Recovery of native proteins from preparative electrophoresis gel slices by reverse polarity elution

A technique for high yield recovery of native, biologically active proteins from preparative polyacrylamide gel slices by reverse polarity elution is described. No apparatus other than the standard slab gel electrophoresis system is required. Several proteins have been recovered in biologically active form at a 90% yield, in quantities ranging from 0.4 mg to 4.2 mg. The method is effective with both small (9,000 dalton) and large (186,000 dalton) polypeptides. Both simple and complex proteins are recovered intact. For example, the copper-zinc and manganese superoxide dismutases from crude soybean extracts are active upon recovery. Similarly, the vitamin D-dependent calcium binding proteins from rat kidney and intestine are isolated by this method in homogeneous, active form.     

Misincorporation during DNA synthesis, analyzed by gel electrophoresis.

A method has been developed for simultaneous comparison of the propensity of a DNA polymerase to misincorporate at different points on a natural template-primer. In this method elongation of a [5'-32P] primer, annealed to a bacteriophage template strand, is carried out in the presence of only three dNTPs (highly purified by HPLC). Under these conditions the rate of primer elongation (monitored by gel electrophoresis/autoradiography) is limited by the rate of misincorporation at template positions complementary to the missing dNTP. Variations in the rate of elongation (revealed by autoradiographic banding patterns) reflect variations in the propensity for misincorporation at different positions along the template. The effect on primer elongation produced by addition of a chemically modified dNTP to 'minus' reactions reveals the mispairing potential of the modified nucleotide during DNA synthesis. By use of this electrophoretic assay of misincorporation we have demonstrated that the fidelity of E. coli DNA polymerase I varies greatly at different positions along a natural template, and that BrdUTP and IodUTP can be incorporated in place of dCTP during chain elongation catalyzed by this enzyme.     

High resolution preparative gel electrophoresis of DNA fragments and plasmid DNA using a continuous elution apparatus

An apparatus designed for preparative gel electrophoretic separation of proteins (M. A. Hediger, (1984) Anal. Biochem. 142, 445-454) has been used successfully for separating DNA restriction fragments. The apparatus displayed yields and resolutions that are higher than those obtainable with commercially available devices. The amounts of DNA applied to the column range from a few micrograms to milligram quantities. Restriction DNA fragments very similar in size were isolated in pure form with the apparatus. After ethanol precipitation, these fragments were successfully used for restriction enzyme cleavages, ligation, or chemical sequencing. Furthermore the apparatus provides a convenient method for the large-scale isolation of plasmid DNA. The method requires only 4 h of electrophoresis and therefore greatly reduces the preparation time compared with the conventional equilibrium centrifugation method which requires centrifugation times of up to 60 h. In contrast to the centrifugation method, contaminants such as RNA, proteins, and chromosomal DNA are efficiently removed by this technique.     

Sequential elution of proteins in small volumes by preparative polyacrylamide gel electrophoresis

A simple flexible method for separation of proteins by polyacrylamide gel electrophoresis and sequential elution into dialysis bags has been devised. The system was applied to isolation of three glycoproteins from the peritoneal fluid of mice bearing Ehrlich ascites tumor.     

Measurement of DNA length by gel electrophoresis

Plotting fragment length against reciprocal of mobility gives a straight line over a wider range than the conventional semilogarithmic plot. Curvature can be removed by a simple correction. A method is also given for determining molecular weights from mobilities by direct calculation.     

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.     

Neighboring nucleotide interactions during DNA sequencing gel electrophoresis.

Electrophoretic separation of oligonucleotides in denaturing polyacrylamide gels is primarily a function of length-dependent mobility. The 3' terminal nucleotide sequence of the oligonucleotide is a significant, secondary determinant of mobility and separation. Oligomers with 3'-ddT migrate more slowly than expected on the basis of length alone, and thus are better separated from the preceding, shorter oligomers in the sequencing ladder. Oligomers with 3'-ddC are relatively faster than expected, and are therefore less separated. At the 3' penultimate position, -dC- increases and -dT- reduces separation. Purines at the 3' terminal or penultimate positions of oligonucleotides affect separation less than the pyrimidines. These results suggest specific interactions among neighboring nucleotides with important effects on the conformation of oligonucleotides during electrophoresis. These interactions are compared to compression artifacts, which represent more extreme anomalies of length-dependent separation of oligonucleotides. Knowledge of base-specific effects on electrophoretic behavior of DNA oligomers supplements the usual information available for determination of sequences; additionally it provides an avenue to thermodynamic and hydrodynamic investigations of DNA structure.     

Recovery of biologically functional messenger RNA from agarose gels by passive elution

A general method for isolating biologically active messenger RNA (mRNA) from agarose gels is reported. Purified cellular RNA is resolved by preparative agarose gel electrophoresis and recovered in high yields (80%) by passive diffusion. Polyadenylated mRNA isolated from the eluted RNA is functionally intact based on the ability of the RNA to serve as a template in cell-free translation systems and complementary DNA synthesis reactions. The entire procedure is simple and rapid. A substantial purification of the mRNAs coding for skeletal muscle myosin heavy chain, light chain subunits and carbonic anhydrase III has been achieved employing this method.     

Detection of varicella-zoster virus DNA by field-inversion gel electrophoresis

A new method for detection of varicella-zoster virus (VZV) DNA using field-inversion gel electrophoresis (FIGE) was devised. VZV-genomic DNA could be differentiated from the host cell DNA of human embryonic lung (HEL) fibroblasts infected with VZV under electrophoretic conditions allowing resolution of linear and double-stranded DNAs in the 49-230 kilobase pairs (Kb) range. The detection of VZV-genomic DNA from infected HEL cells was successful regardless of whether the VZV was a laboratory strain, live vaccine strain, or fresh isolate. Under the same electrophoretic conditions, DNA of VZV-infected HEL cells could be clearly differentiated from DNA obtained from HEL cells infected with herpes simplex virus type 1 (HSV-1), type 2 (HSV-2), or human cytomegalovirus (HCMV). Furthermore, VZV genomic DNA could be detected from as small a sample as 1.9 x 10(4) VZV-infected HEL cells. Finally, we could detect VZV genomic DNA from 10 samples of vesicle tissue (blister lids, each about 1-4 mm2) and one sample of vesicle fluid (about 5 microliters) obtained from patients diagnosed as having herpes-zoster. The results of this study indicate that FIGE is a simple and promising method for the detection of VZV from clinical materials as well as infected in vitro cultured cells.     

Theory of gel electrophoresis of DNA

A theory of the electrophoresis of DNA through gels with large interfiber spacing, such as dilute agarose, is presented. We assume that the DNA molecule moves along its axis through a “tube” in a neutral gel under the influence of the electric field. The tube is random except for possible bias due to the effects of the field. When the field is small, we easily recover the inverse-length dependence of the mobility found previously by de Gennes and by Doi and Edwards. At higher fields, a new effect appears; the tube becomes oriented because the field biases the direction of the leading end of the chain as it moves to form an extension of the tube. This leads to an increase of the mobility with increasing field by adding a field-dependent but length-independent term to the mobility expression. In agreement with experiment, we find that the field effect can be important at fields as low as 1 V/cm and that the effect can seriously decrease the sensitivity of the mobility to chain length. We also examine the fluctuation of the migration distance, the degree of orientation induced by the field, and the transient effects occurring when the feld direction is rotated by a right angle.     

Transient orientation of linear DNA molecules during pulsed-field gel electrophoresis.

The transient orientation of lambda DNA and lambda-DNA oligomers has been measured during pulsed field gel electrophoresis. The DNA becomes substantially aligned parallel to the electric field E. In response to a single rectangular pulse, orientation shows an overshoot with a peak at 1 second, then a small undershoot, and finally a plateau. When the field is turned off, the orientation dissipates in two distinct exponential phases. Field inversion leads to periods of orientation with intervening periods of reduced orientation as the chains reverse direction. Field inversion pulses applied to linear oligomers of lambda-DNA show that orientation responses slow down but increase in amplitude as molecular weight increases, for a given field. Because DNA stretching and alignment parallel to E are expected to correlate with DNA velocity, the velocity in response to a pulsed field is also expected to exhibit an overshoot.     

Orientation and stretching of DNA chains during pulsed field gel electrophoresis

The quantitative analysis of the decay of birefringence accompanying gel electrophoresis leads to the characterization of two phenomena respectively attributed to alignment of the tube and to overstretching of the chain in its tube. The major contribution to the molecular orientation is given by the overstretching which relaxes according to a stretched exponential law. The other process, slow, is characterized by a reptation time and a mean orientation factor in good agreement with the biased reptation model without overstretching.