Sequence-dependent cooperative interactions in A/T-containing oligo- and polydeoxyribonucleotides

To evaluate the length and sequence dependence of the unusual interaction properties observed for nonalternating A/T sequences in deoxyribonucleic acid (DNA) [Wilson, W. D., Wang, Y. H., Krishnamoorthy, C. R., & Smith, J. C. (1985) Biochemistry 24, 3991-3999], we have synthesized the oligomers d(A-T)6, dA10 X dT10, and d(A6-T6) and evaluated their interaction with the intercalator propidium. Propidium visible spectral shifts on adding all three oligomers are quite similar. Low-temperature spectrophotometric binding measurements indicate that d(A-T)6 has a significantly larger binding constant for propidium than dA10.dT10, as with the analogous alternating and nonalternating DNA polymers. The oligomer dA10.dT10 displays positive cooperativity in its propidium binding isotherm, and its binding constant increases with increasing temperature while d(A-T)6 does not display positive cooperativity, and its binding constant decreases with temperature, again as with the analogous polymers. van't Hoff plots indicate that the propidium binding enthalpies are approximately -9 and +6 kcal/mol for the alternating and nonalternating DNA samples, respectively. The mixed-sequence self-complementary oligomer d(A6-T6) has an unusual low-temperature binding isotherm which suggests a single strong binding site and a larger number of weaker binding sites which bind propidium cooperatively. A van't Hoff plot indicates that the cooperative sites d(A-T)6 have binding constants and binding enthalpies similar to dA10.dT10. Similar rate constants are observed in the sodium dodecyl sulfate driven dissociation reaction of propidium from d(A-T)6 and d(A6-T6), but the association reaction of propidium is significantly slower with d(A6-T6) than with d(A-T)6.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of base-pair sequence on the conformations and thermally induced transitions in oligodeoxyribonucleotides containing only AT base pairs

Tm curves, CD spectra, and kinetics results of the self-complementary DNA dodecamers d(A6T6), d(A3T3A3T3), d(A2T2A2T2A2T2), d(ATATATATATAT), and d(T6A6) demonstrate that the thermal transitions of these oligomers at low salt concentration involve a hairpin intermediate. At high salt concentrations (greater than 0.1 M Na+) only a duplex to denatured-strand transition appears to occur. The temperature and salt-concentration regions of the transitions are very sequence dependent. Alternating-type AT sequences have a lower duplex stability and a greater tendency to form hairpins than sequences containing more nonalternating AT base pairs. Of the two nonalternating sequences, d(T6A6) is significantly less stable than d(A6T6). Both oligomers have CD curves that are very similar to the unusual CD spectrum of poly(dA).poly(dT). The Raman spectra of these two oligomers are also quite similar, but at low temperature, small intensity differences in two backbone modes and three nucleoside vibrations are obtained. The hairpin to duplex transition for the AT dodecamers was examined by salt-jump kinetics measurements. The transition is faster than transitions for palindromic-sequence oligomers containing terminal GC base pairs. Stopped-flow kinetics studies indicate that the transition is second order and has a relatively low activation energy. The reaction rate increases with increasing ionic strength. These results are consistent with a three-step mechanism for the hairpin to duplex reaction: (i) fraying of the hairpin oligomers' terminal base pairs, (ii) a rate-determining bimolecular step involving formation of a cruciform-type intermediate from two hairpin oligomers with open terminal base pairs, and (iii) base-pair migration and formation in the intermediate to give the duplex.     

Circular dichroism studies of the interaction of a limited hydrolysate of T4 gene 32 protein with T4 DNA and poly[d(A-T)].poly[d(A-T)].

gp32 I is a protein with a molecular weight of 27 000. It is obtained by limited hydrolysis of T4 gene 32 coded protein, which is one of the DNA melting proteins. gp32 I itself appears to be also a melting protein. It denatures poly[d(A-T)].poly[d(A-T)] and T4 DNA at temperatures far (50-60 degrees C) below their regular melting temperatures. Under similar conditions gp32 I will denature poly[d(A-T).poly[d(A-T)] at temperatures approximately 12 degrees C lower than those measured for the intact gp32 denaturation. For T4 DNA gp32 shows no melting behavior while gp32 I shows considerable denaturation (i.e., hyperchromicity) even at 1 degree C. In this paper the denaturation of poly[d(A-T)].poly[d(A-T)] and T4 DNA by gp32 I is studied by means of circular dichroism. It appears that gp32 I forms a complex with poly[d(A-T)]. The conformation of the polynucleotide in the complex is equal to that of one strand of the double-stranded polymer in 6 M LiCl. In the gp32 I DNA complex formed upon denaturation of T4 DNA, the single-stranded DNA molecule has the same conformation as one strand of the double-strand T4 DNA molecule in the C-DNA conformation.     

Sequence-dependent variation in the conformation of DNA

The specificity of action of the enzyme DNAase I on double-stranded DNA polymers of defined sequence has been investigated. The results obtained with the alternating copolymers poly[d(A-T)] · poly[d(A-T)] and poly[d(G-C)] · poly[d(G-C)] support the suggestion of Klug et al. (1979) that regions of double-stranded DNA containing alternating purine-pyrimidine sequences may exist as structural variants of the classical B-form under physiological salt conditions. Digestion of defined oligomers containing alternating dG-dC sequences indicate that these too exist in some “alternating-B” structure in solution under similar conditions. The results obtained with the oligomers also provide a number of insights into the mode of action of DNAase I.In the case of the B-DNA dodecamer d(C-G-C-G-A-A-T-T-C-G-C-G), for which the crystal structure has been solved (Dickerson &; Drew, 1981), there is a very good correlation between the sites of rapid DNAase I cutting and positions of high local helical twist.     

Electrophoretic mobility is a reporter of hairpin structure in single-stranded DNA oligomers

The electrophoretic mobilities of 24 single-stranded DNA oligomers, each containing 26 nucleotide residues, have been measured in polyacrylamide gels and in free solution. The mobilities observed at 20 degrees C differed by approximately 20% in polyacrylamide gels and by approximately 10% in free solution, even though the oligomers contained the same number of bases. Increasing the temperature or adding urea to the solution equalized the mobilities of the oligomers, suggesting that the variable mobilities observed at 20 degrees C are due to the formation of stable secondary structures, most likely hairpins. Thermal melting profiles were measured for eight oligomers in 40 mM Tris acetate buffer. The observed melting temperatures of most oligomers correlated roughly with the mobilities observed at 20 degrees C; however, one oligomer was much more stable than the others. The melting temperatures of four of the oligomers were close to the values predicted by DINAMelt [Markham, N. R., and Zuker, M. (2005) Nucleic Acids Res. 33, W577-W581]; melting temperatures of the other oligomers differed significantly from the predicted values. Thermal melting profiles were also measured for two oligomers as a function of the Tris acetate buffer concentration. The salt concentration dependence of the melting temperatures suggests that 0.15 Tris+ ion per phosphate is released upon denaturation. Because the apparent number of Tris+ ions released is greater than that observed by others for the release of Na+ ions from similar hairpins, the results suggest that DNA hairpins (and, presumably, duplexes) bind more Tris+ ions than Na+ ions in solution.     

Syntheses of alternating oligo-2'-O-methylribonucleoside methylphosphonates and their interactions with HIV TAR RNA

Oligonucleotide analogues 15-20 nucleotides in length have been prepared, whose sequences are complementary to nucleotides in the upper hairpin of HIV TAR RNA. These alternating oligonucleoside methylphosphonates, mr-AOMPs, contain 2'-O-methylribonucleosides and alternating methylphosphonate and phosphodiester internucleotide linkages. The methylphosphonate and phosphodiester linkages of these oligomers are highly resistant to hydrolysis by exonuclease activity found in mammalian serum and to endonucleases, such as S1 nuclease. The oligomers were prepared using automated phosphoramidite chemistry and terminate with a 5'-phosphate group, which provides an affinity handle for purification by strong anion exchange HPLC. A 15-mer mr-AOMP, 1676, that is complementary to the 5'-side of the TAR RNA hairpin, including the 3-base bulge and 6-base loop region, forms a 1:1 duplex with a complementary RNA 18-mer, mini-TAR RNA. The T(m) of this duplex is 71 degrees C, which is similar to that of the duplex formed by the corresponding all phosphodiester 15-mer. Introduction of two mismatched bases reduces the T(m) by 17 degrees C. The apparent dissociation constant, K(d), for the 1676/mini-TAR RNA duplex as determined by an electrophoretic mobility shift assay at 37 degrees C is 0.3 nM. Oligomer 1676 also binds tightly to the full length TAR RNA target under physiological conditions (K(d) = 20 nM), whereas no binding was observed by the mismatched oligomer. A 19-mer that is complementary to the entire upper hairpin also binds to TAR RNA with a K(d) that is similar to that of 1676, a result that suggests only part of the oligomer binds. When two of the methylphosphonate linkages in the region complementary to the 6-base loop are replaced with phosphodiester linkages, the K(d) is reduced by approximately a factor of 10. This result suggests that interactions between TAR RNA and the oligomer occur initially with nucleotides in the 6-base loop, and that these interactions are sensitive to presence and possibly the chirality of the methylphosphonate linkages in the oligomer. The high affinities of mr-AOMPs for TAR RNA and their resistance to nuclease hydrolysis suggests their potential utility as antisense agents in cell culture.     

Study of conformation characteristics of "X-form" of alternating polynucleotides by the method of slow 1H----3H transition

The rate constants of 1H----3H exchange between water and C8H-groups of purine residues of alternating polynucleotides: poly[d(A-C)].poly[d(G-T)] and poly[d(A-T)].poly[d(A-T)], as well as Escherichia coli DNA, dAMP and dGMP, in solutions with high concentration (4.3 or 6 M) CsF, in water ethanol (60%) solution and (in comparison) in 0.15 M NaCl were determined at 25 degrees C. The 1H----3H exchange rate exchange rate constants for adenylic (kA) and guanylic (kG) residues of polynucleotides were compared with the corresponding constant for DNA and mononucleotides. It was shown that at conditions when poly[d(G-T)] and poly[d(A-T)].poly[d(A-T)] exhibit the "X-form" CD spectrum, alteration of exchange rates in polynucleotides (approximately 2-fold increase in kA in CSF and approximately 1.5-fold decrease in kA and kG in 60% ethanol with 0.15 M NaCl) is due to the effect of solvents on the chemical reactivity of purine residues, but does not reflect a conformational transition. The analysis of these results allows us to conclude, that alternating polynucleotides under the above mentioned conditions retain roughly the conformations inherent in them in 0.15 M NaCl: poly[d(A-C)].poly[d(G-T)] conformation in 4.3 m CsF or 60% ethanol differs only insignificantly from the "canonic" B-DNA, whereas the poly[d(A-T)].poly[d(A-T)] conformation in 6 M CSF corresponds to B-alternating DNA.     

Parallel double stranded helices and the tertiary structure of nucleic acids

Thermal denaturation of four oligonucleotides, viz. 3'-d(AT)5pO(CH2)6Opd(AT)5-3'(par(AT], 3'-d(AT)5pO(CH2)6Opd(AT)5-5'(anti(AT],3'-d(A)10pO(CH2) 6Op(T)10-3'(par(A-T], and 3'-d(A)10pO(CH2)6Opd(T)10-5' (anti(A-T], was studied in 0.01 M phosphate buffer, pH 7, in the presence of 0.1, 0.25, 0.5 and 1.0 M NaCl. All the oligomers were found to exist at a lower temperature (0 to 20 degrees C) as complexes composed either of two oligomer molecules (a canonical duplex) or of more oligomer molecules whereas, at a higher temperature (30 to 70 degrees C), they formed hairpins with a parallel (par(AT) and par(A-T] or antiparallel (anti(AT) and anti(A-T) orientation of the chains. Melting curves (A260(T] were used to calculate thermodynamic parameters for the formation of hairpins and "low-temperature" duplexes. Experiments on ethidium bromide binding to the oligonucleotides have shown that the oligomer anti(A-T) exists, at a low ionic strength, as a four stranded complex ("quadruplex") contains two antiparallel helices, d(A).d(T), which have a parallel orientation and are bound to one another owing to the formation of additional hydrogen bonds between nucleic acid bases. The possible biological function of quadruplexes is discussed.     

Binding of meso-tetrakis(N-methylpyridinium-4-yl)porphyrin to AT oligomers: effect of chain length and the location of the porphyrin stacking

Circular dichroism (CD) spectra of meso-tetrakis(N-methylpyridinium-4-yl)porphyrin (TMPyP) that are associated with various duplex and triplex AT oligomers were investigated in this study. A strong positive CD was apparent for both the TMPyP complexed with duplex d[(A-T)(12)](2), d(A)(12).d(T)(12) and triplex d(A)(12).d[(T)(12)](2) at a low mixing ratio. As the mixing ratio increased, bisignate excitonic CD was produced for TMPyP complexed with duplexes, whereas the positive CD signal remained the same for the TMPyP-d(A)(12).d[(T)(12)](2) complex. This difference in the CD spectrum in the presence of duplex and triplex oligomers indicates that the moderate stacking of TMPyP occurs at the major groove of the duplex and the monomeric binding occurs in (or near) the minor groove. When TMPyP forms a complex with duplex d[(A-T)(6)](2) only excitonic CD was observed, even at a very low mixing ratio. Therefore, at least seven or more basepairs are required for TMPyP to exhibit a monomeric CD spectrum. After close analysis of the CD spectrum, the TMPyP-poly[d(A-T)(2)] complex could be explained by a combination of the CD spectrum of the monomeric, moderately stacked, and extensively stacked TMPyP.     

Sequence and length dependent thermodynamic differences in heterocyclic diamidine interactions at AT base pairs in the DNA minor groove

With the goal of developing a better understanding of the antiparasitic biological action of DB75, we have evaluated its interaction with duplex alternating and nonalternating sequence AT polymers and oligomers. These DNAs provide an important pair of sequences in a detailed thermodynamic analysis of variations in interaction of DB75 with AT sites. The results for DB75 binding to the alternating and nonalternating AT sequences are quite different at the fundamental thermodynamic level. Although the Gibbs energies are similar, the enthalpies for DB75 binding with poly(dA).poly(dT) and poly(dA-dT).poly(dA-dT) are +3.1 and -4.5 kcal/mol, respectively, while the binding entropies are 41.7 and 15.2 cal/mol.K, respectively. The underlying thermodynamics of binding to AT sites in the minor groove plays a key role in the recognition process. It was also observed that DB75 binding with poly(dA).poly(dT) can induce T.A.T triplet formation and the compound binds strongly to the dT.dA.dT triplex.     

Hairpin and parallel quartet structures for telomeric sequences.

The role of thymine residues in the formation of G-quartet structures for telomeric sequences has been investigated using model oligonucleotides of the type d(G4TnG4), with n = 1-4. Sequences d(G4T3G4) and d(G4T4G4) adopt a G-quartet structure formed by hairpin dimerization in 70 mM NaCl as judged by a characteristic circular dichroism signature with a 295 nm positive and 265 nm negative bands while d(G4TG4) adopts a parallel G-quartet structure like d(G12) which exhibits a strong positive band at 260 nm and a negative band at 240 nm. The sequence d(G4T2G4) exhibits a mixture of both conformations. The stability of hairpin G-quartet structures decreases with decrease in the number of intervening thymine residues. Potassium permanganate, a single strand specific probe has been used to establish the presence of loops composed of T residues in the hairpin G quartet structures formed by the oligonucleotides d(G4TnG4) with n = 2-4 in 70 mM NaCl. The formation of hairpin G quartet structure for the above sequences is further supported by the enhanced electrophoretic mobility observed on non-denaturing polyacrylamide gels. Human telomeric sequence d(TTAGGG)4 which showed enhanced electrophoretic mobility like Tetrahymena telomeric sequence d(T2G4)4 also exhibited a characteristic CD spectrum for a folded-back G-quartet structure. A detailed model for G-quartet structure involving hairpin dimer with alternating syn-anti-syn-anti conformation for the guanine residues both along the chain as well as around the G tetrad with at least two thymine residues in the loop is proposed. Intermolecular association of short telomeric sequences reported here provides a possible model for chromosomal pairing.     

Tandem GA residues on opposite sides of the loop in molecular beacon-like DNA hairpins compact the loop and increase hairpin stability

The free solution electrophoretic mobilities and thermal stabilities of hairpins formed by two complementary 26-nucleotide oligomers have been measured by capillary electrophoresis. The oligomers are predicted to form molecular beacon-like hairpins with 5 bp stems and 16 nucleotides in the loop. One hairpin, called hairpin2 (hp2), migrates with a relatively fast free solution mobility and exhibits melting temperatures that are reasonably well predicted by the popular structure-prediction program Mfold. Its complement, called hairpin1 (hp1), migrates with a slower free solution mobility and forms a stable hairpin only in solutions containing ≥200 mM Na(+). The melting temperatures observed for hp1 are ~18 °C lower than those observed for hp2 and ~20 °C lower than those predicted by Mfold. The greater thermal stability of hp2 is due to the presence of tandem GA residues on opposite sides of the loop. If the corresponding TC residues in the hp1 loop are replaced by tandem GA residues, the melting temperatures of the modified hairpin are close to those observed for hp2. Eliminating the tandem GA residues in the hp2 loop significantly decreases the thermal stability of hp2. If the loops are replaced by a loop of 16 thymine residues, the free solution mobilities and thermal stabilities of the T-loop hairpin are equal to those observed for hp1. Hence, the loop of hp1 appears to be relatively unstructured, with few base-base stacking interactions. Interactions between tandem GA residues on opposite sides of the hp2 loop appear to compact the loop and increase hairpin stability.     

Specific activation of open complex formation at an Escherichia coli promoter by oligo(N-methylpyrrolecarboxamide)s: effects of peptide length and identification of DNA target sites

It has previously been shown that open complex formation at a promoter containing a block substitution of nonalternating A-T sequences in the spacer DNA separating the contacted -10 and -35 regions could be accelerated by distamycin. No stimulation was observed at a promoter with a substitution of alternating A-T base pairs in the same region or at the promoter with wild-type spacer. Here we compare the effect of distamycin [tris(N-methylpyrrolecarboxamide), formally a P3] with that of its extended homologues P4, P5, and P6. It is found that the stimulatory potential of these synthetic oligopeptides which bind in the minor groove of DNA ranks in the order P4 greater than (distamycin, P5) greater than P6. The interaction of these peptides with the three promoters was studied by monitoring the positions of the promoter DNA protected from MPE-Fe(II) cleavage in the presence of different concentrations of ligand. The results suggest that a higher affinity of oligopeptide for the spacer DNA than for the -10 and/or -35 region is a necessary, but not sufficient condition for stimulation. Different patterns of protected DNA regions are seen with each of the three promoters; with distamycin, P4, and P5, a unique arrangement of protected regions is observed for the variant containing nonalternating A-T base pairs in its spacer DNA. These data support the hypothesis that differences in the ways the minor-groove binders interact with each of the promoter variants account for the observed differential stimulation. We further postulate that it is a ligand-induced structural change in the nonalternating A-T DNA which is responsible for the activation of open complex formation at the promoter containing this substitution.     

Detection of neocarzinostatin chromophore-deoxyribose adducts as exonuclease-resistant sites in defined-sequence DNA

A 5'-end-labeled DNA restriction fragment was treated with the nonprotein chromophore of neocarzinostatin under anoxia in the presence of dithiothreitol, conditions known to maximize formation of chromophore-deoxyribose adducts. Under conditions where unmodified DNA was digested to completion, chromophore-treated DNA was highly resistant to digestion by exonuclease III plus the 3'----5' exonucleolytic activity of T4 DNA polymerase and partially resistant to digestion by exonuclease III plus snake venom exonuclease. The electrophoretic mobilities of the products of exonucleolytic digestion suggested that (i) digestion by exonuclease III or T4 polymerase terminated one nucleotide before the nucleotide containing the adduct, (ii) the remaining nucleotide directly adjacent to the adduct (3' side) could be removed by snake venom phosphodiesterase, but at a slow rate, (iii) the covalently linked chromophore decreased the electrophoretic mobilities of the digestion products by the equivalent of approximately three nucleotides, and (iv) adducts formed under anaerobic conditions occurred at the same nucleotide positions as the strand breaks formed under aerobic conditions (primarily at T and, to a lesser extent, A residues). The close similarity in sequence specificity of adducts and strand breaks suggests that a common form of nascent DNA damage may be a precursor to both lesions. A chromophore-induced free radical on C-5' of deoxyribose, subject to competitive fixation by addition reactions with either oxygen or chromophore, is the most likely candidate for such a precursor. The base specificity of adduct formation does not reflect the reported base specificity of neocarzinostatin-induced mutagenesis, suggesting that lesions other than adducts may be responsible for at least some neocarzinostatin-induced mutations, particularly those occurring at G X C base pairs.     

Preferential counterion binding to A-tract DNA oligomers

The free solution mobility of four 20 bp DNA oligomers, with and without A-tracts, has been measured by capillary electrophoresis in Tris-acetate buffer, to test the hypothesis that site-specific binding of monovalent counterions can occur in the narrow minor groove of A-tract DNAs. Preferential counterion binding has been proposed to cause A-tract bending because of asymmetric charge neutralization and collapse of the helix backbone toward the minor groove. Preferential counterion binding in A-tract DNAs should be manifested by a decrease in the electrophoretic mobility observed in free solution, compared to that of non-A-tract DNAs of the same size. Of the four sequences studied here, the slowest absolute mobility, indicative of the greatest counterion binding, was observed for a 20 bp oligomer containing two runs of A3T3 in phase with the helix repeat. A 20-mer containing phased CACA sequences migrated with the fastest mobility; 20-mers containing phased A5 tracts or phased runs of T3A3 migrated with intermediate mobilities. Very similar mobility differences were observed when 1-20 mM NaCl was added to the buffer. The results suggest that preferential counterion binding occurs in A-tract DNAs, especially those containing the AnTn sequence motif.     

Unusual duplex formation in purine rich oligodeoxyribonucleotides

The purine rich oligodeoxyribonucleotides 1C, d(ATGACGGAATA) and 2C, d(ATGAGCGAATA) alone exhibit highly cooperative melting transitions. Analysis of the concentration dependence of melting, and electrophoretic studies indicate that these oligomers can form an unusual purine rich offset double helix. The unusual duplex is predicted to contain four A.T, two G.C, and four G.A mismatch base pairs as well as a single A base stacked on the 3' end of each chain of the helix. Other possible models for the duplex are unlikely because they are predicted to contain many base pairs of low stability. Changing the central sequence to CGG or GGG should destabilize the duplex and this is observed. The unusual duplex of 2C is more stable than the duplex of 1C indicating that the stability of G.A base pairs is quite sensitive to the surrounding sequence. Addition of 1C and 2C to their complementary pyrimidine strands results in normal duplexes of similar stability. We feel that the unusual duplexes are significantly stabilized by the intrinsic stacking tendency of purine bases.     

Studies of DNA dumbbells. II. Construction and characterization of DNA dumbbells with a 16 base-pair duplex stem and Tn end loops (n = 2, 3, 4, 6, 8, 10, 14).

The preparation and characterization of DNA dumbbells that contain the 16 base-pair duplex sequences 5'G-C-A-T-A-G-A-T-G-A-G-A-A-T-G-C3' (set 1) and 5'G-C-A-T-C-A-T-C-G-A-T-G-A-T-G-C3' (set 2) are reported. The dumbbells of set 1 have the duplex stem nucleated on both ends by Tn (n = 2, 3, 4, 6, 8, 10, and 14) loops. The dumbbells of set 2 have Tn (n = 2, 4, 8, 10) end loops. For the molecules of set 1, effects of end loop size on the electrophoretic mobility, CD and UV absorbance spectra, and cleavage by restriction enzymes, were investigated. Effects of loop size on the CD spectra and restriction enzyme cleavage of the molecules of set 2 were also examined. Optical melting curves of the molecules of set 1 were collected as a function of sodium ion concentration from 30 to 120 mM. These investigations revealed that as loop size decreases, the electrophoretic mobilities, rates of enzyme cleavage, and optical melting temperatures increase. For end loops with at least three T's the observed increases are inversely proportional to loop size. The behavior of the dumbbell with T2 end loops departs from this linear dependence and is anomalous in every experimental context. For molecules with end loops comprised of at least four T's CD spectra were virtually indistinguishable. However, these spectra differed considerably from the CD spectrum of the T2-looped molecule. The CD spectrum of the dumbbell with T3 end loops displayed features common to the dumbbells with larger loops and T2 end loops. Thermodynamic evidence that the terminal G.C base pairs (bps) nucleating the T2 end loops were intact was obtained from a comparison of the melting temperature of this molecule with that of a DNA dumbbell containing the 14 central bps of the set 1 duplex sequence linked instead by end loops comprised of the four base sequence, C-T-T-C. The tm of this latter molecule was determined to be 9 degrees C less than that of the former dumbbell assumed to contain a 16-bp stem and T2 end loops.(ABSTRACT TRUNCATED AT 400 WORDS)     

A new method for detection of small modifications in genomic DNA, applied to the human delta-beta globin gene cluster

Cloned DNA fragments were subcloned in filamentous coliphages fd 103 or M 13; the recombinant single-stranded DNAs were then used to form hybrids with genomic DNA as well as with complementary recombinant single-stranded DNA. Hybrids were submitted to S1-nuclease treatment alone or in combination with restriction enzyme digestions. This method was used to analyze the delta-beta globin gene cluster from the total genomic DNA of a beta 0-thalassemic patient. A modification located approximately 530 base pairs upstream from the cap site of the beta-globin gene was detected in only one thalassemic chromosome of this patient. Sequence analysis have shown that the patient was homozygous for a single nucleoside change (dC----dT) which remains undetected by our hybridization method, leading to a codon 39 nonsense mutation; they have demonstrated too that he was heterozygous for the modification mentioned and detected by S1-nuclease, which corresponds to an additional sequence d(T-A-T-A) in a 52 alternating purine-pyrimidine run, leading to a complex change from d[(A-T)7(T)7] to d[(A-T)11(T)3].     

Apparent electric charge of protein molecules. Human thyroxine - binding proteins

1. By comparison of electrophoretic mobilities of two different charged particles under the same conditions the net elementary electrostatic charge of one particle could be calculated when the charge of the other is known. 2. The electrophoretic mobility of human thyroxine - binding globulin does not depend upon the concentration of Tris - HCl buffer in the range 0.05 to 0.20 molar. The value of this mobility is 0.078 and 0.083 cm2 vol(-1) hour(-1) at pH 7.0 and 8.6, respectively. 3. The net elementary electrostatic charge of the human thyroxine - binding globulin appears to be approximately 22 negative elementary electrostatic units in mild alkaline solutions.     

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.