The identification and purification of a novel mammalian DNA ligase.

Using a combination of biochemical fractionation and adenylation assays, we have purified a novel 44 kDa protein from human cells which rejoins DNA double-strand breaks. Its rejoining properties and its ability to form an adenylation product with ATP, which can be rapidly dissociated by the presence of DNA breaks, show that this protein is a DNA ligase. As four mammalian DNA ligases have been previously identified we have named this DNA ligase V. Silver staining of the most purified fraction on denaturing polyacrylamide gels reveals a protein doublet of 46/44 kDa of which only the lower band becomes adenylated. Assay of this protein, along with two defined DNA ligases, against DNA templates containing either double and single-strand breaks shows that unlike other DNA ligases, DNA ligase V does not join nicked templates with high efficiency. However, this DNA ligase can join double-strand breaks with a similar efficiency to DNA ligase 1. This result indicates that there may be different types of DNA ligases in mammalian cells which may have specific cellular functions.

The severity of alpha-particle-induced DNA damage is revealed by exposure to cell-free extracts.

The rejoining of single-strand breaks induced by alpha-particle and gamma irradiation in plasmid DNA under two scavenging conditions has been compared. At the two scavenger capacities used of 1.5 x 10(7) and 3 x 10(6) s-1 using Tris-HCl as the scavenger, the ratio of single- to double-strand breaks for alpha particles is fivefold less than the corresponding ratios for gamma irradiation. The repair of such radiation-induced single-strand breaks has been examined using a cell-free system derived from human whole-cell extracts. We show that the rejoining of single-strand breaks for both alpha-particle- and gamma-irradiated plasmid is dependent upon the scavenging capacity and that the efficiency of rejoining of alpha-particle-induced single-strand breaks is significantly less than that observed for gamma-ray-induced breaks. In addition, for DNA that had been irradiated under conditions that mimic the cellular environment with respect to the radical scavenging capacity, 50% of alpha-particle-induced single-strand breaks are converted to double-strand breaks, in contrast with only approximately 12% conversion of gamma-ray-induced single-strand breaks, indicating that the initial damage caused by alpha particles is more severe. These studies provide experimental evidence for increased clustering of damage which may have important implications for the induction of cancer by low-level alpha-particle sources such as domestic radon.

The joining of non-complementary DNA double-strand breaks by mammalian extracts.

We have developed a high efficiency system in which mammalian extracts join DNA double-strand breaks with non-complementary termini. This system has been used to obtain a large number of junction sequences from a range of different break-end combinations, allowing the elucidation of the joining mechanisms. Using an extract of calf thymus it was found that the major mechanism of joining was by blunt-end ligation following removal or fill-in of the single-stranded bases. However, some break-end combinations were joined through an efficient mechanism using short repeat sequences and we have succeeded in separating this mechanism from blunt-end joining by the biochemical fractionation of extracts. Characterization of activities and sequence data in an extensively purified fraction that will join ends by the repeat mechanism led to a model where joining is initiated by 3' strand invasion followed by pairing to short repeat sequences close to the break site. Thus the joining of double-strand breaks by mammalian extracts is achieved by several mechanisms and this system will allow the purification of the factors involved in each by the judicial choice of the non-complementary ends used in the assay.

The identification and characterization of mammalian proteins involved in the rejoining of DNA double-strand breaks in vitro.

Using a combination of specific assays and biochemical fractionation of mammalian extracts, we have identified multiple activities involved in the rejoining of DNA double-strand breaks. Fractionation of whole cell extracts from calf thymus has identified four biochemically distinct fractions capable of joining double-strand breaks, and an activity Rejoin Enhancement Protein (REP-1), that stimulates this process. We also show that REP-1 directly stimulates a DNA ligase and that this stimulation is associated with the increased turnover of the adenylated intermediate formed by all ATP-dependent DNA ligases. Activity relationships between the rejoining fractions and REP-1 indicates that the joining of double-strand breaks is carried out by protein complexes of which REP-1 is a component. In support of this, the cellular activities identified here that can efficiently rejoin double-strand breaks, do not show detectable adenylation products. Western analysis also shows that several proteins that have been suggested to be involved in the joining of double-strand breaks, such as the Ku heterodimer, are not present in all fractions that contain rejoining activity. These data strongly suggests that many different activities exist that can rejoin double-strand breaks and that this process is not dependent on the presence of proteins such as the end-binding protein Ku.

Rejoining of gamma-radiation-induced single-strand breaks in plasmid DNA by human cell extracts: dependence on the concentration of the hydroxyl radical scavenger, Tris.

The rejoining of single-strand breaks induced by gamma irradiation in plasmid DNA under different scavenging conditions is described using human cell extracts. As the scavenging capacity of the irradiated solution increases from 1.5 x 10(7) to 3 x 10(8) s-1 using Tris-HCl as a scavenger, the ratio of single- to double-strand breaks is reduced from approximately 70:1 to 40:1. After irradiation, a proportion of DNA molecules have no initial strand breaks but contain damage that is converted to strand breaks when incubated either at 37 degrees C or in the presence of cellular extract. Repair of damage by the extracts is dependent upon the scavenging capacity of the irradiated solution. Optimal rejoining is observed when the scavenging capacity is < 1.5 x 10(7) s-1, and results in the repair of some initial strand breaks. As the scavenging capacity increases to 3 x 10(8) s-1 the proportion of breaks repaired is significantly reduced. The relative increase in the yield of double-strand breaks and reduced repairability of single-strand breaks at a scavenging capacity of 3 x 10(8) s-1 is consistent with the concept that the severity of damage increases upon increasing the scavenger concentration.

Multiple components are involved in the efficient joining of double stranded DNA breaks in human cell extracts.

We describe a rapid and efficient in vitro system for the rejoining of double stranded breaks in DNA based on extracts of human 293 cells. Using this system as an assay, we have separated the nuclear extract into several components involved in break rejoining. The unfractionated system can convert approx. 100% of the input DNA, linearized with a restriction enzyme, to high molecular weight material at low temperature (17 degrees C), and at the physiological temperature of 37 degrees C we have shown that competing activities in the extract can also act on the DNA template. We present the fractionation of the extract and the partial purification of a novel factor which will stimulate a crude rejoin activity and in addition increases the activity of purified DNA ligase I. We have also partially purified the break joining activity and show that the chromatographic properties do not directly correspond with the three DNA ligases previously described, indicating that the activity observed may not be due to a single enzyme species. By studying the rejoining of double stranded DNA breaks as a biochemical process, we have demonstrated that the efficient joining of such breaks requires factors in addition to DNA ligases.

Patterns of DNA replication in Drosophila polytene nuclei replicating in Xenopus egg and oocyte extracts.

We have used Xenopus laevis cell-free extracts to study patterns of DNA replication in polytene nuclei isolated from salivary glands of Drosophila melanogaster 3rd instar larvae. Replication was visualized by supplementation with biotin-dUTP so that nascent DNA became labelled, thus allowing detection with fluorescein or Texas-Red-conjugated streptavidin. Biotin incorporation was dependent on incubation in extracts. Transverse bands were labelled in high-speed supernatants of eggs or oocytes in which replication does not initiate de novo. These patterns corresponded to the patterns of endogenous replication forks in polytene nuclei, monitored by bromodeoxyuridine incorporation in intact salivary glands. By contrast, when nuclei were incubated in low-speed supernatants of eggs, they underwent more extensive chromatin decondensation and initiated replication. The spatial patterns of replication are strikingly different from the endogenous patterns. Instead they closely resemble patterns of clustered replication forks seen in Xenopus sperm nuclei replicating in the extract. This indicates that the egg extract can impose its pattern of replication foci even when the template is presented in the highly organized form of a polytene nucleus.

Cell-cycle-regulated phosphorylation of DNA replication factor A from human and yeast cells.

Replication factor A (RF-A) is a multisubunit, cellular protein that functions with SV40 T antigen during the initiation stage of DNA replication at the SV40 origin. It also cooperates with other replication factors to stimulate the activity of both polymerases alpha and delta during chain elongation. RF-A from both human and yeast cells is phosphorylated in a cell-cycle-dependent manner; the protein is phosphorylated at the G1- to S-phase transition, and dephosphorylation occurs at mitosis, thereby resetting this cycle. This observation provides a direct link between a protein required for DNA replication and cell-cycle-regulated protein phosphorylation.

S phase of the cell cycle.

In each cell cycle the complex structure of the chromosome must be replicated accurately. In the last few years there have been major advances in understanding eukaryotic chromosome replication. Patterns of replication origins have been mapped accurately in yeast chromosomes. Cellular replication proteins have been identified by fractionating cell extracts that replicate viral DNA templates in vitro. Cell-free systems that initiate eukaryotic DNA replication in vitro have demonstrated the importance of complex nuclear architecture in the control of DNA replication. Although the events of S phase were relatively neglected for many years, knowledge of DNA replication is now advancing rapidly in step with other phases of the cell cycle.

Large T-antigen mutants define multiple steps in the initiation of simian virus 40 DNA replication.

The biochemical activities of a series of transformation-competent, replication-defective large T-antigen point mutants were examined. The assays employed reflect partial reactions required for the in vitro replication of simian virus 40 (SV40) DNA. Mutants which failed to bind specifically to SV40 origin sequences bound efficiently to single-stranded DNA and exhibited nearly wild-type levels of helicase activity. A mutation at proline 522, however, markedly reduced ATPase, helicase, and origin-specific unwinding activities. This mutant bound specifically to the SV40 origin of replication, but under certain conditions it was defective in binding to both single-stranded DNA and the partial duplex helicase substrate. This suggests that additional determinants outside the amino-terminal-specific DNA-binding domain may be involved in nonspecific binding of T antigen to single-stranded DNA and demonstrates that origin-specific DNA binding can be separated from binding to single-stranded DNA. A mutant containing a lesion at residue 224 retained nearly wild-type levels of helicase activity and recognized SV40 origin sequences, yet it failed to function in an origin-specific unwinding assay. This provides evidence that origin recognition and helicase activities are not sufficient for unwinding to occur. The distribution of mutant phenotypes reflects the complex nature of the initiation reaction and the multiplicity of functions provided by large T antigen.

Simian virus 40 DNA replication in vitro: identification of multiple stages of initiation.

A cell-free DNA replication system dependent upon five purified cellular proteins, one crude cellular fraction, and the simian virus 40 (SV40)-encoded large tumor antigen (T antigen) initiated and completed replication of plasmids containing the SV40 origin sequence. DNA synthesis initiated at or near the origin sequence after a time lag of approximately 10 min and then proceeded bidirectionally from the origin to yield covalently closed, monomer daughter molecules. The time lag could be completely eliminated by a preincubation of SV40 ori DNA in the presence of T antigen, a eucaryotic single-stranded DNA-binding protein (replication factor A [RF-A]), and topoisomerases I and II. In contrast, if T antigen and the template DNA were incubated alone, the time lag was only partially decreased. Kinetic analyses of origin recognition by T antigen, origin unwinding, and DNA synthesis suggest that the time lag in replication was due to the formation of a complex between T antigen and DNA called the T complex, followed by formation of a second complex called the unwound complex. Formation of the unwound complex required RF-A. When origin unwinding was coupled to DNA replication by the addition of a partially purified cellular fraction (IIA), DNA synthesis initiated at the ori sequence, but the template DNA was not completely replicated. Complete DNA replication in this system required the proliferating-cell nuclear antigen and another cellular replication factor, RF-C, during the elongation stage. In a less fractionated system, another cellular fraction, SSI, was previously shown to be necessary for reconstitution of DNA replication. The SSI fraction was required in the less purified system to antagonize the inhibitory action of another cellular protein(s). This inhibitor specifically blocked the earliest stage of DNA replication, but not the later stages. The implications of these results for the mechanisms of initiation and elongation of DNA replication are discussed.

Production of simian virus 40 large tumor antigen in bacteria: altered DNA-binding specificity and dna-replication activity of underphosphorylated large tumor antigen.

A bacterial expression system was used to produce simian virus 40 large tumor antigen (T antigen) in the absence of the extensive posttranslational modifications that occur in mammalian cells. Wild-type T antigen produced in bacteria retained a specific subset of the biochemical activities displayed by its mammalian counterpart. Escherichia coli T antigen functioned as a helicase and bound to DNA fragments containing either site I or the wild-type origin of replication in a manner identical to mammalian T antigen. However, T antigen purified from E. coli did not efficiently bind to site II, an essential cis element within the simian virus 40 origin of replication. It therefore could not unwind origin-containing plasmids or efficiently replicate simian virus 40 DNA in vitro. The ability of protein phosphorylation to modulate the intrinsic preference of full-length T antigen for either site I or site II is discussed.

Replication of SV40 in vitro using proteins derived from a human cell extract.

In the presence of large T antigen and plasmids containing a functional origin of replication, extracts from a human cell line will support multiple rounds of simian virus 40 (SV40) replication in vitro. Fractionation of this extract has led to the identification of several factors, some of which have been purified to homogeneity. The characterisation of these proteins has led to the separation of SV40 replication in vitro into multiple stages. Two proteins, the cell cycle-regulated proliferating cell nuclear antigen and replication factor-C, have been shown to be essential for coordinating leading and lagging strand synthesis in this system. Another protein, replication factor-A, is a multi-subunit protein of 70, 34 and 11K (K = 10(3) Mr) polypeptides which, because of its high affinity for DNA, is thought to function as a eukaryotic single-stranded DNA binding protein. Interactions between other cellular factors are also described that effect the initiation of DNA replication, but are not required in a more purified system. In addition a model for a hypothetical replication fork is described, which suggests a role for both alpha- and delta-polymerases in this system, and may be applicable to higher eukaryotes.

Cellular factors required for multiple stages of SV40 DNA replication in vitro.

Plasmids containing the SV40 origin replicate in the presence of SV40 T antigen and a cell free extract derived from human 293 cells. Upon fractionation of this extract, two essential replication factors have been identified. One of these is a multi-subunit DNA binding protein containing polypeptides of 70,000, 34,000 and 11,000 daltons which may function as a eukaryotic single strand DNA binding protein (SSB). The other partially purified fraction is required with T antigen for the first stage of DNA replication, the formation of a pre-synthesis complex at the replication origin. These results, and others, define multiple stages of SV40 DNA replication in vitro which are analogous to multiple stages of Escherichia coli and phage lambda replication, and may reflect similar events in the replication of cellular chromosomes.

Identification of multiple cellular factors required for SV40 replication in vitro.

The replication of simian virus 40 has been studied by using cell-free extracts derived from human 293 cells. Fractionation of this extract has led to the identification of three fractions that are required for efficient DNA synthesis. Initial fractionation of the crude extract by phosphocellulose chromatography has produced two fractions, I and II, neither of which is able to support replication separately, but when they are combined, efficient synthesis is restored. Both fractions are required, with SV40 T antigen, for the formation of a presynthesis complex at the SV40 origin. The major replication enzymes, DNA polymerase, DNA primase and the topoisomerases I and II all reside in fraction II. Fraction I has been subdivided into two subfractions (A and B) by DEAE-cellulose chromatography. Fraction A is essential for replication and is required for presynthesis complex formation. Fraction B stimulates DNA replication and is only required at the elongation stage. This multicomponent system has provided the foundation for identification of individual components that are required for DNA replication in vitro.