Identification of human alcohol dehydrogenase isozymes by disc polyacrylamide gel electrophoresis in 7 M urea

Polyacrylamide gel electrophoresis in the presence of 7 M urea provides a simple, reproducible method for the identification of cathodic alcohol dehydrogenase (ADH) isozymes. Treatment of native ADH dimers with 7 M urea and 1 mM dithiothreitol results in a complete dissociation of the 40,000 Mr subunits. Electrophoresis of urea-dissociated ADH isozymes yields a single protein band for homodimers and two bands of equal intensity for heterodimers. The ADH subunits pi, alpha, gamma 2, gamma 1, and beta exhibit electrophoretic mobilities of 0.71, 0.79, 0.88, 0.95, and 1.0, respectively. Thus, the identity of any cathodic ADH isozyme can be determined from the electrophoretic mobilities of its component subunits.     

Electrophoretic separation of histones and high-mobility-group proteins on acid-urea-Triton gels

The electrophoretic mobilities of calf thymus histones and high-mobility-group (HMG) nonhistone proteins were studied on a newly modified polyacrylamide gel containing acetic acid, urea, and the nonionic detergent Triton X-100 in combination with glycine in the electrode buffer. This gel system avoids stacking gel, photopolymerization of acrylamide, and preelectrophoresis. Under extremely low Triton concentrations some H3 variant forms (H3.1) were preferentially separated by their slower migration from bulk H3. Under increasing concentrations of Triton in the gel in the presence of 3 or 6 M urea, the mobilities of H2A.1, H3.2, H2A.2, H4, and H2B were sequentially retarded. The mobilities of H1 and HMGs remained virtually unchanged under all conditions. This gel system is able to resolve charge-modified histones.     

Gel electrophoresis in studies of protein conformation and folding

Electrophoresis through polyacrylamide gels is a useful method for distinguishing conformational states of proteins and analyzing the thermodynamic and kinetic properties of transitions between conformations. Although the relationship between protein conformation and electrophoretic mobility is quite complex, relative mobilities provide qualitative estimates of compactness. Conformational states which interconvert slowly on the time scale of the electrophoretic separation can often be resolved, and the rates of interconversion can be estimated. If the transitions are more rapid, then the electrophoretic mobility represents the equilibrium distribution of conformations. Protein unfolding transitions induced by urea are readily studied using slab gels containing a gradient of urea concentration perpendicular to the direction of electrophoresis. Protein applied across the top of such a gel migrates in the presence of continuously varying urea concentrations, and a profile of the unfolding transition is generated directly. Transitions induced by other agents could be studied using analogous gradient gels. Electrophoretic methods are especially suited for studying small quantities of protein, and complex mixtures, since the different components can be separated during the electrophoresis.     

Anomalous behavior of certain poliovirus polypeptides during SDS-gel electrophoresis.

Urea is shown to be a useful additive to sodium dodecyl sulfate gels prior to electrophoresis and offers an alternative means for the resolution of some SDS-protein complexes. Two types of effect are described, one of which causes increases in the relative mobilities of certain polypeptides found in poliovirus-infected cells. It is postulated that urea plus SDS is able to achieve a more complete denaturation of some polypeptides, which leads to faster electrophoretic mobilities. The molecular weight estimations for such proteins in these conditions are therefore lower than those determined in the presence of SDS alone. A second effect of some urea solutions is to cause the multiple banding of the structural polypeptide VP3 when included in gels at high concentrations. This effect is variable and appears to be unrelated to the presence of cyanate ions.     

Rapid separation of DNA molecules by agarose gel electrophoresis: use of a new agarose matrix and a survey of running buffer effects.

This report describes the use of a new type of agarose (FastLane agarose) for faster separation of DNA by agarose gel electrophoresis. DNA molecules separated in this agarose exhibited electrophoretic mobilities up to 30% higher than similar separations in standard analytical grade agarose. DNA molecules of all sizes examined showed higher mobilities in FastLane agarose. The mobility increase was predominantly due to the low electroendosmosis of FastLane agarose and was most pronounced in pulsed field gel electrophoresis separations. The magnitude of mobility increase varied depending on the conditions used for electrophoresis.     

Improved single-strand DNA sizing accuracy in capillary electrophoresis.

Interpolation algorithms can be developed to size unknown single-stranded (ss) DNA fragments based on their electrophoretic mobilities, when they are compared with the mobilities of standard fragments of known sizes; however, sequence-specific anomalous electrophoretic migration can affect the accuracy and precision of the called sizes of the fragments. We used the anomalous migration of ssDNA fragments to optimize denaturation conditions for capillary electrophoresis. The capillary electrophoretic system uses a refillable polymer that both coats the capillary wall to suppress electro-osmotic flow and acts as the sieving matrix. The addition of 8 M urea to the polymer solution, as in slab gel electrophoresis, is insufficient to fully denature some anomalously migrating ssDNA fragments in this capillary electrophoresis system. The sizing accuracy of these fragments is significantly improved by the addition of 2-pyrrolidinone, or increased capillary temperature (60 degrees C). the effect of these two denaturing strategies is additive, and the best accuracy and precision in sizing results are obtained with a combination of chemical and thermal denaturation.     

Molecular analysis of the histone gene cluster of Psammechinus miliaris: I. Fractionation and identification of five individual histone mRNAs

The electrophoretic separation of labeled “9S” histone mRNAs obtained from cleaving sea urchin polysomes was found at first to be highly unreproducible. It became evident that the secondary structure of the individual mRNAs had a greater effect on their relative electrophoretic mobilities than did their molecular weight differentials. We determined the parameters affecting electrophoretic mobility by the novel method of running the labeled polysomal RNA in slab gels across polyacrylamide and urea gradients. The initially complex and species-specific electrophoretic pattern could then, by a judicious choice of denaturing conditions, be simplified to yield five well defined classes of labeled mRNAs. Using optimal conditions for the separation of the RNA components, five messengers were isolated from Psammechinus embryos by preparative disc electrophoresis, four of which, after two electrophoretic separations, exhibited a unimodal distribution.Each of the mRNAs was translated in vitro, four of the five fractions promoting the synthesis of one major protein. The in vitro products were characterized by comparison of their electrophoretic mobilities with those of known sea urchin histones. It was thus possible to correlate individual mRNAs with specific histones. We propose that the five mRNAs designated a–e in order of decreasing electrophoretic mobility code for the histones H4, H2A, H2B, H3, and H1.     

DNA-dependent RNA polymerases from Acanthamoeba castellanii. Comparative subunit structures of the homogeneous enzymes.

The constituent polypeptides of the three classes of DNA-dependent RNA polymerase from Acanthamoeba castellanii were compared by several electrophoretic methods. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS) reveals that a number of polypeptide components of the isozymes have identical molecular weights. Two-dimensional electrophoresis (isoelectric focusing in 8 M urea:SDS-polyacrylamide gel electrophoresis) demonstrates that the polypeptides of identical molecular weights also have identical isoelectric pH values. These polypeptides were also coincident after electrophoresis in 8 M urea at acidic or basic pH values followed by a second electrophoretic separation in the presence of SDS. By these criteria, subunits of molecular weight 13,300, 15,500, 17,500, 22,500, 37,000, and 39,000 are indistinguishable in polymerase I and III. The 13,300, 15,500, and 22,500 subunits are also shared by the class II polymerase. In addition, electrophoresis in 8 M urea under basic conditions reveals microheterogeneity in the 17,500 molecular weight subunit. The strikingly similar pattern of common subunits between yeast and Acanthamoeba suggests that a universal arrangement of functional units may be an essential feature of the eukaryotic polymerases.     

Genome RNAs and polypeptides of reovirus serotypes 1, 2, and 3.

The virus-specific double-stranded genome RNA and polypeptides present in virions and cells infected with the three mammalian reovirus serotypes have been examined by co-electrophoresis in several different polyacrylamide gel systems. The double-stranded RNA and polypeptide species previously described for type 3 Dearing were found to have corresponding species in the other serotypes examined. In each serotype several RNA and polypeptide species were found to have different electrophoretic mobilities from the corresponding RNA or polypeptide species of type 3 Dearing. The combination of electrophoretic variants among the RNAs and polypeptides of the reovirus serotypes gave electrophoretic markers in all 10 of the reovirus genes. The usefulness of these electrophoretic markers in "mapping" the reovirus genome is discussed.     

Heterogeneity of the 3'' end of minus-strand RNA in the poliovirus replicative form.

The 3' terminus of the strand (minus strand) complementary to poliovirion RNA (plus strand) has been examined to see whether this sequence extends to the 5'-nucleotide terminus of the plus strand, or whether minus-strand synthesis terminates prematurely, perhaps due to the presence of a nonreplicated nucleotide primer for initiation of plus-strand synthesis. The 3' terminus was labeled with 32P using [5'-32P]pCp and RNA ligase, and complete RNase digests were performed with RNases A, T1, and U2. 32P-oligonucleotides were analyzed for size by polyacrylamide-urea gel electrophoresis. The major oligonucleotide products formed were consistent with the minus strand containing 3' ends complementary and flush with the 5' end of the plus strand. However, a variable proportion of the isolated minus strands from different preparations were heterogeneous in length and appeared to differ from each other by the presence of one, two, or three 3'-terminal A residues.     

On the heterogeneity and organ specificity of chicken tropomyosins.

1. Tropomyosins from chicken cardiac, skeletal, and gizzard muscles were each resolved into two subunits by polyacrylamide gel electrophoresis in a system containing sodium dodecylsulfate (SDS), urea and sodium borate, and were designated C1 C2, S1 S2, and G1 G2, respectively, in descending order of mobility on electrophoresis. S1, S2, G1, and G2 were prepared as pure samples by electrophoresis. 2. The apparent molecular weights of C (C1 + C2), S1, S2, G1, and G2 were calculated to be 36,000, 36,000, 37,500, 36,000, and 40,000, respectively, based on SDS gel electrophoretic mobility according to the method of Weber and Osborn. C and S1 showed nearly the same mobility in all electrophoretic systems tried. S1 and G1, which comigrated in an SDS-sodium borate system, showed different mobilities upon addition of 5 M urea to the system. 3. Immunological evidence presented indicates that each subunit has a specific antigenic site(s) in addition to an identical one(s) in common with the others. 4. As each tropomyosin subunit formed two precipitin lines with the homologous antiserum, as many as ten kinds of subunits may exist in chicken muscles.     

Further Characterization of the Reduced Nicotinamide Adenine Dinucleotide Phosphate:Nitrate Oxidoreductase in Aspergillus nidulans

The reduced nicotinamide adenine dinucleotide phosphate (NADPH):nitrate oxidoreductase (EC 1.6.6.2) from Aspergillus nidulans wild-type bi-1 was purified by means of salt fractionation, gel filtration, affinity chromatography, and polyacrylamide gel electrophoresis. Enzyme which was adsorbed on Cibacron blue agarose could be eluted with 2 mM NADPH or 2 mM oxidized NADP (NADP(+)), the former being about three times more effective than the latter. About half the total NADPH:nitrate reductase activity adsorbed on agarose required elution with 1 M NaCl. This salt-elutable form remained active with NADPH and was not converted to the NADPH-elutable form after readsorption on Cibacron blue agarose. The NADPH-eluted enzyme exhibited a markedly different electrophoretic mobility than the enzyme eluted with NADP(+) or NaCl. After electrophoresis on polyacrylamide gels, the NADPH-eluted NADPH:nitrate reductase was separated into four proteins, two of which contained nonheme iron and exhibited reduced methyl viologen-nitrate reductase activity. None of these proteins, singly or in combination, reduced nitrate with NADPH as substrate. Difference spectra analyses and specific heme iron stains revealed the presence of cytochrome b(557) in the largest of the proteins. The molecular weights of the four proteins, which were determined from the relationship of their mobilities on varied concentrations of acrylamide gel, were 360,000, 300,000, 240,000, and 118,000. The subunit molecular weights of these, which are determined via sodium dodecyl sulfate slab gel electrophoresis, were 49,000, 50,000, and 75,000. The key role of NADPH in maintenance of the active form of the heteromultimer is further substantiated.     

Evidence from cauliflower mosaic virus virion DNA for additional discontinuities in the plus strand.

Two-dimensional electrophoresis of cauliflower mosaic virus (CaMV) virion DNA and analysis of Southern blots using (+) strand-specific probes to the 5' termini of the beta (5.4 Kb) and alpha (2.6 Kb) strands, revealed the presence of molecules in addition to those predicted from the known structure of CaMV DNA. The presence of 8 Kb molecules of (+) sense after denaturation suggested that a small proportion of circular molecules have only a single discontinuity in the (+) strand. Other molecules, probably 5' coterminal with the beta strand but smaller than 5.4 Kb, indicated that a minority of the circular full length CaMV DNA contain additional gaps in the (+) strand. Consequently, molecules equivalent to the remainder of the beta strand could be identified using a single strand probe for a region towards the 3'-end of the beta strand. Computer analysis of the nucleotide sequence of CaMV DNA in the region of the proposed additional discontinuities revealed regions displaying some homology with the major (+) strand priming sites at the 5' ends of the beta and alpha strands. It is our contention that the additional (+) strand molecules of beta specificity are a consequence of minor (+) strand priming sites.     

The separation of whale myoglobins with two-dimensional electrophoresis

Five myoglobins (sperm whale, Sei whale, Hubbs' beaked whale, pilot whale, and Amazon River dolphin) were examined using two-dimensional electrophoresis. Previous reports indicated that none of these proteins could be separated by using denaturing (in the presence of 8-9 M urea) isoelectric focusing. This result is confirmed in the present study. However, all the proteins could be separated by using denaturing nonequilibrium pH-gradient electrophoresis in the first dimension. Additionally, all the myoglobins have characteristic mobilities in the second dimension (sodium dodecyl sulfate), but these mobilities do not correspond to the molecular weights of the proteins. We conclude that two-dimensional electrophoresis can be more sensitive to differences in primary protein structure than previous studies indicate and that the assessment seems to be incorrect that this technique can separate only proteins that have a unit charge difference.     

Stability of non-Watson-Crick G-A/A-G base pair in synthetic DNA and RNA oligonucleotides

A non-Watson-Crick G-A/A-G base pair is found in SECIS (selenocysteine-insertion sequence) element in the 3'-untranslated region of Se-protein mRNAs and in the functional site of the hammerhead ribozyme. We studied the stability of G-A/A-G base pair (bold) in 17mer GT(U)GACGGAAACCGGAAC synthetic DNA and RNA oligonucleotides by thermal melting experiments and gel electrophoresis. The measured Tm value of DNA oligonucleotide having G-A/A-G pair showed an intermediate value (58 degrees C) between that of Watson-Crick G-C/C-G base pair (75 degrees C) and that of G-G/A-A of non-base-pair (40 degrees C). Similar thermal melting patterns were obtained with RNA oligonucleotides. This result indicates that the secondary structure of oligonucleotide having G-A/A-G base pair is looser than that of the G-C type Watson-Crick base pair. In the comparison between RNA and DNA having G-A/A-G base pair, the Tm value of the RNA oligonucleotide was 11 degrees C lower than that of DNA, indicating that DNA has a more rigid structure than RNA. The stained pattern of oligonucleotide on polyacrylamide gel clarified that the mobility of the DNA oligonucleotide G-A/A-G base pair changed according to the urea concentration from the rigid state (near the mobility of G-C/C-G oligonucleotide) in the absence of urea to the random state (near the mobility of G-G/A-A oligonucleotide) in 7 M urea. However, the RNA oligonucleotide with G-A/A-G pair moved at an intermediate mobility between that of oligonucleotide with G-C/C-G and of the oligonucleotide with G-G/A-A, and the mobility pattern did not depend on urea concentration. Thus, DNA and RNA oligonucleotides with the G-A/A-G base pair showed a pattern indicating an intermediate structure between the rigid Watson-Crick base pair and the random structure of non-base pair. RNA with G-A/A-G base pair has the intermediate structure not influenced by urea concentration. Finally, this study indicated that the intermediate rigidity imparted by Non-Watson-Crick base pair in SECIS element plays an important role in the selenocysteine expression by UGA codon.     

Overestimates of the size of poly(A) segments.

Poly(A) molecules containing on average 25, 45 and 90 nucleotide residues are all eluted from DEAE-Sephadex in the presence of 7 M urea by approximately the same NaCl concentration which is higher than that required to elute 4 S and 5 S RNA. The same poly(A) molecules have electrophoretic mobilities on 12% polyacrylamide gels which are proportional to the logarithm of the number of nucleotide residues they contain but not to the number found in 4 S and 5 S RNA, even after denaturation of the RNA and performing electrophoresis in the presence of 2.2 M formaldehyde. As a result, many reported estimates of poly(A) size derived from such techniques are probably too large and need re-evaluation. Corrections are suggested for the use of 4 S and 5 S RNA as molecular weight markers for electrophoresis on 12% polyacrylamide gels.     

Characterization of Enterobacter cloacae and E. sakazakii by electrophoretic polymorphism of acid phosphatase, esterases, and glutamate, lactate and malate dehydrogenases

Acid phosphatase, esterases, and glutamate, lactate and malate dehydrogenases of 34 strains of Enterobacter cloacae and 22 strains of Enterobacter sakazakii were analysed by horizontal polyacrylamide agarose gel electrophoresis and by isoelectrofocusing in thin-layer polyacrylamide gel. The two species could be separated on the basis of distinct electrophoretic patterns of all enzymes analysed. Glutamate dehydrogenase and acid phosphatase were detected exclusively in E. cloacae, whereas esterase bands were more intensively stained in E. sakazakii. For each species, two zymotypes could be distinguished, on the basis of electrophoretic mobilities of malate dehydrogenase and banding patterns of esterase for E. cloacae, and by both isoelectric point and electrophoretic mobilities of an esterase and of lactate and malate dehydrogenases for E. sakazakii. The high degree of enzyme polymorphism within the two species permitted precise identification of strains. The variations in electrophoretic patterns might therefore provide useful epidemiological markers.     

Microspectrophotometric and enzymatic analyses of fish plasma proteins electrophoretically separated in thin polyacrylamide gels

A system for horizontal, discontinuous electrophoresis in thin sheets of polyacrylamide gel was developed to permit rapid and direct comparison of multiple samples of fish plasmas for population studies. The resulting electropherograms are suitable either for screening for enzyme polymorphisms or for densitometric scanning after gels are stained for total proteins. Each gel sheet (110×90×0.8 mm) can be used for simultaneous separation of 10–15 different samples. Since total voltage and the running time required for successful resolution of fine protein bands are greatly reduced in this system, minimal heating occurs within the gel matrix during electrophoresis. Up to 120 different blood samples (8 gel sheets) can be processed in about 8 h. Gel sheets are routinely stained overnight in Coomassie Brilliant Blue (0.1%, v/v), rinsed several times and stored overnight in 7% acetic acid to complete destaining. Particular gel sectors are then transferred to distilled water and mounted on glass microslides for photography or for densitometric evaluation with a Leitz microspectrophotometer. These procedures have been used to identify characteristic differences in the electrophoretic mobilities of plasma enzymes and albumin fractions from several populations of poeciliid fishes. Observed differences in albumin mobilities (albumin phenotypes) were verified by mixing isoaliquots of test plasmas with plasma samples containing albumins of known mobility. Resultant patterns for albumin bands for such mixed plasmas were indistinguishable from those obtained with plasma samples from the F₁ hybrid progeny of parents possessing albumins of characteristically different electrophoretic mobilities. Procedural details for gel casting, electrophoresis and sample evaluation are described.     

Two-dimensional electrophoresis for the isolation of integral membrane proteins and mass spectrometric identification

Acrylamide concentration, urea content, and the trailing ion used for sodium dodecyl sulfate (SDS)-gels modify electrophoretic protein mobilities in a protein-dependent way. Varying these parameters we coupled two SDS-gels to a two-dimensional (2-D) electrophoresis system. Protein spots in 2-D gels are dispersed around a diagonal. Hydrophobic proteins are well separated from water-soluble proteins which is the essential advantage of the novel technique. Mass spectrometric identification of previously unaccessible hydrophobic proteins is now possible.     

Histone gene expression in early development of Xenopus laevis

Abstract. This study comprises the hybridization analysis of electrophoretically separated histone mRNAs from oocytes and embryos of Xenopus laevis , and analysis of in vitro translation products of these mRNAs on polyacrylamide gels containing sodium dodecyl sulfate (SDS) or Triton X-100. In oocytes and embryos up to the tailbud stage, four types of mRNAs complementary to histone H2B DNA and two complementary to histone H4 DNA can be discriminated by their different electrophoretic mobilities on polyacrylamide gels. Electrophoretic heterogeneity was not detected for messengers for histones H2A and H3.
Histone mRNA, purified by hybridization under stringent conditions with a cloned histone gene cluster, was used to direct histone protein synthesis in a wheat-germ cell free system. The proteins synthesized comigrate with purified marker histones when electrophoresed on SDS-gels or acid-urea gels containing Triton X-100. When hybrid-selected histone mRNAs from oocytes and embryos in different developmental stages are translated, the proteins made by the mRNA from one stage can not be discriminated from those made by the mRNA from another stage after electrophoresis on SDS-gels or acid urea Triton X-100 gels.