocation or cell death. DSB repair (DSBR) is therefore a critical part of the DNA damage response (DDR) to restore molecular and genomic integrity. In humans, this process is achieved through different pathways with various outcomes. The balance between DSB repair activities varies depending on cell types, tissues or individuals. Over the years, several methods have been developed to study variations in DSBR capacity. Here, we mainly focus on functional techniques, which provide dynamic information regarding global DSB repair proficiency or the activity of specific pathways. These methods rely on two kinds of approaches. Indirect techniques, such as pulse field gel electrophoresis (PFGE), the comet assay and immunofluorescence (IF), measure DSB repair capacity by quantifying the time-dependent decrease in DSB levels after exposure to a DNA-damaging agent. On the other hand, cell-free assays and reporter-based methods directly track the repair of an artificial DNA substrate. Each approach has intrinsic advantages and limitations and despite considerable efforts, there is currently no ideal method to quantify DSBR capacity. All techniques provide different information and can be regarded as complementary, but some studies report conflicting results. Parameters such as the type of biological material, the required equipment or the cost of analysis may also limit available options. Improving currently available methods measuring DSBR capacity would be a major step forward and we present direct applications in mechanistic studies, drug development, human biomonitoring and personalized medicine, where DSBR analysis may improve the identification of patients eligible for chemo- and radiotherapy.

Steady state sedimentation of ultrasoft colloids

The structural and dynamical properties of ultra-soft colloids-star polymers-exposed to a uniform external force field are analyzed by applying the multiparticle collision dynamics technique, a hybrid coarse-grain mesoscale simulation approach, which captures thermal fluctuations and long-range hydrodynamic interactions. In the weak-field limit, the structure of the star polymer is nearly unchanged; however, in an intermediate regime, the radius of gyration decreases, in particular transverse to the sedimentation direction. In the limit of a strong field, the radius of gyration increases with field strength. Correspondingly, the sedimentation coefficient increases with increasing field strength, passes through a maximum, and decreases again at high field strengths. The maximum value depends on the functionality of the star polymer. High field strengths lead to symmetry breaking with trailing, strongly stretched polymer arms and a compact star-polymer body. In the weak-field-linear response regime, the sedimentation coefficient follows the scaling relation of a star polymer in terms of functionality and arm length.

Heavy Ion-induced DNA Double-strand Breaks in Yeast

DNA double-strand break (dsb) induction in diploid yeast was measured by neutral sucrose sedimentation after exposure to very heavy ions with values of linear energy transfer (LET) ranging from about 300 to 11500 ke V/microns. Linear fluence dependencies were found in all cases from which dsb production cross-sections (sigma dsb) could be calculated. Corresponding cross-sections for cell killing (sigma i) were derived from final slopes of survival curves measured in parallel and for the same fluence range. A close correlation was found between sigma i and sigma dsb. It is calculated that over the entire LET range, including 30 MeV electron irradiation, about 22 dsb are induced per lethal event when high exposures are considered.

Fluid mechanics of DNA double-strand filter elution

Measurement of infrequent DNA double-strand breaks (DSB) in mammalian cells is essential for the understanding of cell damage by ionizing radiation and many DNA-reactive drugs. One of the most important assays for measuring DSB in cellular DNA is filter elution. This study is an attempt to determine whether standard concepts of fluid mechanics can yield a self-consistent model of this process. Major assumptions of the analysis are reptation through a channel formed by surrounding strands, with only strand ends captured by filter pores. Both viscosity and entanglement with surrounding strands are considered to determine the resistance to this motion. One important result is that the average elution time of a strand depends not only on its length, but also on the size distribution of the surrounding strands. This model is consistent with experimental observations, such as the dependence of elution kinetics upon radiation dose, but independence from the size of the DNA sample up to a critical filter loading, and possible overlap of elution times for strands of different length. It indicates how the dependence of elution time on the flow rate could reveal the relative importance of viscous and entanglement resistance, and also predicts the consequences of using different filters.

The role of DNA double strand breaks in ionizing radiation-induced killing of eukaryotic cells

A widely accepted assumption in radiobiology is that ionizing radiation kills cells by inducing forms of damage in DNA structures that lead to the formation of lethal chromosome aberrations. One goal of radiation biology research is the identification of these forms of DNA damage, the characterization of the mechanisms involved in their repair and the elucidation of the processes involved in their transformation to chromosome damage. In recent years, evidence has accumulated implicating DNA double stranded breaks as lesions relevant for cell killing. Here, the available information on this topic is reviewed together with the methods most commonly used to quantitate induction and repair of this type of lesion. The presentation concludes with an outline of present research directions and future goals.

Significance and measurement of DNA double strand breaks in mammalian cells

Techniques for measuring DNA double strand breaks in mammalian cells are being used increasingly by researchers studying both physiological processes, such as recombination, replication, and apoptosis, as well as pathological processes, such as clastogenesis induced by ionizing radiation, chemotherapeutic drugs, and chemical toxicants. In this review we evaluate commonly used assays for measuring DNA double strand breaks, focusing on neutral filter elution and pulsed field gel electrophoresis, and explore the advantages and limitations of applying these techniques to problems of current interest in carcinogenesis and genetic toxicology.

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 dose-response for low-LET radiation-induced DNA double-strand breakage: methods of measurement and implications for radiation action models

There is considerable controversy over the form of the dose-response for DNA double-strand breakage (dsb) induction in mammalian cells by low-LET type radiation. This controversy centres on the techniques used for measuring DNA dsb. The applications and shortcomings of the four major techniques for estimating DNA size--sedimentation, viscoelastometry, electrophoresis, and non-denaturing filter elution--are examined. In particular, the criticisms of the results obtained using the non-denaturing filter elution technique, which have suggested that the DNA dsb dose-response is non-linear, are discussed. It is concluded that these results may require a re-evaluation of the basic assumptions of many radiation action models.

The effect of bleomycin on DNA in Escherichia coli K12 cells

In Escherichia coli cells treated to reduce colony-forming ability to about 10%, bleomycin causes fewer than six randomly located DNA single-strand breaks or three double-strand breaks per genome. This is many fewer than produced by strand-breaking agents such as ionizing radiations in cells with similar loss of colony-forming ability. Bleomycin treatment to this level of colony-forming ability does affect the intracellular DNA, as shown by a change in the sedimentation rate of the chromosomal structure found in lysates made with sodium dodecyl sulfate. Bleomycin may act on only a limited part of the chromosome of such cells, perhaps the part associated with the outer cell membrane, or it may make strand breaks that are less repairable than those formed by ionizing radiations. Extensive DNA degradation in heavily treated cells (colony-forming ability 1% or less) could be from the action on DNA of bleomycin entering freely through membranes which are no longer intact, or from enzymatic degradation in heavily damaged cells.

DNA double strand breaks in Ehrlich ascites tumour cells at low doses of x-rays. I. Determination of induced breaks by centrifugation at reduced speed

DNA double strand breaks (dsb) were determined in Ehrlich ascites tumour cells at doses down to 5 Gy. The method is based on the separation of DNA from other components by heating in a solution of pronase and detergents held in wide-mouth syringes, which were also used to facilitate the application of the released high molecular weight DNA to sucrose gradients. Purified DNA was sedimented in neutral sucrose gradients at low speed to reduce speed artifacts. The sedimentation profiles were analysed using a computer program and the number of dsb was determined by simulation of random breaks in the mass distribution of the control sample and by comparison of this simulated profile with that of the irradiated one. The number of dsb formed was proportional to X-ray dose in the range of 5 to 2000 Gy. The induction per dose was found to be nmr-1 D-1 = (11.7 +/- 2) x 10(-12) Gy-1.

Assembly of secondary intermediates during deoxyribonucleic acid replication in transformed human fibroblasts

The elongation of replicative DNA was studied in transformed WI-38 cells (designated 2RA). Shear effects were avoided by use of an alkaline sucrose gradient sedimentation method whereby cells were lysed directly on top of gradients, at 4 degrees C in the dark. The earliest detected intermediate is a short (2 S) piece of DNA which is converted first to a 25 S piece and then to a 100 S piece, within 10 min. The 100 S piece is next converted to a 212 S, and a 370 S, and finally to a chromosomal DNA of about 450 S. This pattern is quite different from that previously reported by us for normal WI-38 cells, where there was a 50 S intermediate which was not quickly converted into a much larger size, but which gradually elongated, by addition of smaller pieces, to a larger size, of 100 S.; another difference was the time required for formation of the 100 S piece, i.e., 75 min (Rawles, J.W., Jr. and Collins, J.M. (1977) J. Biol. Chem. 252, 4762-4766).

Measurement of the kinetics of DNA double strand break repair in Ehrlich ascites tumour cells using the unwinding method

Two main components of DNA strand break repair have been found using the unwinding method. The first has a time constant (t37) of some minutes and the second, much slower component, a time constant of several hours. The time constant for the slower component of repair was found to vary with the conditions of incubation and to depend on the quality of the radiation. The t37 values obtained for slow repair under various conditions after X-irradiation and after alpha-irradiation were found to be close to those for repair of double strand breaks as measured by velocity sedimentation. Values for initial breaks, obtained by extrapolation of slow repair data back to time zero, were also close to those obtained for double strand breaks. We therefore propose that the unwinding method can be a useful technique for monitoring the repair of double strand breaks.

High-molecular-weight DNA and the sedimentation coefficient: a new perspective based on DNA from T7 bacteriophage and two novel forms of T4 bacteriophage

The DNA molecules from T7 bacteriophage and a recently obtained mutant form of T4D were studied. The DNA of this T4 mutant contains cytosine in place of all of the glucosylated hydroxymethylcytosines normally present in T4. Molecular weights were measured with an electron microscope technique, and sedimentation coefficients were determined in isokinetic sucrose gradients. T7 DNA was found to have an Mr of 26.5 x 10(6). The T4 mutant, which we have termed T4c, produces two distinct phage head and DNA size clases. DNA from the standard heads (T4c DNA) has an Mr of 114.9 x 10(6), and DNA from the petite heads (T4cp DNA) has an Mr of 82.9 x 10(6). This enabled the derivation of an equation of sedimentation coefficient at zero concentration corrected to water at 20 degrees C versus Mr for the molecular weight range of 25 x 10(6) to 115 x 10(6) that is based solely on cytosine-containing DNA standards, thereby avoiding possible anomalies introduced by the glucosylation and hydroxymethylation of cytosine. The theory of Gray et al. provided the best description of the sedimentation coefficient versus Mr relationship, based on the sedimentation coefficients and the molecular weights of the three DNA standards and other evidence.

Size distribution and maturation of newly replicated DNA through the S and G2 phases of Physarum polycephalum

The size distribution of newly made DNA and the dynamics of size maturation of progeny DNA molecules were studied in the synchronous S and G2 phases of Physarum polycephalum. Pulse labeling of DNA and analysis of the products on alkaline sucrose gradients showed that synthesis of primary replication units (which will also be referred to as "Okazaki" fragments) occurred throughout the S period. Pulse and pulse-chase experiments revealed a distinct pattern of size maturation. An apparently linear increase in molecular weight of progeny DNA molecules during the first hour of the S phase occurred at a rate of approximately 4-5 X 10(5) daltons per min at 26 degrees C, corresponding to the joining of 6-8 Okazaki fragments. The resulting 35-45S (1.1-2.2 X 10(7) daltons) DNA molecules may correspond to the Physarum "replicon." The further size increases of the newly made DNA appear to occur in steps, possibly reflecting a clustering of isochronous replicons along the chromatide. These observations are discussed with regard to mechanisms of DNA replication and size maturation.

Biochemical analysis of meiosis in the male mouse. II. DNA metabolism at pachytene

The DNA metabolism of mouse spermatogenic cells was investigated by intravenous administration of isotope and Staput fractionation of the cells. The pattern of metabolism is virtually identical with that observed in Lilium microsporocytes. A programmed single strand nicking of DNA occure at pachytene such that at least 50% of the DNA is in the form of 62S fragments. Repair replication of endogenously nicked sites is fully achieved during pachytene. The sites of nicking and repair are preferentially located in sequences that are repeated about 400 times. These results are considered as strong evidence for a universal pattern of meiotic prophase DNA metabolism which is associated with crossing-over.

The effect of X chromosome heterozygosity on the structure of the ribosomal genes in Drosophila melanogaster

Sucrose gradient analysis of DNA isolated from detergent-pronase lysates of adult flies has been used to look for ribosomal genes not integrated into the DNA of the chromosome in genotypes containing various combinations of inversions having breakpoints in the proximal heterochromatin of the X chromosome. Unintegrated genes are found in females heterozygous for inversions which have one breakpoint between the nucleolus organizer and the centromere. Homozygotes and males do not have unintegrated genes. The results suggest that unintegrated ribosomal genes result from an interaction between homologues having different arrangements of the proximal heterochromatin. In addition, data from a series of stocks carrying duplications of the X heterochromatin provide independent evidence for the size of the DNA on our gradients.

Dependence of the sedimentation of high molecular weight DNA on centrifuge speed

A theory by Zimm [B.H.Zimm, Biophys. Chem. 1-(1974)279] predicts that for a given centrifuge speed, there is a broad maximum in a plot of the sedimentation coefficient of DNA against molecular wight. Experimental measurements of these maxima for various centrifuge speeds were made for double-helical DNA in neutral sucrose gradients and singlestrand DNA in alkaline gradients. The measurements are in quantitative agreement with the theory, providing good evidence for its validity. The existence of the maximum shows that there is a limit to the sedimentation rate under specified conditions for KNA in the linear form. By implication, DNA observed to sediment faster than this limit is not in the linear form to which most sedimentation theory is applicable.

The so20,w of unsheared DNA from whole cell lysates of Escherichia coli

We present measurements of the sedimentation coefficients of DNA present in whole cell lysates of E. coli. The method used is a preparative version of the band sedimentation experiment of Bruner and Vinograd. We show that in order to obtain reliable data on the time dependence of sedimentation, it is necessary to accelerate and decelerate the rotor over much longer times than the standard centrifuge allows. We describe the necessary modifications to the preparative centrifuge and use them to determine the So20,W of unsheared E. coli DNA. The value for the fastest moving components in the lysate is 220 S. The molecular weight of the DNA corresponding to this sedimentation coefficient is probably 1.7 X 10(9) g/mole. However, alternative values cannot be ruled out.