The 3' 5' exonucleases

Over the past few years, several new 3' 5' exonucleases have been identified. In vitro studies of these enzymes have uncovered much about their potential functions in vivo, and certain organisms with a defect in 3' 5' exonucleases have an increased susceptibility to cancer, especially under conditions of stress. Here, we look at not only the newly discovered enzymes, but also at the roles of other 3' 5' exonucleases in the quality control of DNA synthesis, where they act as proofreading exonucleases for DNA polymerases during DNA replication, repair and recombination.     

Studies towards the large scale chemical synthesis of the precursors of ribonucleosides-3',4',5',5'-2H4 and -2',3',4',5',5'-2H5

A summary delineating the large scale synthetic studies to prepare labeled precursors of ribonucleosides-3',4',5',5'-2H4 and -2',3',4',5',5'-2H5 from D-glucose is presented. The recycling of deuterium-labeled by-products has been devised to give a high overall yield of the intermediates and an expedient protocol has been elaborated for the conversion of 3-O-benzyl-alpha,beta-D-allofuranose-3,4-d2 6 to 1-O-methyl-3-O-benzyl-2-O-t-butyldimethylsilyl-alpha,beta-D-ribofuranose-3,4,5,5'-d4 16 (precursor of ribonucleosides-3',4',5',5'-2H4) or to 1-O-methyl-3,5-di-O-benzyl-alpha,beta-D-ribofuranose-3,4,5,5'-d4 18 (precursor of ribonucleosides-3',4',5',5'-2H4).     

Parallel helical domains in DNA branched junctions containing 5',5' and 3',3' linkages

The Holliday junction is a central intermediate in genetic recombination. It contains four strands of DNA that are paired into four double helical arms that flank a branch point. In the presence of Mg2+, the four arms are known to stack in pairs forming two helical domains whose orientations are antiparallel but twisted by about 60 degrees. The basis for the antiparallel orientation of the domains could be either junction structure or the effect of electrostatic repulsion between domains. To discriminate between these two possibilities, we have constructed and characterized an analogue, called a bowtie junction, in which one strand contains a 3',3' linkage at the branch point, the strand opposite it contains a 5',5' linkage, and the other two strands contain conventional 3',5' linkages. Electrostatic effects are expected to lead to an antiparallel structure in this system. We have characterized the molecule in comparison with a conventional immobile branched junction by Ferguson analysis and by observing its thermal transition profile; the two molecules behave virtually identically in these assays. Hydroxyl radical autofootprinting has been used to establish that the unusual linkages occur at the branch point and that the arms stack to form the same domains as the conventional junction. Cooper-Hagerman gel mobility analyses have been used to determine the relative orientations of the helical domains. Remarkably, we find them to be closer to parallel than to antiparallel, suggesting that the preferred structure of the branch point dominates over electrostatic repulsion. We have controlled for the number of available bonds in the branch point, for gel concentration, and for the role of divalent cations. This finding suggests that control of branch point structure alone can lead to parallel domains, which are generally consistent with recombination models derived from genetic data.     

Rapid amplification of 5' complementary DNA ends (5' RACE)

This method is used to extend partial cDNA clones by amplifying the 5' sequences of the corresponding mRNAs 1-3. The technique requires knowledge of only a small region of sequence within the partial cDNA clone. During PCR, the thermostable DNA polymerase is directed to the appropriate target RNA by a single primer derived from the region of known sequence; the second primer required for PCR is complementary to a general feature of the target-in the case of 5' RACE, to a homopolymeric tail added (via terminal transferase) to the 3' termini of cDNAs transcribed from a preparation of mRNA. This synthetic tail provides a primer-binding site upstream of the unknown 5' sequence of the target mRNA. The products of the amplification reaction are cloned into a plasmid vector for sequencing and subsequent manipulation.     

Flexibility of 3',5' deoxyribonucleoside diphosphates

In 3',5' deoxyribonucleoside diphosphates, in addition to the nature of the base and the sugar puckering, there are six single bond rotations. However, from the analysis of crystal structure data on the constituents of nucleic acids, only three rotational angles, that are about glycosyl bond, about C4'-C5' and about C3'-O3' bonds, are flexible. For a given sugar puckering and a base, potential energy calculations using non-bonded, electrostatic and torsional functions were carried out by varying the three torsion angles. The energies are represented as isopotential energy surfaces. Since the availability of the real-time color graphics, it is possible to analyse these isopotential energy surfaces. The calculations were carried out for C3' exo and C3' endo puckerings for deoxyribose and also for four bases. These calculations throw more light not only on the allowed regions for the three rotational angles but also on the relationships among them. The dependence of base and the puckering of the sugar on these rotational angles and thereby the flexibility of the 3',5' deoxyribonucleoside diphosphates is discussed. From our calculations, it is now possible to follow minimum energy path for interconversion among various conformers.     

Oligoribonucleotides containing 2',5'-phosphodiester linkages exhibit binding selectivity for 3',5'-RNA over 3',5'-ssDNA.

Oligoribonucleotides containing 2',5'-phosphodiester linkages have been synthesized on a solid support by the 'silyl-phosphoramidite' method. The stability of complexes formed between these oligonucleotides and complementary 3',5'-RNA strands have been studied using oligoadenylates and a variety of oligonucleotides of mixed base sequences including phosphorothioate backbones. In many cases, particularly for 2',5'-linked adenylates, the UV melting profiles are quite sharp and exhibit large hyperchromic changes. Substituting a few 3',5'-linkages with the 2',5'-linkage within an oligomer lowers the Tm of the complex and the degree of destabilization depends on the neighboring residues and neighboring linkages. The 2',5'-linked oligoribonucleotides prepared in this study exhibited remarkable selectivity for complementary single stranded RNA over DNA. For example, in 0.01 M phosphate buffer--0.10 M NaCl (pH 7.0), no association was observed between 2',5'-r(CCC UCU CCC UUC U) and its Watson-Crick DNA complement 3',5'-d(AGAAGGGAGAGGG). However, 2',5'-r(CCC UCU CCC UUC U) with its RNA complement 3',5'-r(AGAAGGGAGAGGG) forms a duplex which melts at 40 degrees C. The decamer 2',5'-r(Ap)9A forms a complex with both poly dT and poly rU but the complex [2',5'-r(Ap)9A]:[poly dT] is unstable (Tm, -1 degree C) and is seen only at high salt concentrations. In view of their unnatural character and remarkable selectivity for single stranded RNA, 2',5'-oligo-RNAs and their derivatives may find use as selective inhibitors of viral mRNA translation, and as affinity ligands for the purification of cellular RNA.     

(2')3',5'-Bisphosphate nucleotidase

(2')3',5'-Bisphosphate nucleotidase has been prepared in electrophoretically homogeneous form from guinea pig liver. The enzyme catalyzes the hydrolysis of the 2'- or 3'-phosphate from the appropriate nucleoside 2',5'- and 3',5'-bisphosphates and is active with 3'-phosphoadenosine 5'-phosphosulfate and with coenzyme A but not with ATP. The 40,000-dalton protein is a monomer that requires Mg2+ for activity.     

Synthesis of 5'(3')-O-amino nucleosides

Synthetic methods leading to 5'(3')-O-amino nucleosides have been developed in an effort to prepare derivatives that may have antitumor or antiviral activities. They are based on ring opening of O2,5'-cyclonucleosides with the N-protected hydroxylamines and dehydrative coupling of 5'(3')-O-unprotected nucleosides with N-hydroxyphthalimide.     

Adenosine(5')tetraphospho(5')adenosine-binding protein of calf thymus

An adenosine(5')tetraphospho(5')adenosine (Ap4A) binding protein has been purified from calf thymus. The protein is comprised of a single polypeptide of Mr 54000 and is capable of high-affinity (Kd = 13 microM) binding of Ap4A with great substrate specificity. The Ap4A binding protein has been isolated in two forms: a 'free', or non-polymerase-bound, form which predominates, and a similar form which copurifies with DNA polymerase alpha, but which can be resolved from it. The free form of Ap4A binding protein contains associated adenosine(5')tetraphospho(5')adenosine phosphohydrolase (Ap4Aase) activity, while the form resolved from DNA polymerase alpha contains no such activity. The Ap4Aase activity, which catalyzes the phosphohydrolysis of Ap4A to ATP and AMP, is strongly inhibited by low levels (50-100 microM) of Zn2+ without any effect on the Ap4A binding protein activity. This difference in associated Ap4Aase activity between free and polymerase-bound forms of the protein, plus the copurification mentioned above, indicate a specific association between Ap4A binding protein and DNA polymerase alpha.     

2',5'-Oligoadenylate and 2',5'-oligoadenylate phosphodiesterase in human plasma

2',5'-Oligoadenylate and 2',5'-oligoadenylate phosphodiesterase activity were detected in the human plasma and serum by sensitive radioimmuno assays. The phosphodiesterase in the serum degraded 20 nM of added 2',5'-oligoadenylate in less than 1 hr. Addition of EDTA in the blood sample inhibited the phosphodiesterase activity completely and allowed the measurement of low levels of 2',5'-oligoadenylate. The concentration in the plasma from healty people was in the range of 0.03 to 0.3 nM.     

5' cleavage site in eukaryotic pre-mRNA splicing is determined by the overall 5' splice region, not by the conserved 5' GU

We have generated all possible single point mutations of the invariant 5' GT of the large beta-globin intron and determined their effect on splicing in vitro. None of the mutants prevented cleavage in the 5' splice region, but many reduced or abolished exon joining. The mutations GT----TT and GT----CT resulted in a shift of the 5' cleavage site on nucleotide upstream; in the case of the mutation GT----TT, this shift was reverted by a second site mutation within the 5' splice region. Our results suggest that the 5' cleavage site is determined not by the conserved GU sequence but by the 5' splice region as a whole, most probably via base-pairing to the 5' end of the U1 snRNA.