Selection of primer-template sequences that bind human immunodeficiency virus reverse transcriptase with high affinity

A SELEX (systematic evolution of ligands by exponential enrichment)-based approach was developed to determine whether HIV-RT showed preference for particular primer-template sequences. A 70 nt duplex DNA was designed with 20 nt fixed flanking sequences at the 3' and 5' ends and a randomized 30 nt internal sequence. The fixed sequence at the 5' end contained a BbsI site six bases removed from the randomized region. BbsI cuts downstream of its recognition site generating four base 5' overhangs with recessed 3' termini. Cleavage produced a 50 nt template and 46 nt primer with the 3' terminus within the randomized region. HIV-RT was incubated with this substrate and material that bound RT was isolated by gel-shift. The recovered material was treated to regenerate the BbsI site, amplified by PCR, cleaved with BbsI and selected with HIV-RT again. This was repeated for 12 rounds. Material from round 12 bound approximately 10-fold more tightly than starting material. All selected round 12 primer-templates had similar sequence configuration with a 6-8 base G run at the 3' primer terminus, similar to the HIV polypurine tract. Further modifications indicate that the Gs were necessary and sufficient for strong binding.     

Enzymatic incorporation of a third nucleobase pair

DNA polymerases are identified that copy a non-standard nucleotide pair joined by a hydrogen bonding pattern different from the patterns joining the dA:T and dG:dC pairs. 6-Amino-5-nitro-3-(1'-beta-D-2'-deoxyribofuranosyl)-2(1H)-pyridone (dZ) implements the non-standard 'small' donor-donor-acceptor (pyDDA) hydrogen bonding pattern. 2-Amino-8-(1'-beta-D-2'-deoxyribofuranosyl)-imidazo[1,2-a]-1,3,5-triazin-4(8H)-one (dP) implements the 'large' acceptor-acceptor-donor (puAAD) pattern. These nucleobases were designed to present electron density to the minor groove, density hypothesized to help determine specificity for polymerases. Consistent with this hypothesis, both dZTP and dPTP are accepted by many polymerases from both Families A and B. Further, the dZ:dP pair participates in PCR reactions catalyzed by Taq, Vent (exo-) and Deep Vent (exo-) polymerases, with 94.4%, 97.5% and 97.5%, respectively, retention per round. The dZ:dP pair appears to be lost principally via transition to a dC:dG pair. This is consistent with a mechanistic hypothesis that deprotonated dZ (presenting a pyDAA pattern) complements dG (presenting a puADD pattern), while protonated dC (presenting a pyDDA pattern) complements dP (presenting a puAAD pattern). This hypothesis, grounded in the Watson-Crick model for nucleobase pairing, was confirmed by studies of the pH-dependence of mismatching. The dZ:dP pair and these polymerases, should be useful in dynamic architectures for sequencing, molecular-, systems- and synthetic-biology.     

Comparison of interactions of 5′-derivatives of deoxyoctathymidylate with human DNA polymerize α and HIV reverse transcriptase

K_m and V_max values for d(pT₈) and its derivatives containing various 5′-end groups were estimated in the reaction of DNA polymerization α catalyzed by DNA polymerase α and HIV-RT. The effect of 5′-end modification of primer is more pronounced in the case of HIV-RT. Strong influence is observed for an intercalating (ethidium) group. The affinity of EtpT₈ is 200-fold higher than that of d(pT₈). Attachment of Phn-, Dnm- and Hem-groups results in the increase of affinity of modified primer from 10 up to 20 times. For DNA polymerase α the influence of modifiers on primer affinity is much weaker. The effect of 5′-end residues on the V_max values is also more pronounced for HIV RT. The way to improve selective interaction of oligonucleotide derivatives with the primer site of HIV RT is suggested.     

Lysine 188 of the catabolite gene activator protein (CAP) plays no role in specificity at base pair 7 of the DNA half site.

Two similar, but not identical, models have been proposed for the amino acid-base pair contacts in the CAP-DNA complex ('model I,' Weber, I. and Steitz, T., Proc. Natl. Acad. Sci. USA, 81, 3973-3977, 1984; 'model II,' Ebright, et al., Proc. Natl. Acad. Sci. USA, 81, 7274-7278, 1984). The most important difference between the two models involves Lys188 of CAP. Model I predicts that Lys188 of CAP makes a specificity determining contact with base pair 7 of the DNA half site. In contrast, model II predicts that Lys188 makes no contact with base pair 7 of the DNA half site. In the present work, we have used site-directed mutagenesis to replace Lys188 of CAP by Asn, an amino acid unable to make the putative contact. We have assessed the specificities of the following proteins, both in vitro and in vivo: wild-type CAP, [Asn188]CAP, [Val181]CAP, and [Val181;Asn188]CAP. The results indicate that Lys188 makes no contribution to specificity at base pair 7 of the DNA half site. We propose, contrary to model I, that Lys188 makes no contact with base pair 7 of the DNA half site.     

Functional hydrogen-bonding map of the minor groove binding tracks of six DNA polymerases

Recent studies have identified amino acid side chains forming several hydrogen bonds in the DNA minor groove as potentially important in polymerase replication of DNA. Few studies have probed these interactions on the DNA itself. Using non-hydrogen-bonding nucleoside isosteres, we have now studied effects in both primer and template strands with several polymerases to investigate the general importance of these interactions. All six polymerases show differences in the H-bonding effects in the minor groove. Two broad classes of activity are seen, with a first group of DNA polymerases (KF(-), Taq, and HIV-RT) that efficiently extends nonpolar base pairs containing nucleoside Q (9-methyl-1H-imidazo[4,5-b]pyridine) but not the analogue Z (4-methylbenzimidazole), implicating a specific minor groove interaction at the first extension site. A second group of polymerases (Pol alpha, Pol beta, and T7(-)) fails to extend all non-H-bonding base pairs, indicating that these enzymes may need minor groove hydrogen bonds at both minor groove sites or that they are especially sensitive to noncanonical DNA structure or stability. All DNA polymerases examined use energetically important minor groove interactions to probe newly synthesized base pairs before extending them. The positions of these interactions vary among the enzymes, and only a subset of the interactions identified structurally appears to be functionally important. In addition, polymerases appear to be differently sensitive to small changes in base pair geometry.     

A code governing specific binding of regulatory proteins to DNA and structure of stereospecific sites of regulatory proteins]

A model is proposed for the structure of stereospecific sites in regulatory proteins. On its basis a possible code is suggested that governs the binding of regulatory proteins at specific control sites on DNA. Stereospecific sites of regulatory proteins are assumed to contain pairs of antiparallel polypeptide chain segments which form a right-hand twisted antiparallel beta-sheet, with single-stranded regions at the ends of the beta-structure. The model predicts that binding reaction between a regulatory protein and double-helical DNA is a cooperative phenomenon and is accompanied by significant structural alteration at the stereospecific site of the protein. Half of hydrogen bonds normally existing in beta-structure are broken upon complex formation with DNA and a new set of hydrogen bonds is formed between polypeptide amide groups and DNA base pairs. In a stereospecific site, one chain (t-chain) is attached through hydrogen bonds to the carbonyl oxygens of pyramides and N3 adenines lying in one DNA strand, while the second polypeptide chain (g chain) is hydrogen bonded to the 2-amino groups of guanine residues lying in the opposite DNA strand. The amide groups serve as specific reaction sites being hydrogen bond acceptors in g-chain and hydrogen bond donors in t-chain. The single-stranded portions of t- and g-chains lying in neighbouring subunits of regulatory protein interact with each other forming deformed beta-sheets. The recognition of regulatory sequences by proteins is based on the structural complementarity between stereospecific sites of regulatory proteins and base pairs sequences at the control sites. An essential feature of these sequences is the asymmetrical distribution of guanine residues between the two DNA strands. The code predicts that there are six fundamental amino acid residues (serine, threonine, asparagine, histidine, glutamine and cysteine) whose sequence in stereospecific site determines the base pair sequence to which a given regulatory protein would bind preferentially. The code states a correspondence between four amino acid residues at the stereospecific site of regulatory protein with the two residues being in t- and g-segments, respectively, and AT(GC) base pair at the control site. It is thus possible to determine which amino acid residues in the repressor and which base pairs in the operator DNA are involved in specific interactions with each other, as exemplified by lac repressor binding to lac operator.     

Chemical consequences of incorporation of 5-fluorouracil into DNA as studied by NMR

The cytotoxic analogue of thymine, 5-fluorouracil (Uf), is known to be incorporated into DNA in biological systems. This abnormal base has been synthetically incorporated into short DNA oligomers. The ionization of the N-3 proton of this base within DNA oligomers was measured by observation of the 19F chemical shift at varying pH values. The pKa values for the Uf ring of dTpdUfpdT and dApdUfpdA were determined to be 7.84 and 7.9, respectively. The self-complementary 12-mers d(G-C-G-C-A-A-T-Uf-G-C-G-C) and d(C-G-A-T-Uf-A-T-A-A-T-C-G) were synthesized, and 1H NMR was used to compare the helix dynamics and stability of the interstrand imino proton hydrogen bonds with those of the 12-mers d(G-C-G-C-A-A-T-T-G-C-G-C) and d(C-G-A-T-T-A-T-A-A-T-C-G). The N-3 hydrogen bond of the A-Uf base pair was less stable than the corresponding hydrogen bond in A-T base pairs in the same helix, and the A-Uf base pair was less stable than the A-T base pair in the analogous position of the control helix. The observed temperature-dependent dynamics and NMR melting temperatures of the control and dUf-containing oligomers were similar.     

Thermodynamics of DNA containing very stable chemically modified base pairs

DNA chemical modifications caused by the binding of some antitumor drugs give rise to a very strong local stabilization of the double helix. These sites melt at a temperature that is well above the melting temperatures of ordinary AT and GC base pairs. In this work we have examined the melting behavior of DNA containing very stable sites. Analytical expressions were derived and used to evaluate the thermodynamic properties of homopolymer DNA with several different distributions of stable sites. The results were extended to DNA with a heterogeneous sequence of AT and GC base pairs. The results were compared to the melting properties of DNA with ordinary covalent interstrand cross-links. It was found that, as with an ordinary interstrand cross-link, a single strongly stabilized site makes a DNA's melting temperature (T(m)) independent of strand concentration. However in contrast to a DNA with an interstrand cross-link, a strongly stabilized site makes the DNA's T(m) independent of DNA length and equal to T(infinity), the melting temperature of an infinite length DNA with the same GC-content and without a stabilized site. Moreover, at a temperature where more than 80% of base pairs are melted, the number of ordinary (non-modified) helical base pairs (n) is independent of both the DNA length and the location of the stabilized sites. For this condition, n(T) = (2 omega-a)S/(1-S) and S = exp[DeltaS(T(infinity)-T)/(RT)] where omega is the number of strongly stabilized sites in the DNA chain, a is the number of DNA ends that contain a stabilized site, and DeltaS, T, and R are the base pair entropy change, the temperature, and the universal gas constant per mole. The above expression is valid for a temperature interval that corresponds to n<0.2N for omega=1, and n<0.1N for omega>1, where N is the number of ordinary base pairs in the DNA chain.     

An unnatural base pair system for efficient PCR amplification and functionalization of DNA molecules

Toward the expansion of the genetic alphabet, we present an unnatural base pair system for efficient PCR amplification, enabling the site-specific incorporation of extra functional components into DNA. This system can be applied to conventional PCR protocols employing DNA templates containing unnatural bases, natural and unnatural base triphosphates, and a 3′→5′ exonuclease-proficient DNA polymerase. For highly faithful and efficient PCR amplification involving the unnatural base pairing, we identified the natural-base sequences surrounding the unnatural bases in DNA templates by an in vitro selection technique, using a DNA library containing the unnatural base. The system facilitates the site-specific incorporation of a variety of modified unnatural bases, linked with functional groups of interest, into amplified DNA. DNA fragments (0.15 amol) containing the unnatural base pair can be amplified 10⁷-fold by 30 cycles of PCR, with <1% total mutation rate of the unnatural base pair site. Using the system, we demonstrated efficient PCR amplification and functionalization of DNA fragments for the extremely sensitive detection of zeptomol-scale target DNA molecules from mixtures with excess amounts (pmol scale) of foreign DNA species. This unnatural base pair system will be applicable to a wide range of DNA/RNA-based technologies.     

Ambiguous base pairing of the purine analogue 1-(2-deoxy-beta-D-ribofuranosyl)-imidazole-4-carboxamide during PCR.

In principle the hydrogen bonding capacities of 1-(2-deoxy-beta-D-ribofuranosyl)-imidazole-4-carboxamide (dY), and its N-propyl derivative (dYPr), allow them to pair to all four deoxynucleosides. Their triphosphate derivatives (dYTP and dYPrTP) are preferentially incorporated as dATP analogues in a PCR reaction. However, once incorporated into a DNA template their ambiguous hydrogen bonding potential gave rise to misincorporation at frequencies of approximately 3 x 10(-2) per base per amplification. Most of the substitutions were transitions resulting from rotation about the carboxamide bond when part of the template. Between 11-15% of transversions were noted implying rotation of purine or imidazole moieties about the glycosidic bond. As part of a DNA template, dYPr behaved in the same way as dY, despite its propyl moiety. These deoxyimidazole derivatives are among the most radical departures from the canonical bases used so far as substrates in PCR and could be used to generate mutant gene libraries.     

Retrospective study of Chlamydia trachomatis using the polymerase chain reaction on archival Papanicolaou-stained cytologic smears.

OBJECTIVE: To detect chlamydial DNA on archived Papanicolaou-stained (Pap) smears using the polymerase chain reaction (PCR) technique. STUDY DESIGN: A PCR assay was designed to identify chlamydial DNA using consensus sequences unique to the genus Chlamydia in the 16S rRNA gene. This assay produced a 109 base pair product containing a single Pvu II restriction site. One hundred cervicovaginal Pap smears from a teen clinic population were processed for DNA isolation and PCR. Amplifiable DNA was isolated from 93 of the 100 cases as determined by a human growth hormone gene. These specimens were subjected to chlamydial PCR. RESULTS: PCR analysis of the 93 samples yielded 6 that were positive for the chlamydial 16S rRNA sequence. The six positive chlamydial amplicons were purified and subjected to Pvu II restriction enzyme analysis to validate their identity. The analysis confirmed the identity of the products, as a single Pvu II restriction site resulted in 41 base pair and 68 base pair products, as predicted. CONCLUSION: PCR testing for Chlamydia trachomatis can be performed on DNA isolated from archival Pap smears. Using this methodology, 6.5% of young women in our teen clinic population were positive for chlamydial DNA.     

Systematic Analysis of Possible Hydrogen Bonds between Amino Acid Side Chains and B-form DNA

Abstract

The ways in which amino acid side chains could make a pair of hydrogen bonds within the major groove of B DNA are systematically analyzed. Hydrogen bond donors within the major groove are characterized by determining the idealized position of the hydrogen bond acceptors that they might bond with. It appears that an amino acid side chain could, at most, contact a pair of base pairs. The ten possible pairs of base pairs are analyzed to determine how they could be recognized by the amino acid side chains.