DNA Polymerase Alpha-primase Complex Research Articles

The intrinsically disordered N-terminal region of mouse DNA polymerase alpha mediates its interaction with POT1a/b at telomeres.

Mouse telomerase and the DNA polymerase alpha-primase complex elongate the leading and lagging strands of telomeres, respectively. To elucidate the molecular mechanism of lagging strand synthesis, we investigated the interaction between DNA polymerase alpha and two paralogs of the mouse POT1 telomere-binding protein (POT1a and POT1b). Yeast two-hybrid analysis and a glutathione S-transferase pull-down assay indicated that the C-terminal region of POT1a/b binds to the intrinsically disordered N-terminal region of p180, the catalytic subunit of mouse DNA polymerase alpha. Subcellular distribution analyses showed that although POT1a, POT1b, and TPP1 were localized to the cytoplasm, POT1a-TPP1 and POT1b-TPP1 coexpressed with TIN2 localized to the nucleus in a TIN2 dose-dependent manner. Coimmunoprecipitation and cell cycle synchronization experiments indicated that POT1b-TPP1-TIN2 was more strongly associated with p180 than POT1a-TPP1-TIN2, and this complex accumulated during the S phase. Fluorescence in situ hybridization and proximity ligation assays showed that POT1a and POT1b interacted with p180 and TIN2 on telomeric chromatin. Based on the present study and a previous study, we propose a model in which POT1a/b-TPP1-TIN2 translocates into the nucleus in a TIN2 dose-dependent manner to target the telomere, where POT1a/b interacts with DNA polymerase alpha for recruitment at the telomere for lagging strand synthesis.

Subunits of the DNA polymerase alpha‐primase complex promote Notch‐mediated proliferation with discrete and shared functions in C. elegans germline

Notch receptor signaling is a highly conserved cell communication system in most multicellular organisms and plays a critical role at several junctures in animal development. In Caenorhabditis elegans,GLP-1/Notch signaling is essential for both germline stem cell maintenance and germ cell proliferation during gonad development. Here, we show that subunits (POLA-1, DIV-1, PRI-1, and PRI-2) of the DNA polymerase alpha-primase complex are required for germ cell proliferation in response to GLP-1/Notch signaling in different tissues at different developmental stages. Specifically, genetic and functional analyses demonstrated that (a) maternally contributed DIV-1 (regulatory subunit) is indispensable non-cell autonomously for GLP-1/Notch-mediated germ cell proliferation during early larval development, whereas POLA-1 (catalytic subunit) and two primase subunits, PRI-1 and PRI-2, do not appear to be essential; (b) germline POLA-1, PRI-1, and PRI-2 play a crucial role in GLP-1/Notch-mediated maintenance of proliferative cell fate during adulthood, while DIV-1 is dispensable; and (c) germline POLA-1, DIV-1, PRI-1, and PRI-2 function in tandem with PUF (Pumilio/FBF) RNA-binding proteins to maintain germline stem cells in the adult gonad. These findings suggest that the subunits of the DNA polymerase alpha-primase complex exhibit both discrete and shared functions in GLP-1/Notch or PUF-mediated germ cell dynamics in C. elegans. These findings link the biological functions of DNA replication machineries to signals that maintain a stem cell population, and may have further implications for Notch-dependent tumors.

The B-subunit of DNA polymerase alpha-primase associates with the origin recognition complex for initiation of DNA replication.

The B-subunit (p70/Pol12p) of the DNA polymerase alpha-primase (Polalpha-primase) complex is thought to have a regulatory role in an early stage of S phase. We generated a panel of fission yeast thermosensitive mutants of the B-subunit (termed Spb70) to investigate its role in initiation of DNA replication by genetic and biochemical approaches. Here, we show that the fission yeast Spb70 genetically interacts and coprecipitates with origin recognition complex proteins Orp1/Orc1 and Orp2/Orc2 and primase coupling subunit Spp2/p58. A fraction of Spb70 associates with Orp2 on chromatin throughout the cell cycle independent of the other subunits of Polalpha-primase. Furthermore, primase Spp2/p58 subunit preferentially associates with the unphosphorylated Orp2, and the association requires Spb70. Mutations in orp2+ that abolish or mimic the Cdc2 phosphorylation of Orp2 suppress or exacerbate the thermosensitivity of the spb70 mutants, respectively, indicating that an unphosphorylated Orp2 promotes an Spb70-dependent replication event. Together, these results indicate that the chromatin-bound B-subunit in association with origin recognition complex mediates recruiting Polalpha-primase complex onto replication origins in G1 pre-Start through an interaction with primase Spp2/p58 subunit. Our results thus suggest a role for the recruited Polalpha-primase in the initiation of both leading and lagging strands at the replication origins.

Primer Utilization by DNA Polymerase α-Primase Is Influenced by Its Interaction with Mcm10p

Models of DNA replication in yeast and Xenopus suggest that Mcm10p is required to generate the pre-initiation complex as well as progression of the replication fork during the elongation of DNA chains. In this report, we show that the Schizosaccharomyces pombe Mcm10p/Cdc23p binds to the S. pombe DNA polymerase (pol) alpha-primase complex in vitro by interacting specifically with the catalytic p180 subunit and stimulates DNA synthesis catalyzed by the pol alpha-primase complex with various primed DNA templates. We investigated the mechanism by which Mcm10p activates the polymerase activity of the pol alpha-primase complex by generating truncated derivatives of the full-length 593-amino acid Mcm10p. Their ability to stimulate pol alpha polymerase activity and bind to single-stranded DNA and to pol alpha were compared. Concomitant with increased deletion of the N-terminal region (from amino acids 95 to 415), Mcm10p derivatives lost their ability to stimulate pol alpha polymerase activity and bind to single-stranded DNA. Truncated derivatives of Mcm10p containing amino acids 1-416 retained the pol alpha binding activity, whereas the C terminus, amino acids 496-593, did not. These results demonstrate that both the single-stranded DNA binding and the pol alpha binding properties of Mcm10p play important roles in the activation. In accord with these findings, Mcm10p facilitated the binding of pol alpha-primase complex to primed DNA and formed a stable complex with pol alpha-primase on primed templates. A mutant that failed to activate or bind to DNA and pol alpha, was not observed in this complex. We suggest that the interaction of Mcm10p with the pol alpha-primase complex, its binding to single-stranded DNA, and its activation of the polymerase complex together contribute to its role in the elongation phase of DNA replication.

Dissociation of DNA polymerase alpha-primase complex during meiosis in Coprinus cinereus.

Previously, the activity of DNA polymerase alpha was found in the meiotic prophase I including non-S phase stages, in the basidiomycetes, Coprinus cinereus. To study DNA polymerase alpha during meiosis, we cloned cDNAs for the C. cinereus DNA polymerase alpha catalytic subunit (p140) and C. cinereus primase small subunit (p48). Northern analysis indicated that both p140 and p48 are expressed not only at S phase but also during the leptotene/zygotene stages of meiotic prophase I. In situ immuno-staining of cells at meiotic prophase I revealed a sub population of p48 that does not colocalize with p140 in nuclei. We also purified the pol alpha-primase complex from meiotic cells by column chromatography and characterized its biochemical properties. We found a subpopulation of primase that was separated from the pol alpha-primase complex by phosphocellulose column chromatography. Glycerol gradient density sedimentation results indicated that the amount of intact pol alpha-primase complex in crude extract is reduced, and that a smaller complex appears upon meiotic development. These results suggest that the form of the DNA polymerase alpha-primase complex is altered during meiotic development.

Initiation of JC virus DNA replication in vitro by human and mouse DNA polymerase alpha-primase.

Host species specificity of the polyomaviruses simian virus 40 (SV40) and mouse polyomavirus (PyV) has been shown to be determined by the host DNA polymerase alpha-primase complex involved in the initiation of both viral and host DNA replication. Here we demonstrate that DNA replication of the related human pathogenic polyomavirus JC virus (JCV) can be supported in vitro by DNA polymerase alpha-primase of either human or murine origin indicating that the mechanism of its strict species specificity differs from that of SV40 and PyV. Our results indicate that this may be due to differences in the interaction of JCV and SV40 large T antigens with the DNA replication initiation complex.

The DNA polymerase alpha-primase complex: multiple functions and interactions.

DNA polymerase _ (pol _) holds a special position among the growing family of eukaryotic DNA polymerases. In fact, pol _ is associated with DNA primase to form a four subunit complex and, as a consequence, is the only enzyme able to start DNA synthesis de novo. Because of this peculiarity the major role of the DNA polymerase _-primase complex (pol-prim) is in the initiation of DNA replication at chromosomal origins and in the discontinuous synthesis of Okazaki fragments on the lagging strand of the replication fork. However, pol-prim seems to play additional roles in other complex cellular processes, such as the response to DNA damage, telomere maintenance, and the epigenetic control of higher order chromatin assembly.

The Archaeal DNA Primase: BIOCHEMICAL CHARACTERIZATION OF THE p41-p46 COMPLEX FROMPYROCOCCUS FURIOSUS

We characterized the primase complex of the hyperthermophilic archaeon, Pyrococcus furiosus. The two proteins, Pfup41 and Pfup46, have similar sequences to the p48 and p58 subunits, respectively, of the eukaryotic DNA polymerase alpha-primase complex. Unlike previously reported primases, the Pfup41 preferentially utilizes deoxyribonucleotides for its de novo synthesis, and moreover, it synthesizes up to several kilobases in length in a template-dependent manner (Bocquier, A., Liu, L., Cann, I., Komori, K., Kohda, D., and Ishino, Y. (2001) Curr. Biol. 11, 452-456). The p41-p46 complex showed higher DNA binding activity than the catalytic p41 subunit alone. In addition, the amount of DNA synthesized by the p41-p46 complex was much more abundant and shorter in length than that by Pfup41 alone. The activity for RNA primer synthesis, which was not detected with Pfup41, was observed from the reaction using the p41-p46 complex in vitro. The in vitro replication of M13 single-stranded DNA by the P. furiosus proteins was stimulated by ATP. Observation of the labeled primers by using [gamma-(32)P]ATP in the substrates suggests ATP as the preferable initiating nucleotide for the p41-p46 complex. These results show that the primer synthesis activity of Pfup41 is regulated by Pfup46, and the p41-p46 complex may function as the primase in the DNA replication machinery of P. furiosus, in a similar fashion to the eukaryotic polymerase alpha-primase complex.

A mutation in subunit B of the DNA polymerase alpha-primase complex from Novikoff hepatoma cells concomitant with a conformational change and abnormal catalytic properties of the DNA polymerase alpha-primase complex.

Mutated constituents of the DNA replication complex might contribute to the mutational load of the genome during tumor development by impairing DNA synthesis as well as cell cycle-related control of DNA replication. To prove or disprove this hypothesis, we looked for mutations in the cDNA sequences of the four subunits of DNA polymerase alpha-primase from both highly malignant Novikoff hepatoma cells and regenerating normal rat liver and compared physicochemical and catalytic properties of the DNA polymerase alpha-primase complexes purified from both sources. Sequence analysis showed two mutations in subunit B from Novikoff cells: one in nucleotide position 855 (CCG-->CCA) that did not result in an amino acid exchange and one in position 862 (GTG-->ATG) that caused a change of valine to methionine in codon 288. No mutation was found in the three other subunits. The wild-type and mutated sequences of subunit B were cloned and expressed in vitro. Sedimentation analysis of the expressed polypeptides revealed different sedimentation constants, indicating that the amino acid exchange affected the conformation of subunit B. The analysis of the purified DNA polymerase alpha-primase complexes showed a sedimentation value that was significantly higher for the enzyme complex from normal liver than for that from Novikoff cells. In addition, DNA polymerase alpha-primase complexes from Novikoff cells showed higher sensitivity to camptothecin, topotecan, and structurally related compounds (such as (R,S)-7-ethyl-10-hydroxy camptothecin, 9-aminocamptothecin, and 10-hydroxycamptothecin) than the enzyme from normal rat liver. Thus, the amino acid change found in subunit B appears to result in a conformational change of the DNA polymerase alpha-primase complex from Novikoff hepatoma cells. Whether this mutation influences genetic instability or tumor development needs to be explored.

Archaeal primase: bridging the gap between RNA and DNA polymerases.

In the evolution of life, DNA replication is a fundamental process, by which species transfer their genetic information to their offspring. DNA polymerases, including bacterial and eukaryotic replicases, are incapable of de novo DNA synthesis. DNA primases are required for this function, which is sine qua non to DNA replication. In Escherichia coli, the DNA primase (DnaG) exists as a monomer and synthesizes a short RNA primer. In Eukarya, however, the primase activity resides within the DNA polymerase alpha-primase complex (Pol alpha-pri) on the p48 subunit, which synthesizes the short RNA segment of a hybrid RNA-DNA primer. To date, very little information is available regarding the priming of DNA replication in organisms in Archaea. Available sequenced genomes indicate that the archaeal DNA primase is a homolog of the eukaryotic p48 subunit. Here, we report investigations of a p48-like DNA primase from Pyrococcus furiosus, a hyperthermophilic euryarchaeote. P. furiosus p48-like protein (Pfup41), unlike hitherto-reported primases, does not catalyze by itself the synthesis of short RNA primers but preferentially utilizes deoxynucleotides to synthesize DNA fragments up to several kilobases in length. Pfup41 is the first DNA polymerase that does not require primers for the synthesis of long DNA strands.

Cloning and characterization of the 5'-upstream sequence governing the cell cycle-dependent transcription of mouse DNA polymerase alpha 68 kDa subunit gene.

We have isolated the genomic DNA fragment spanning the 5-end and the first four exons encoding the 68 kDa subunit (p68) of the mouse DNA polymerase alpha-primase complex [corrected]. The p68 promoter region lacks TATA and CAAT boxes, but contains a GC-rich sequence, two palindrome sequences and two putative E2F-binding sites [corrected]. A series of transient expression assays using a luciferase reporter gene indicated that a region from nucleotide position -89 to -30 (-89/-30) with respect to the transcription initiation site is crucial for basal transcription of the p68 gene in proliferating NIH 3T3 cells. In particular, part of the GC-rich sequence (-57/-46) and the palindrome (-81/-62) elements were necessary for promoter activity, both of which share homology with the E-box sequence. Gel mobility shift assays using NIH 3T3 nuclear extracts revealed that the upstream stimulatory factor, known as an E-box-binding protein, binds to these sites. Moreover, we observed binding of E2F to two sites near the transcription initiation site (-11/-3 and +9/+16). A transient luciferase expression assay using synchronized NIH 3T3 cells in G(0)phase revealed that these E2F sites are essential for transcription induction of the p68 gene after serum stimulation, but are dispensable for basal transcription. These results indicate that growth-dependent regulation of transcription of the mouse p68 and p180 genes is mediated by a common factor, E2F; however, basal transcription of the genes, interestingly, is regulated by different transcription factors.

Surface plasmon resonance measurements reveal stable complex formation between p53 and DNA polymerase alpha.

Surface plasmon resonance measurements were used for detecting and quantifying protein-protein interactions between the tumor suppressor protein p53, the SV40 large T antigen (T-ag), the cellular DNA polymerase alpha-primase complex (pol-prim), and the cellular single-strand DNA binding protein RPA. Highly purified p53 protein bound to immobilized T-ag with an apparent binding constant of 2 x 10(8) M(-1). Binding of p53 to RPA was in the same order of magnitude with a binding constant of 4 x 10(8) M(-1), when RPA was coupled to the sensor chip via its smallest subunit, and 1 x 10(8) M(-1), when RPA was coupled via its p70 subunit. Furthermore, p53 bound human DNA polymerase alpha-primase complex (pol-prim) with a K(A) value of 1 x 10(10) m(-1). Both the p68 subunit and the p180 subunit of pol-prim could interact with p53 displaying binding constants of 2 x 10(10) m1(-1) and 5 X 10(9) M(-1), respectively. Complex formation was also observed with a p180/p68 heterodimer, and again with a binding constant similar. Hence, there was no synergistic effect when p53 bound to higher order complexes of pol-prim. A truncated form of p53, consisting of amino acids 1-320, bound pol-prim by four orders of magnitude less efficiently. Therefore, an intact C-terminus of p53 seems to be important for efficient binding to pol-prim. It was also tried to measure complex formation between p53, pol-prim, and T-ag. However there was no evidence for the existence of a ternary complex consisting of T-ag, pol-prim, and p53.

Functional association of poly(ADP-ribose) polymerase with DNA polymerase alpha-primase complex: a link between DNA strand break detection and DNA replication.

Poly(ADP-ribose) polymerase (PARP) is an element of the DNA damage surveillance network evolved by eukaryotic cells to cope with numerous environmental and endogenous genotoxic agents. PARP has been found to be involved in vivo in both cell proliferation and base excision repair of DNA. In this study the interaction between PARP and the DNA polymerase alpha-primase tetramer has been examined. We provide evidence that in proliferating cells: (i) PARP is physically associated with the catalytic subunit of the DNA polymerase alpha-primase tetramer, an association confirmed by confocal microscopy, demonstrating that both enzymes are co-localized at the nuclear periphery of HeLa cells; (ii) this interaction requires the integrity of the second zinc finger of PARP and is maximal during the S and G2/M phases of the cell cycle; (iii) PARP-deficient cells derived from PARP knock-out mice exhibited reduced DNA polymerase activity, compared with the parental cells, a reduction accentuated following exposure to sublethal doses of methylmethanesulfonate. Altogether, the present results strongly suggest that PARP participates in a DNA damage survey mechanism implying its nick-sensor function as part of the control of replication fork progression when breaks are present in the template.

A meiosis-specific protein kinase, Ime2, is required for the correct timing of DNA replication and for spore formation in yeast meiosis.

In this report we study the regulation of premeiotic DNA synthesis in Saccharomyces cerevisiae. DNA replication was monitored by fluorescence-activated cell sorting analysis and by analyzing the pattern of expression of the DNA polymerase alpha-primase complex. Wild-type cells and cells lacking one of the two principal regulators of meiosis, Ime1 and Ime2, were compared. We show that premeiotic DNA synthesis does not occur in ime1 delta diploids, but does occur in ime2 delta diploids with an 8-9 h delay. At late meiotic times, ime2 delta diploids exhibit an additional round of DNA synthesis. Furthermore, we show that in wild-type cells the B-subunit of DNA polymerase alpha is phosphorylated during premeiotic DNA synthesis, a phenomenon that has previously been reported for the mitotic cell cycle. Moreover, the catalytic subunit and the B-subunit of DNA polymerase alpha are specifically degraded during spore formation. Phosphorylation of the B-subunit does not occur in ime1 delta diploids, but does occur in ime2 delta diploids with an 8-9 h delay. In addition, we show that Ime2 is not absolutely required for commitment to meiotic recombination, spindle formation and nuclear division, although it is required for spore formation.

Yeast pip3/mec3 Mutants Fail To Delay Entry into S Phase and To Slow DNA Replication in Response to DNA Damage, and They Define a Functional Link between Mec3 and DNA Primase

The catalytic DNA primase subunit of the DNA polymerase alpha-primase complex is encoded by the essential PRI1 gene in Saccharomyces cerevisiae. To identify factors that functionally interact with yeast DNA primase in living cells, we developed a genetic screen for mutants that are lethal at the permissive temperature in a cold-sensitive pril-2 genetic background. Twenty-four recessive mutations belonging to seven complementation groups were identified. Some mutants showed additional phenotypes, such as increased sensitivity to UV irradiation, methyl methanesulfonate, and hydroxyurea, that were suggestive of defects in DNA repair and/or checkpoint mechanisms. We have cloned and characterized the gene of one complementation group, PIP3, whose product is necessary both for delaying entry into S phase or mitosis when cells are UV irradiated in G1 or G2 phase and for lowering the rate of ongoing DNA synthesis in the presence of methyl methanesulfonate. PIP3 turned out to be the MEC3 gene, previously identified as a component of the G2 DNA damage checkpoint. The finding that Mec3 is also required for the G1- and S-phase DNA damage checkpoints, together with the analysis of genetic interactions between a mec3 null allele and several conditional DNA replication mutations at the permissive temperature, suggests that Mec3 could be part of a mechanism coupling DNA replication with repair of DNA damage, and DNA primase might be involved in this process.

Phosphorylation of the DNA Polymerase -Primase B Subunit Is Dependent on Its Association with the p180 Polypeptide

The B subunit of the DNA polymerase (pol) alpha-primase complex executes an essential role at the initial stage of DNA replication in Saccharomyces cerevisiae and is phosphorylated in a cell cycle-dependent manner. In this report, we show that the four subunits of the yeast DNA polymerase alpha-primase complex are assembled throughout the cell cycle, and physical association between newly synthesized pol alpha (p180) and unphosphorylated B subunit (p86) occurs very rapidly. Therefore, B subunit phosphorylation does not appear to modulate p180.p86 interaction. Conversely, by depletion experiments and by using a yeast mutant strain, which produces a low and constitutive level of the p180 polypeptide, we found that formation of the p180.p86 subcomplex is required for B subunit phosphorylation.

Common structural features of replication origins in all life forms.

Origins of replication (ORIs) among prokaryotes, viruses, and multicellular organisms appear to possess simple tri-, tetra-, or higher dispersed repetitions of nucleotides, AT tracts, inverted repeats, one to four binding sites of an initiator protein, intrinsically curved DNA, DNase I-hypersensitive sites, a distinct pattern of DNA methylation, and binding sites for transcription factors. Eukaryotic ORIs are sequestered on the nuclear matrix; this attachment is supposed to facilitate execution of their activation/deactivation programs during development. Furthermore, ORIs fall into various classes with respect to their sequence complexity: those enriched in AT tracts, those with GA- and CT-rich tracts, a smaller class of GC-rich ORIs, and a major class composed of mixed motifs yet containing distinct AT and polypurine or GC stretches. Multimers of an initiator protein in prokaryotes and viruses that might have evolved into a multiprotein replication initiation complex in multicellular organisms bind to the core ORI, causing a structural distortion to the DNA which is transferred to the AT tract flanking the initiator protein site; single-stranded DNA-binding proteins then interact with the melted AT tract as well as with the DNA polymerase alpha-primase complex in animal viruses and mammalian cells, causing initiation in DNA replication. ORIs in mammalian cells seem to colocalize with matrix-attached regions and are proposed to become DNase I-hypersensitive during their activation.

Human Xeroderma Pigmentosum Group A Protein Interacts with Human Replication Protein A and Inhibits DNA Replication

Human replication protein A (RPA; also known as human single-stranded DNA binding protein, or HSSB) is a multisubunit complex involved in both DNA replication and repair. While the role of RPA in replication has been well studied, its function in repair is less clear, although it is known to be involved in the early stages of the repair process. We found that RPA interacts with xeroderma pigmentosum group A complementing protein (XPAC), a protein that specifically recognizes UV-damaged DNA. We examined the effect of this XPAC-RPA interaction on in vitro simian virus 40 (SV40) DNA replication catalyzed by the monopolymerase system. XPAC inhibited SV40 DNA replication in vitro, and this inhibition was reversed by the addition of RPA but not by the addition of DNA polymerase alpha-primase complex, SV40 large tumor antigen, or topoisomerase I. This inhibition did not result from an interaction between XPAC and single-stranded DNA (ssDNA), or from competition between RPA and XPAC for DNA binding, because XPAC does not show any ssDNA binding activity and, in fact, stimulates RPA's ssDNA binding activity. Furthermore, XPAC inhibited DNA polymerase alpha activity in the presence of RPA but not in RPA's absence. These results suggest that the inhibitory effect of XPAC on DNA replication probably occurs through its interaction with RPA.

Efficient Replication of Polyomavirus DNA in a Cell-Free System Supplemented with Escherichia coli Single-Stranded DNA Binding Protein, Which Exhibits Species-Specificity in the Requirement for DNA Polymerase α-Primase1

We established a modified cell-free system for polyomavirus (PyV) DNA replication, which was supplemented with Escherichia coli single-stranded DNA binding protein (SSB). DNA synthesis in this system was enhanced by 1.4- to over 15-fold depending upon the amount of cell extracts contained in the reaction mixture. By supplementing with E. coli SSB, we were able to reduce the amount of cell extracts in the reaction mixture, and to lower the concentrations of creatine phosphate and Tris, rendering this system more resistant to salts than the conventional PyV DNA replication system. The modified system was characterized using mutant cell extracts which had heat-inactivated DNA polymerase alpha. DNA synthesis in the system was dependent on PyV T antigen, the PyV origin of DNA replication, mutant cell extracts, and DNA polymerase alpha-primase complex purified from wild-type cells. The DNA polymerase alpha-primase complex was not replaced by DNA polymerase alpha, indicating that this system requires a functional DNA polymerase alpha-primase complex. This system exhibited species-specificity in the requirement for DNA polymerase alpha-primase; only mouse DNA polymerase alpha-primase but not human DNA polymerase alpha-primase functioned in this system.

A 130 kDa Polypeptide Immunologically Related to the 180 kDa Catalytic Subunit of DNA Polymerase α-Primase Complex Is Detected in Early Embryos of Drosophila

An immunocytochemical method using specific antibodies was employed to detect DNA polymerase alpha-primase complex in Drosophila melanogaster embryos during the first 13 nuclear division cycles. A monoclonal antibody specific to the 72 kDa polypeptide stained interphase nuclei, but not metaphase chromosome, while at late anaphase and thereafter staining of the chromosome was regained. On the other hand, a polyclonal antibody specific to the 180 kDa polypeptide stained not only the interphase nuclei but also the cytoplasmic regions surrounding interphase nuclei. These results suggest that the distributions of the 180 kDa and the 72 kDa polypeptides of DNA polymerase alpha-primase complex are different. We detected the 180 kDa and the 72 kDa polypeptides in the extract prepared from a single Drosophila embryo by Western blotting, and a 130 kDa polypeptide immunologically related to the 180 kDa polypeptide was also detected in the extract. These polypeptides (180, 130, and 72 kDa) in the embryos were detected at similar levels at interphase and at the mitotic phase. These three polypeptides were also detected in unfertilized eggs, showing that they were maternally stored. The 130 kDa polypeptide was detected till cycle 10, then began to decrease, and finally disappeared at cycle 14, whereas the 180 kDa and the 72 kDa polypeptides were present without marked fluctuation in quantity throughout the developmental stages. Even in unfertilized eggs, the level of the 130 kDa polypeptide decreased gradually with a similar time course to that in fertilized ones, but the levels of the 180 kDa and the 72 kDa polypeptides remained unchanged. This is the first report suggesting the existence of the 130 kDa polypeptide in vivo in the early embryos of Drosophila. The significance of the 130 kDa polypeptide is discussed.