Transcription, beta-like DNA polymerases and hypermutation.

This paper discusses two aspects of immunoglobulin (Ig) gene hypermutation. In the first approach, a transcription termination signal is introduced in an Ig light chain transgene acting as a mutation substrate, and transgenic lines are generated with control and mutant transgenes integrated in tandem. Analysis of transcription levels and mutation frequencies between mutant and control transgenes clearly dissociates transcription elongation and mutation, and therefore argues against models whereby specific pausing of the RNA polymerase during V gene transcription would trigger an error-prone repair process. The second part reports the identification of two novel beta-like DNA polymerases named Pol lambda and Pol mu, one of which (Pol mu) represents a good candidate for the Ig mutase due to its higher lymphoid expression and its similarity with the lymphoid enzyme terminal deoxynucleotidyl transferase. Peculiar features of the expression of this gene, including an unusual splicing variability and a splicing inhibition in response to DNA-damaging agents, are discussed.

Two novel human and mouse DNA polymerases of the polX family.

We describe here two novel mouse and human DNA polymerases: one (pol lambda) has homology with DNA polymerase beta while the other one (pol mu) is closer to terminal deoxynucleotidyltransferase. However both have DNA polymerase activity in vitro and share similar structural organization, including a BRCT domain, helix-loop-helix DNA-binding motifs and polymerase X domain. mRNA expression of pol lambda is highest in testis and fetal liver, while expression of pol mu is more lymphoid, with highest expression both in thymus and tonsillar B cells. An unusually large number of splice variants is observed for the pol mu gene, most of which affect the polymerase domain. Expression of mRNA of both polymerases is down-regulated upon treatment by DNA damaging agents (UV light, gamma-rays or H(2)O(2)). This suggests that their biological function may differ from DNA translesion synthesis, for which several DNA polymerase activities have been recently described. Possible functions are discussed.

Inhibition of apoptosis of a PARP(-)/(-)cell line transfected with PARP DNA-binding domain mutants.

We have investigated the possibility of the involvement of PARP in apoptosis, independently of its enzymatic activity. We thus transfected PARP(-)/(-)A11 cells with a DNA construct encoding the PARP DNA-binding domain (DBD) fragment or mutants DBDbd(-), defective in DNA binding to DNA strand breaks, and DBDcl(-), resistant to caspase-3 cleavage. We found that in the absence of PARP, while expression of DBD has only a marginal effect, expression of the mutants strongly inhibits the apoptosis induced by staurosporine, as measured by the binding of annexin V. Moreover, the mutants, but not DBD, inhibit the cleavage of DNA PKcs, suggesting inhibition of activation of caspase-3. In addition, the mutant transfectants are fractionally less susceptible to low doses of an alkylating agent than the DBD transfectant or the original A11 line. The results suggest that the DBD fragment of PARP, apart from its classical role of nick detection and DNA binding, participates in complexes involved in upstream events leading to activation of the caspase cascade.

Regulation by phosphorylation of Xenopus laevis poly(ADP-ribose) polymerase enzyme activity during oocyte maturation.

Poly(ADP-ribose) polymerase (PARP) is an abundant nuclear enzyme that is dependent on DNA breaks and nicks for its enzyme activity. These DNA nicks and breaks function as allosteric effectors of the enzyme activity. This reaction is important for efficient DNA base excision repair, although it is not a component of the elementary repair pathway itself. The physiological relevance of this reaction might be to ensure correct and efficient DNA repair. We have examined the enzyme activity of PARP in oocytes and eggs of Xenopus laevis. Although both oocytes and eggs contain approximately the same amounts of enzyme protein, there is no detectable enzyme activity in the oocytes, whereas in the eggs the enzyme is active. Enzyme activity appears during oocyte maturation, approx. 4 h after induction by progesterone. This enzyme activation coincides with the appearance of active maturation-promoting factor. Enzyme activation is accompanied by a shift in the electrophoretic mobility of the polypeptide, from an apparent molecular mass of 116 kDa to 125 kDa. Treatment with either bacterial or potato phosphatase reverses the mobility shift and abolishes enzyme activity. Incubation of maturing X. laevis eggs with radioactive inorganic phosphate and subsequent immunoprecipitation demonstrate that the PARP protein is phosphorylated in vivo. We show that maturation-promoting factor (Cyclin B/cdc2) cannot itself be responsible for the phosphorylation and activation of PARP in maturing X. laevis eggs. Together, these results demonstrate that the enzyme activity of PARP in X. laevis oocytes and eggs is regulated by post-translational, covalent phosphorylation.

Post-translational activation of non-homologous DNA end-joining in Xenopus oocyte extracts.

We have analysed the recircularisation of plasmid DNA, cut with two different endonucleases to generate non-homologous DNA ends, in extracts of unfertilised eggs and oocytes of Xenopus. We found that the capacity to join non-homologous DNA ends, generating diagnostic covalently closed monomer circles, appeared during oocyte maturation at the time of germinal vesicle breakdown. This enzyme function was post-translationally activated in oocyte extracts incubated with unfertilised egg extract containing active cdc2/cyclin B, or by incubation with purified cdc2/cyclin B. Dephosphorylation of egg proteins by alkaline phosphatase inhibited the ability to join non-homologous DNA ends. We show that most linear non-homologous DNA ends repaired to form closed-circular supercoiled monomers, are joined without loss of nucleotides. Following partial purification, the activity was inhibited by inhibitors of poly(ADP-Rib) polymerase, an enzyme that is inactive in oocytes, but phosphorylated and activated during maturation. Competitive inhibition of poly(ADP-Rib) polymerase by > 50 microM 3-aminobenzamide prevented the joining of both matched and non-homologous DNA ends. We conclude that post-translational phosphorylation provides one route by which end-joining of non-homologous DNA can be regulated.

XRCC1 polypeptide interacts with DNA polymerase beta and possibly poly (ADP-ribose) polymerase, and DNA ligase III is a novel molecular 'nick-sensor' in vitro.

The DNA repair proteins XRCC1 and DNA ligase III are physically associated in human cells and directly interact in vitro and in vivo. Here, we demonstrate that XRCC1 is additionally associated with DNA polymerase-beta in human cells and that these polypeptides also directly interact. We also present data suggesting that poly (ADP-ribose) polymerase can interact with XRCC1. Finally, we demonstrate that DNA ligase III shares with poly (ADP-ribose) polymerase the novel function of a molecular DNA nick-sensor, and that the DNA ligase can inhibit activity of the latter polypeptide in vitro. Taken together, these data suggest that the activity of the four polypeptides described above may be co-ordinated in human cells within a single multiprotein complex.

The cloning and characterization of a cDNA encoding Xenopus laevis DNA ligase I.

A cDNA clone coding for DNA ligase I (LigI) was isolated from a Xenopus laevis oocyte cDNA library. The 3766-bp sequence showed a putative ORF capable of encoding a 1070-amino-acid protein whose overall identity with two mammalian sequences is 63%. This identity, however, rises to 72.5% in the C-terminal portion of the protein that contains the active site. Expression of the cDNA in a prokaryotic system produces a protein that is immunologically identical to LigI and can be adenylated. The 180-kDa size of the recombinant protein is similar to the LigI detected in oocyte. Northern blot analysis of ovary and embryo RNAs revealed the expression of two (4.1 and 6 kb) LigI transcripts.

Nonsense mutations inhibit RNA splicing in a cell-free system: recognition of mutant codon is independent of protein synthesis.

Mutations resulting in premature termination codons reduce the corresponding mRNA levels. We describe a cell-free system in which depletion of the mutant immunoglobulin kappa mRNA pool correlates with inefficient splicing and not with RNA decay. Splicing deficiency does not depend on the sequence surrounding the in-frame nonsense codon and can be partially corrected by mutating the methionine initiation codon. Despite the apparent link between translation and low mutant mRNA levels, inefficient splicing is not dependent on protein synthesis. Abnormal splicing of mutant immunoglobulin RNA is observed with B-cell but not with HeLa or T-cell extracts. A nonsense mutant beta-globin RNA is normally spliced by B-cell extract. We propose that the phenomenon exhibits tissue and gene specificity.

Cyclin B/p34cdc2 triggers phosphorylation of DNA ligase I during Xenopus laevis oocyte maturation.

Phosphorylation of DNA ligase I has been analyzed during Xenopus laevis early development. The enzyme, which is involved in DNA replication and DNA repair events, is accumulated during oogenesis to reach a maximum in the stage VI oocyte, and remains at a constant level during maturation. When maturation of the oocyte is induced (in vivo or in vitro), this leads to a post-translational modification of the protein. In stage VI oocytes, a DNA ligase I of apparent molecular mass 180 kDa is detected immunologically whereas a 190-kDa form is found in unfertilized eggs and persists until the tadpole stage. This modification is due to phosphorylation performed by a protein kinase that is turned on 3-4 h after induction of the maturation. Activation of the kinase requires protein synthesis, and appearance of phosphorylated DNA ligase coincides with activation of histone H1 kinase activity. Induction of DNA ligase I modification and maturation are induced in the absence of protein synthesis following injection of maturation promoting factor into oocytes. Immunoprecipitated oocyte DNA ligase I is phosphorylated and its molecular mass modified by purified cyclin B/p34cdc2 in vitro. DNA ligase I phosphorylation is not induced in oocyte extract where only mitogen-activated-protein kinase is induced. Phosphorylation of DNA ligase I induced by cdc2 kinase occurs at the time new DNA replication and recombination activities appear in eggs.

Expression of DNA ligases I and II during oogenesis and early development of Xenopus laevis.

We have analyzed the expression of DNA ligase I protein during oogenesis and early development of Xenopus laevis. The protein is already present in stage I oocytes and then accumulates throughout oogenesis to reach a steady state level by stage VI. It remains at this level at least until tadpole stage. In stage VI oocytes DNA ligase I protein is almost exclusively localized in the germinal vesicle. We have partially purified a DNA ligase II activity from stage VI oocytes, unfertilized eggs, and stage 8 embryos. An 80-kDa polypeptide can be specifically adenylated in all three purified extracts. It is not recognized by antibodies directed against DNA ligase I and is active on oligo(dT)-poly(rA) substrate. It could therefore represent DNA ligase II protein. The presence of both DNA ligases I and II in oocytes and embryos is inconsistent with the DNA ligase model that had been previously proposed for amphibia.

Reinvestigation of DNA ligase I in axolotl and Pleurodeles development.

We have recently shown that the exclusion process causing the replacement of DNA ligases II by DNA ligase I in amphibian eggs after fertilization does not occur in the case of Xenopus laevis [Hardy, S., Aoufouchi, S., Thiebaud, P., and Prigent, C., (1991) Nucleic Acids Res. 19, 701-705]. Since this result is in contradiction with the situation reported in axolotl and Pleurodeles we decided to reinvestigate such results in both species. Three different approaches have been used: (1) the substrate specificity of DNA ligase I; (2) the DNA ligase-AMP adduct reaction and (3) the immunological detection using antibodies raised against the X.laevis DNA ligase I. Our results clearly demonstrate that DNA ligase I activity is associated with a single polypeptide which is present in oocyte, unfertilized egg and embryo of both amphibians. Therefore, the hypothesis of a change in DNA ligase forms, resulting from an expression of the DNA ligase I gene in axolotl and Pleurodeles early development must be rejected. We also show that, in contradiction with published data, the unfertilized sea urchin egg contains a DNA ligase activity able to join blunt ended DNA molecules.

DNA ligase I from Xenopus laevis eggs.

We have purified the major DNA ligase from Xenopus laevis eggs and raised antibodies against it. Estimates from SDS PAGE indicate that this DNA ligase is a 180 kDa protein. This enzyme is similar to the mammalian type I DNA ligase which is presumed to be involved in DNA replication. We have also analysed DNA ligase activity during X. laevis early development. Unfertilized eggs contain the highest level of activity reflecting the requirement for a large amount of DNA replicative enzymes for the period of intense replication following fertilization. In contrast with previous studies on the amphibians axolotl and Pleurodeles, the major DNA ligase activity detected during X. laevis early development is catalysed by a single enzyme: DNA ligase I. And the presence of this DNA ligase I in Xenopus egg before fertilization clearly demonstrates that the exclusion process of two forms of DNA ligase does not occur during X. laevis early development.

Identification of DNA ligase I related polypeptides in three different human cells.

Partial purification of the DNA ligase from three human tissues (liver, thymus and lymphoblasts) revealed that each cell type contains several different polypeptides bearing a DNA ligase I activity. Their apparent molecular weights estimated after SDS PAGE, 130 kDa, 100 kDa and 80 kDa, are in agreement with previous reports. These polypeptides are related by proteolysis to a single higher molecular weight protein of 200 kDa which does not show DNA ligase activity but that could be a preprotein.