Increased activity of polynucleotide ligase in 5-iodo-2'-deoxyuridine and mitomycin C-pretreated simian virus 40 (SV40)-infected monkey kidney cells

Induction and utilization of an ATM signaling pathway by polyomavirus

Progression from G(1) to S is essential for polyomavirus DNA replication and depends on the interaction of large T with the retinoblastoma gene product pRb. This virus-induced replication pathway is accompanied by p53 activation resembling a DNA damage response (12). We sought to determine whether this pathway depends in part on activation of the ATM (ataxia telangiectasia mutated) kinase and whether the virus gains advantages from this pathway beyond that of entry into S. We show that polyomavirus infection activates the S- and G(2)-phase checkpoints in primary as well as established mouse cells. Infected cells undergo a prolonged S phase compared to uninfected serum-stimulated cells and show no evidence of a G(2)-->M transition before lytic death ensues. Infection is accompanied by increases in ATM activity in vitro and in the level of ATM-S1981-P in vivo. The incubation of infected cells with caffeine, a known ATM inhibitor, did not block entry into S but reduced the rate of viral compared to cellular DNA synthesis. Importantly, caffeine lowered the yields of viral DNA an average of 3- to 6-fold and those of infectious virus by as much as 10-fold. Virus yields were 10-fold lower in ATM (-/-) p53(-/-) than in ATM(+/+) p53(-/-) mouse embryo fibroblasts, indicating a p53-independent role of ATM in productive infection. Replacement of the normal SMC1 (structural maintenance of chromosomes, or cohesin) protein, a critical ATM substrate in the DNA repair pathway, with its phosphorylation mutant SMC1(S957AS966A) also lowered virus yields by roughly 90%. We suggest that polyomavirus activates and utilizes a component(s) of an ATM pathway of DNA repair to prolong S phase and aid its own replication.

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.

Changes in the catalytic properties of DNA ligases during early sea urchin development

Two distinct DNA ligases are expressed during early sea urchin embryogenesis. A light form (50 kDa) is found in unfertilized eggs (oocyte form) and a heavier enzyme (110 kDa) is observed at the two-cell stage (embryonic form). The chronology of the change reveals that the embryonic form is detected 90 min after fertilization. After the two proteins were purified, their catalytic properties were studied using different substrates. The oocyte ligase acts only on deoxypolymers while the embryonic form also ligates heteropolymers. The two enzymes were found to undergo both nick and cohesive-end ligation. With different kinds of restriction sites it was observed that the embryonic enzyme could also ligate blunt-ended DNA. These catalytic properties account for sealing of exogenous DNA and concatenation following DNA injection into eggs. The role of the oocyte form of the enzyme is unclear; one speculation is a role in repair of DNA breaks which might accumulate during long-term sperm and oocyte storage in the gonad.

Mammalian DNA ligase. Structure and function in rat-liver tissues

DNA ligase was partially purified from normal and regenerating rat liver. Its structure was studied using the activity gel procedure that identifies the functional polypeptides. Two slightly different purification procedures were followed leading to the isolation of one or two peaks (fractions A and B) of DNA ligase by hydroxyapatite chromatography. When analyzed on activity gels, all these enzyme fractions corresponded to a single active 130-kDa polypeptide both in normal and regenerating liver. A limited trypsin digestion of ligase fractions A and B gave rise to an identical pattern of smaller polypeptides of 110 kDa, 100 kDa and 75 kDa. Also storage at 4 degrees C of fractions A and B produced smaller polypeptides of 110 kDa, 100 kDa, 85 kDa and 60 kDa, which were identical for the two fractions. Our results indicate that the same ligase polypeptide of 130 kDa can be isolated from stationary or regenerating rat liver cells. However, physiological or artifactual proteolysis during various purification procedures can lead to the isolation of two enzyme fractions with different chromatographic behaviour but with the same molecular mass.

Immunochemical analysis of molecular forms of mammalian DNA ligases I and II

Using specific antibodies against calf thymus DNA ligases I and II (EC 6.5.1.1), we have investigated the polypeptide structures of DNA ligases I and II present in the impure enzyme preparations, and estimated the polypeptides of DNA ligases I and II present in vivo. Immunoblot analysis of DNA ligase I after sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a 130-kDa polypeptide as a major one in the enzyme preparations from calf thymus throughout the purification. In addition to the 130-kDa polypeptide, a 200-kDa polypeptide was detected in the enzyme preparations at the earlier steps of the purification, and a 90-kDa polypeptide was observed as a minor one in the enzyme preparations at the later steps of the purification. The polypeptides with molecular weight of 130 000 and 90 000 were detected by SDS-polyacrylamide gel electrophoresis of DNA ligase I-[3H]AMP complex. These results suggest that a 200-kDa polypeptide of DNA ligase I present in vivo is degraded to a 130-kDa polypeptide and then to a 90-kDa polypeptide during the isolation and purification procedures. On the other hand, the monospecific antibody against calf thymus DNA ligase II cross-reacted with only a 68 kDa polypeptide in the enzyme preparations throughout the purification, suggesting that the 68-kDa polypeptide is a single form of calf thymus DNA ligase II present in vivo as well as in vitro.

Variation in DNA ligase structure during repair and replication processes in monkey kidney cells

Using a method that detects catalytically active DNA ligase in NaDodSO4-polyacrylamide gels (activity gels) we have characterized ligase produced in CV1-P monkey kidney cells infected with SV40 or treated with mitomycin C. Purification on hydroxylapatite columns of DNA ligase from control cells results in two peaks of activity called ligases I and II, respectively. Analysis of ligase I on activity gels revealed major catalytic peptides with Mr of 120, 110, 70 and 58 kDa, while analysis of ligase II revealed two major peptides of 65 and 58 kDa. Infecting CV1-P cells with SV40 produced a significant increase in the 120, 110, 70 and 58 kDa peptides while treating them with mitomycin C produced a significant increase in the 70 and 58 kDa peptides and a decrease in the 120 and 110 kDa ones. Autoproteolysis of partially purified ligase under several conditions resulted in an increase in the 58 kDa peptide and in the disappearance of other peptides. These results suggest that at least one active polypeptide is common to ligases I and II.

DNA ligases as markers of lymphoid cell maturation and heterogeneity in the chicken

The activities of 8 S and 6 S DNA ligases have been studied in the chicken lymphoid cells of blood, spleen and bursa of Fabricius at different stages of development, from late embryonic life to about 3 months after hatching. These cells have been sorted with the fluorescence-activated cell sorter FACS II on the basis of size and T or B antigenicity (immunofluorescence). The light 6 S DNA ligase has been previously demonstrated to be associated to a late stage of differentiation of thymocytes. In the bursa, a unique form of 8 S DNA ligase is found during the whole period of observation. This form of enzyme remains in the B cells of the spleen until 3 weeks after hatching, but is never present in the blood B cells. As far as T cells are concerned, the light DNA ligase is present in the blood from 18-day embryonic life on. In the spleen T cells, on the contrary, this enzyme appears only 3 weeks after hatching. Before this stage, splenic T cells are devoid of any form of DNA ligase activity. These findings show biochemical differences in T and B lymphocytes colonizing the periphery, blood and spleen, and suggest, at least for the T cells at early stages, a heterogeneity in the degree of differentiation.

Heterogeneity of mammalian DNA ligase detected on activity and DNA sequencing gels

A new method to detect DNA ligase activity in situ after NaDodSO4 polyacrylamide gel electrophoresis has been developed. After renaturation of active polypeptides the ligase reaction occurs in situ by incubating the intact gel in the presence of Mg++ and ATP. Further treatment with alkaline phosphatase removes the unligated 5'-32P-end of oligo (dT) used as a substrate and active polypeptides having ligase activity are identified by autoradiography. Analysis on DNA sequencing gels of the oligo (dT) reaction products present in the activity bands ensures that the radioactive material detected in activity gels or in standard in vitro ligase assays corresponds unambiguously to a ligase activity. Using these methods, we have analysed the purified phage T4 DNA ligase, and the activities present in crude extracts and in purified fractions from monkey kidney (CV1-P) cells. The purified T4 enzyme yields one or two active peptides with Mr values of 60,000 and 70,000. Crude extracts from CV1-P cells contain several polypeptides having DNA ligase activity. Partial purification of these extracts shows that DNA ligase I isolated from hydroxylapatite column is enriched in polypeptides with Mr 200,000, 150,000 and 120,000, while DNA ligase II is enriched in those with Mr 60,000 and 70,000.