Phosphorylation of simian virus 40 T antigen on Thr 124 selectively promotes double-hexamer formation on subfragments of the viral core origin

Cell cycle-dependent phosphorylation of simian virus 40 (SV40) large tumor antigen (T-ag) on threonine 124 is essential for the initiation of viral DNA replication. A T-ag molecule containing a Thr-->Ala substitution at this position (T124A) was previously shown to bind to the SV40 core origin but to be defective in DNA unwinding and initiation of DNA replication. However, exactly what step in the initiation process is defective as a result of the T124A mutation has not been established. Therefore, to better understand the control of SV40 replication, we have reinvestigated the assembly of T124A molecules on the SV40 origin. Herein it is demonstrated that hexamer formation is unaffected by the phosphorylation state of Thr 124. In contrast, T124A molecules are defective in double-hexamer assembly on subfragments of the core origin containing single assembly units. We also report that T124A molecules are inhibitors of T-ag double hexamer formation. These and related studies indicate that phosphorylation of T-ag on Thr 124 is a necessary step for completing the assembly of functional double hexamers on the SV40 origin. The implications of these studies for the cell cycle control of SV40 DNA replication are discussed.     

Phosphopeptide binding by Sld3 links Dbf4‐dependent kinase to MCM replicative helicase activation

The initiation of eukaryotic DNA replication requires the assembly of active CMG (Cdc45‐MCM‐GINS) helicases at replication origins by a set of conserved and essential firing factors. This process is controlled during the cell cycle by cyclin‐dependent kinase (CDK) and Dbf4‐dependent kinase (DDK), and in response to DNA damage by the checkpoint kinase Rad53/Chk1. Here we show that Sld3, previously shown to be an essential CDK and Rad53 substrate, is recruited to the inactive MCM double hexamer in a DDK‐dependent manner. Sld3 binds specifically to DDK‐phosphorylated peptides from two MCM subunits (Mcm4, 6) and then recruits Cdc45. MCM mutants that cannot bind Sld3 or Sld3 mutants that cannot bind phospho‐MCM or Cdc45 do not support replication. Moreover, phosphomimicking mutants in Mcm4 and Mcm6 bind Sld3 without DDK and facilitate DDK‐independent replication. Thus, Sld3 is an essential “reader” of DDK phosphorylation, integrating signals from three distinct protein kinase pathways to coordinate DNA replication during S phase.     

Interactions required for binding of simian virus 40 T antigen to the viral origin and molecular modeling of initial assembly events

The purified T-antigen origin binding domain binds site specifically to site II, the central region of the simian virus 40 core origin. However, in the context of full-length T antigen, the origin binding domain interacts poorly with DNA molecules containing just site II. Here we investigate the contributions of additional core origin regions, termed the flanking sequences, to origin recognition and the assembly of T-antigen hexamers and double hexamers. Results from these studies indicate that in addition to site-specific binding of the T-antigen origin binding domain to site II, T-antigen assembly requires non-sequence-specific interactions between a basic finger in the helicase domain and particular flanking sequences. Related studies demonstrate that the assembly of individual hexamers is coupled to the distortions in the proximal flanking sequence. In addition, the point in the double-hexamer assembly process that is regulated by phosphorylation of threonine 124, the sole posttranslational modification required for initiation of DNA replication, was further analyzed. Finally, T-antigen structural information is used to model various stages of T-antigen assembly on the core origin and the regulation of this process.     

Mechanisms of simian virus 40 T-antigen activation by phosphorylation of threonine 124.

Previous studies have shown that phosphorylation of simian virus 40 (SV40) T antigen at threonine 124 enhances the binding of T antigen to the SV40 core origin of replication and the unwinding of the core origin DNA via hexamer-hexamer interactions. Here, we report that threonine 124 phosphorylation enhances the interaction of T-antigen amino acids 1 to 259 and 89 to 259 with the core origin of replication. Phosphorylation, therefore, activates the minimal DNA binding domain of T antigen even in the absence of domains required for hexamer formation. Activation is mediated by only one of three DNA binding elements in the minimal DNA binding domain of T antigen. This element, including amino acids 167, 215, and 219, enhances binding to the unique arrangement of four pentanucleotides in the core origin but not to other pentanucleotide arrangements found in ancillary regions of the SV40 origin of replication. Interestingly, the same four pentanucleotides in the core origin are necessary and sufficient for phosphorylation-enhanced DNA binding. Further, we show that phosphorylation of threonine 124 promotes the assembly of high-order complexes of the minimal DNA binding domain of T antigen with core origin DNA. We propose that phosphorylation induces conformational shifts in the minimal DNA binding domain of T antigen and thereby enhances interactions among T-antigen subunits oriented by core origin pentanucleotides. Similar subunit interactions would enhance both assembly of full-length T antigen into binary hexamer complexes and origin unwinding.     

Differential contribution of inhibitory phosphorylation of CDC2 and CDK2 for unperturbed cell cycle control and DNA integrity checkpoints

Inhibition of cyclin-dependent kinases (CDKs) by Thr14/Tyr15 phosphorylation is critical for normal cell cycle progression and is a converging event for several cell cycle checkpoints. In this study, we compared the relative contribution of inhibitory phosphorylation for cyclin A/B1-CDC2 and cyclin A/E-CDK2 complexes. We found that inhibitory phosphorylation plays a major role in the regulation of CDC2 but only a minor role for CDK2 during the unperturbed cell cycle of HeLa cells. The relative importance of inhibitory phosphorylation of CDC2 and CDK2 may reflect their distinct cellular functions. Despite this, expression of nonphosphorylation mutants of both CDC2 and CDK2 triggered unscheduled histone H3 phosphorylation early in the cell cycle and was cytotoxic. DNA damage by a radiomimetic drug or replication block by hydroxyurea stimulated a buildup of cyclin B1 but was accompanied by an increase of inhibitory phosphorylation of CDC2. After DNA damage and replication block, all cyclin-CDK pairs that control S phase and mitosis were to different degrees inhibited by phosphorylation. Ectopic expression of nonphosphorylated CDC2 stimulated DNA replication, histone H3 phosphorylation, and cell division even after DNA damage. Similarly, a nonphosphorylation mutant of CDK2, but not CDK4, disrupted the G2 DNA damage checkpoint. Finally, CDC25A, CDC25B, a dominant-negative CHK1, but not CDC25C or a dominant-negative WEE1, stimulated histone H3 phosphorylation after DNA damage. These data suggest differential contributions for the various regulators of Thr14/Tyr15 phosphorylation in normal cell cycle and during the DNA damage checkpoint.     

Partial purification and characterization of a protein kinase that is activated by nuclear localization signal peptides

A nuclear localization signal (NLS) is required for the transport of karyophilic proteins from the cytoplasm to the nucleus. In this study, NLS was examined in terms of its effect on diverse cellular functions such as protein phosphorylation reactions. When synthetic peptides containing the NLS of SV40 T-antigen were injected into the cytoplasm of Xenopus oocytes, and the oocytes incubated with [³²P]phosphorus-containing medium, a 32 kDa protein was found to be preferentially phosphorylated in an NLS-dependent manner. The incubation of fractionated cytosolic extracts prepared from mouse Ehrlich ascites tumor cells with [γ-³²P]ATP in the presence of the NLS peptides, results in the stimulation of the phosphorylation of several proteins. Similar in vitro stimulation was observed by other functional NLS peptides such as those of polyoma virus T-antigen and nucleoplasmin. Little or no stimulation, however, was detected for peptides of mutant type and reverse type NLS of SV40 T-antigen, and the C-terminal portion of lamin B. Using an in vitro assay, the phosphorylation activity was fractionated chromatographically and a fraction was obtained which contained a high level of activity. The fraction was found to contain three major proteins having molecular masses of 95, 70, and 43 kDa. The in vivo and in vitro results are consistent with the existence of a protein kinase, called NLS kinase, that is specifically activated by NLS peptides.     

Timed interactions between viral and cellular replication factors during the initiation of SV40 in vitro DNA replication

The initiation of SV40 (simian virus 40) DNA replication requires the co-operative interactions between the viral Tag (large T-antigen), RPA (replication protein A) and Pol (DNA polymerase alpha-primase) on the template DNA. Binding interfaces mapped on these enzymes and expressed as peptides competed with the mutual interactions of the native proteins. Prevention of the genuine interactions was accomplished only prior to the primer synthesis step and blocked the assembly of a productive initiation complex. Once the complex was engaged in the synthesis of an RNA primer and its extension, the interfering effects of the peptides ceased, suggesting a stable association of the replication factors during the initiation phase. Specific antibodies were still able to disrupt preformed interactions and inhibited primer synthesis and extension activities, underlining the crucial role of specific protein-protein contacts during the entire initiation process.     

A CDK-catalysed regulatory phosphorylation for formation of the DNA replication complex Sld2-Dpb11

Phosphorylation often regulates protein-protein interactions to control biological reactions. The Sld2 and Dpb11 proteins of budding yeast form a phosphorylation-dependent complex that is essential for chromosomal DNA replication. The Sld2 protein has a cluster of 11 cyclin-dependent kinase (CDK) phosphorylation motifs (Ser/Thr-Pro), six of which match the canonical sequences Ser/Thr-Pro-X-Lys/Arg, Lys/Arg-Ser/Thr-Pro and Ser/Thr-Pro-Lys/Arg. Simultaneous alanine substitution for serine or threonine in all the canonical CDK-phosphorylation motifs severely reduces complex formation between Sld2 and Dpb11, and inhibits DNA replication. Here we show that phosphorylation of these canonical motifs does not play a direct role in complex formation, but rather regulates phosphorylation of another residue, Thr84. This constitutes a non-canonical CDK-phosphorylation motif within a 28-amino-acid sequence that is responsible, after phosphorylation, for binding of Sld2-Dpb11. We further suggest that CDK-catalysed phosphorylation of sites other than Thr84 renders Thr84 accessible to CDK. Finally, we argue that this novel mechanism sets a threshold of CDK activity for formation of the essential Sld2 to Dpb11 complex and therefore prevents premature DNA replication.     

Site-specific phosphorylation of MCM4 during the cell cycle in mammalian cells

MCM4, a subunit of a putative replicative helicase, is phosphorylated during the cell cycle, at least in part by cyclin-dependent kinases (CDK), which play a central role in the regulation of DNA replication. However, detailed characterization of the phosphorylation of MCM4 remains to be performed. We examined the phosphorylation of human MCM4 at Ser3, Thr7, Thr19, Ser32, Ser54, Ser88 and Thr110 using anti-phosphoMCM4 sera. Western blot analysis of HeLa cells indicated that phosphorylation of MCM4 at these seven sites can be classified into two groups: (a) phosphorylation that is greatly enhanced in the G2 and M phases (Thr7, Thr19, Ser32, Ser54, Ser88 and Thr110), and (b) phosphorylation that is firmly detected during interphase (Ser3). We present data indicating that phosphorylation at Thr7, Thr19, Ser32, Ser88 and Thr110 in the M phase requires CDK1, using a temperature-sensitive mutant of mouse CDK1, and phosphorylation at sites 3 and 32 during interphase requires CDK2, using a dominant-negative mutant of human CDK2. Based on these results and those from in vitro phosphorylation of MCM4 with CDK2/cyclin A, we discuss the kinases responsible for MCM4 phosphorylation. Phosphorylated MCM4 detected using anti-phospho sera exhibited different affinities for chromatin. Studies on the nuclear localization of chromatin-bound MCM4 phosphorylated at sites 3 and 32 suggested that they are not generally colocalized with replicating DNA. Unexpectedly, MCM4 phosphorylated at site 32 was enriched in the nucleolus through the cell cycle. These results suggest that phosphorylation of MCM4 has several distinct and site-specific roles in the function of MCM during the mammalian cell cycle.     

Thr199 phosphorylation targets nucleophosmin to nuclear speckles and represses pre-mRNA processing

Nucleophosmin (NPM) is a multifunctional phosphoprotein, being involved in ribosome assembly, pre-ribosomal RNA processing, DNA duplication, nucleocytoplasmic protein trafficking, and centrosome duplication. NPM is phosphorylated by several kinases, including nuclear kinase II, casein kinase 2, Polo-like kinase 1 and cyclin-dependent kinases (CDK1 and 2), and these phosphorylations modulate the activity and function of NPM. We have previously identified Thr(199) as the major phosphorylation site of NPM mediated by CDK2/cyclin E (and A), and this phosphorylation is involved in the regulation of centrosome duplication. In this study, we further examined the effect of CDK2-mediated phosphorylation of NPM by using the antibody that specifically recognizes NPM phosphorylated on Thr(199). We found that the phospho-Thr(199) NPM localized to dynamic sub-nuclear structures known as nuclear speckles, which are believed to be the sites of storage and/or assembly of pre-mRNA splicing factors. Phosphorylation on Thr(199) by CDK2/cyclin E (and A) targets NPM to nuclear speckles, and enhances the RNA-binding activity of NPM. Moreover, phospho-Thr(199) NPM, but not unphosphorylated NPM, effectively represses pre-mRNA splicing. These findings indicate the involvement of NPM in the regulation of pre-mRNA processing, and its activity is controlled by CDK2-mediated phosphorylation on Thr(199).     

Characterization of the nuclear transport of a novel leucine-rich acidic nuclear protein-like protein

We previously reported that the nuclear localization signal (NLS) peptides stimulate the in vitro phosphorylation of several proteins, including a 34 kDa protein. In this study, we show that this specific 34 kDa protein is a novel murine leucine-rich acidic nuclear protein (LANP)-like large protein (mLANP-L). mLANP-L was found to have a basic type NLS. The co-injection of Q69LRan-GTP or SV40 T-antigen NLS peptides prevented the nuclear import of mLANP-L. mLANP-L NLS bound preferentially to Rch1 and NPI-1, but not to the Qip1 subfamily of importin alpha. These findings suggest that mLANP-L is transported into the nucleus by Rch1 and/or NPI-1.     

Two Regions of Simian Virus 40 T Antigen Determine Cooperativity of Double-Hexamer Assembly on the Viral Origin of DNA Replication and Promote Hexamer Interactions during Bidirectional Origin DNA Unwinding

Phosphorylation of simian virus 40 large tumor (T) antigen on threonine 124 is essential for viral DNA replication. A mutant T antigen (T124A), in which this threonine was replaced by alanine, has helicase activity, assembles double hexamers on viral-origin DNA, and locally distorts the origin DNA structure, but it cannot catalyze origin DNA unwinding. A class of T-antigen mutants with single-amino-acid substitutions in the DNA binding domain (class 4) has remarkably similar properties, although these proteins are phosphorylated on threonine 124, as we show here. By comparing the DNA binding properties of the T124A and class 4 mutant proteins with those of the wild type, we demonstrate that mutant double hexamers bind to viral origin DNA with reduced cooperativity. We report that T124A T-antigen subunits impair the ability of double hexamers containing the wild-type protein to unwind viral origin DNA, suggesting that interactions between hexamers are also required for unwinding. Moreover, the T124A and class 4 mutant T antigens display dominant-negative inhibition of the viral DNA replication activity of the wild-type protein. We propose that interactions between hexamers, mediated through the DNA binding domain and the N-terminal phosphorylated region of T antigen, play a role in double-hexamer assembly and origin DNA unwinding. We speculate that one surface of the DNA binding domain in each subunit of one hexamer may form a docking site that can interact with each subunit in the other hexamer, either directly with the N-terminal phosphorylated region or with another region that is regulated by phosphorylation.

The initiation of simian virus 40 (SV40) DNA replication by the viral T antigen is a complex series of events that begins when T antigen binds specifically to a palindromic arrangement of four GAGGC pentanucleotide sequences in the minimal origin of viral DNA replication (recently reviewed in references 1, 2, 3, 22, and 48). In the presence of Mg-ATP, T antigen assembles cooperatively on the two halves of the palindrome as a double hexamer (10, 11, 13, 24, 30, 38, 51, 53). The DNA conformation flanking the T-antigen binding sites is locally distorted upon hexamer assembly (reference 7 and references therein). One pair of pentanucleotides is sufficient to direct double-hexamer assembly and local distortion of the origin DNA but not to initiate DNA replication (25). ATP hydrolysis by T-antigen hexamers then catalyzes bidirectional unwinding of the parental DNA (reference 53 and references therein). A mutant origin with a single nucleotide insertion in the center of the palindromic T-antigen binding site prevents cooperative interactions between hexamers and cannot support bidirectional origin unwinding (8, 51), suggesting that both processes require interactions between T-antigen hexamers. After assembly of the two replication forks, bidirectional replication is carried out by 10 cellular proteins and T antigen, which remains at the forks as the only essential helicase (reviewed in references 3, 22, and 48).The phosphorylation state of SV40 T antigen governs its ability to initiate viral DNA replication (reviewed in references 15 to 17 and 39). T antigen contains two clusters of phosphorylation sites located at the N and C termini (40, 41). Phosphorylation of T antigen on threonine 124 in the N-terminal cluster was shown to be essential for viral DNA replication in monkey cells and in vitro (5, 14, 32–36, 44). Efforts to define what step in viral DNA replication requires modification of threonine 124 revealed that Mg-ATP-induced hexamer formation of T antigen in solution and DNA helicase activity of T antigen did not require phosphorylation at this site (33, 36). Origin DNA binding of T antigen lacking the modification at residue 124 was weaker than that of the modified T antigen (33, 34, 36, 44), but the reduction in binding was modest under the conditions used for SV40 DNA replication in vitro (36). Moreover, a mutant T antigen containing alanine in place of the phosphorylated threonine (T124A) assembled as a double hexamer on the viral origin and altered the conformation of the early palindrome and AT-rich sequences flanking the T-antigen binding sites in the viral origin in the same manner as the wild-type protein, except that higher concentrations were required (36). However, even at an elevated concentration, these mutant double hexamers were unable to unwind closed circular duplex DNA containing the viral origin (33, 36), suggesting that the defect in unwinding was responsible for the inability of T124A T antigen to replicate SV40 DNA. One possible explanation for the unwinding defect of the mutant T antigen, despite its helicase activity, was that some essential interaction between the two hexamers during bidirectional unwinding depended upon phosphorylation of threonine 124. Electron micrographs of SV40 DNA unwinding intermediates, which showed two single-stranded DNA loops protruding between two hexamers of T antigen, provided support for this explanation, implying that a double hexamer pulled the parental duplex DNA into the protein complex and spooled the single-stranded DNA out (53). Furthermore, double-hexamer formation significantly enhanced the helicase activity of T antigen (47, 47a).Most of the T antigen isolated from mammalian cells is in a hyperphosphorylated form, containing multiple phosphoserines, as well as two phosphothreonines, and supports SV40 DNA replication in vitro poorly but can be stimulated by treatment with alkaline phosphatase or protein phosphatase 2A (19, 28, 37, 42, 49, 50). Hyperphosphorylated T antigen is unable to unwind duplex closed circular duplex DNA harboring the viral origin (4, 6, 51). Dephosphorylation of serines 120 and 123 restores its ability to unwind origin DNA (14, 43, 51). Studies of double-hexamer assembly on the origin indicate that phosphorylation of T antigen on serines 120 and 123 also impairs the cooperativity of double-hexamer assembly (14, 51). These results demonstrate that hyperphosphorylation of T antigen interferes with interactions between hexamers that are required for origin unwinding and raise the question of whether the phosphorylation state of threonine 124 might also affect the cooperativity of double-hexamer assembly on the viral origin.One class of T antigen mutants with single-amino-acid substitutions in the DNA binding domain (class 4) has been reported to display properties similar to those of the T124A mutant and the hyperphosphorylated form of T antigen (54). Class 4 mutant proteins are defective in viral DNA replication in vivo and in vitro, bind to the viral origin as double hexamers and alter the local DNA conformation, and have helicase activity but do not unwind closed circular duplex viral DNA. The replication and unwinding defects could be due to faulty phosphorylation patterns or to other malfunctions not dependent on phosphorylation status.The work presented here was undertaken to reevaluate the assembly of wild-type and T124A T antigen on SV40 origin DNA by using more-sensitive quantitative assays and to compare them with the class 4 mutants. We report that cooperativity of T124A T antigen in double-hexamer assembly on the viral origin is impaired. The class 4 mutant T antigens were also found to have defects in cooperativity of double-hexamer assembly. T124A T antigen inhibited the ability of the wild-type protein to unwind closed circular duplex origin DNA. Both T124A and the class 4 mutants displayed dominant-negative phenotypes in viral DNA replication in vitro. Based on these observations, we propose that the N-terminal cluster of phosphorylation sites and the DNA binding domain mediate cooperative hexamer-hexamer interactions during assembly on the viral origin and speculate that these regions of T antigen may interact during origin DNA unwinding.     

Phosphorylation of MCM4 at sites inactivating DNA helicase activity of the MCM4-MCM6-MCM7 complex during Epstein-Barr virus productive replication

Induction of Epstein-Barr virus (EBV) lytic replication blocks chromosomal DNA replication notwithstanding an S-phase-like cellular environment with high cyclin-dependent kinase (CDK) activity. We report here that the phosphorylated form of MCM4, a subunit of the MCM complex essential for chromosomal DNA replication, increases with progression of lytic replication, Thr-19 and Thr-110 being CDK2/CDK1 targets whose phosphorylation inactivates MCM4-MCM6-MCM7 (MCM4-6-7) complex-associated DNA helicase. Expression of EBV-encoded protein kinase (EBV-PK) in HeLa cells caused phosphorylation of these sites on MCM4, leading to cell growth arrest. In vitro, the sites of MCM4 of the MCM4-6-7 hexamer were confirmed to be phosphorylated with EBV-PK, with the same loss of helicase activity as with CDK2/cyclin A. Introducing mutations in the N-terminal six Ser and Thr residues of MCM4 reduced the inhibition by CDK2/cyclin A, while EBV-PK inhibited the helicase activities of both wild-type and mutant MCM4-6-7 hexamers, probably since EBV-PK can phosphorylate MCM6 and another site(s) of MCM4 in addition to the N-terminal residues. Therefore, phosphorylation of the MCM complex by redundant actions of CDK and EBV-PK during lytic replication might provide one mechanism to block chromosomal DNA replication in the infected cells through inactivation of DNA unwinding by the MCM4-6-7 complex.     

Regulation of the localization and stability of Cdc6 in living yeast cells

The Cdc6 protein is an essential regulator for initiation of DNA replication. Following the G1/S transition, Cdc6 is degraded through a ubiquitin-mediated proteolysis pathway. In this study, we tagged Cdc6 with green fluorescent protein (GFP) and used site-specific mutations to study the regulation of Cdc6 localization and degradation in living yeast cells. Our major findings are: (1). Cdc6-GFP distributes predominantly in the nucleus in all cell cycle stages, with a small increase in cytoplasmic localization in G2/M cells. (2). This nuclear localization is critical for Cdc6 degradation. When the N-terminal nuclear localization signal (NLS) was mutated, Cdc6-GFP no longer accumulated in the nucleus, and the mutant cdc6 was stabilized compared to wild type. (3). The putative CDK phosphorylation sites are not required for Cdc6 nuclear localization, but are important for protein stability. These observations suggest that the stability of Cdc6 protein is regulated by two factors: nuclear localization and phosphorylation by CDK1.     

CDK-Dependent Stabilization of Cdc6: Linking Growth and Stress Signals to Activation of DNA Replication

Cyclin-dependent kinases (CDKs) play a crucial role in cell cycle progression by controlling the transition from G1 phase into S phase where DNA is replicated. Key to this transition is the regulation of initiation of DNA replication at replication origins. CDKs are thought to regulate origins of replication both positively and negatively by phosphorylating replication proteins at origins. Several replication proteins that are potentially negatively regulated upon CDK phosphorylation have been identified. However, the mechanism by which CDKs activate replication is currently less well understood. New observations revealing that the initiation protein Cdc6 is stabilized by CDK2-dependent phosphorylation may give more insight in this process.     

Identification of MCM4 as a target of the DNA replication block checkpoint system

Inhibition of the progression of DNA replication prevents further initiation of DNA replication and allows cells to maintain arrested replication forks, but the proteins that are targets of the replication checkpoint system remain to be identified. We report here that human MCM4, a subunit of the putative DNA replicative helicase, is extensively phosphorylated in HeLa cells when they are incubated in the presence of inhibitors of DNA synthesis or are exposed to UV irradiation. The data presented here indicate that the consecutive actions of ATR-CHK1 and CDK2 kinases are involved in this phosphorylation in the presence of hydroxyurea. The phosphorylation sites in MCM4 were identified using specific anti-phosphoantibodies. Based on results that showed that the DNA helicase activity of the MCM4-6-7 complex is negatively regulated by CDK2 phosphorylation, we suggest that the phosphorylation of MCM4 in the checkpoint control inhibits DNA replication, which includes blockage of DNA fork progression, through inactivation of the MCM complex.     

Xenopus phospho-CDK7/cyclin H expressed in baculoviral-infected insect cells.

The cyclin-dependent kinase-activating kinase (CAK) catalyzes the phosphorylation of the cyclin-dependent protein kinases (CDKs) on a threonine residue (Thr160 in human CDK2). The reaction is an obligatory step in the activation of the CDKs. In higher eukaryotes, the CAK complex has been characterized in two forms. The first consists of three subunits, namely CDK7, cyclin H, and an assembly factor called MAT1, while the second consists of phospho-CDK7 and cyclin H. Phosphorylation of CDK7 is essential for cyclin association and kinase activity in the absence of the assembly factor MAT1. The Xenopus laevis CDK7 phosphorylation sites are located on the activation segment of the kinase at residues Ser170 and at Thr176 (the latter residue corresponding to Thr160 in human CDK2). We report the expression and purification of X. laevis CDK7/cyclin H binary complex in insect cells through coinfection with the recombinant viruses, AcCDK7 and Accyclin H. Quantities suitable for crystallization trials have been obtained. The purified CDK7/cyclin H binary complex phosphorylated CDK2 and CDK2/cyclin A but did not phosphorylate histone H1 or peptide substrates based on the activation segments of CDK7 and CDK2. Analysis by mass spectrometry showed that coexpression of CDK7 with cyclin H in baculoviral-infected insect cells results in phosphorylation of residues Ser170 and Thr176 in CDK7. It is assumed that phosphorylation is promoted by kinase(s) in the insect cells that results in the correct, physiologically significant posttranslational modification. We discuss the occurrence of in vivo phosphorylation of proteins expressed in baculoviral-infected insect cells.     

Phosphorylation of Mcm4 at specific sites by cyclin-dependent kinase leads to loss of Mcm4,6,7 helicase activity.

Mcm proteins that play an essential role in eukaryotic DNA replication are phosphorylated in vivo, and cyclin-dependent protein kinase is at least in part responsible for the phosphorylation of Mcm4. Our group reported that the DNA helicase activity of Mcm4,6,7 complex, which may be involved in initiation of DNA replication, is inhibited following phosphorylation by Cdk2/cyclin A in vitro. Here, we further examined the interplay between mouse Mcm4,6,7 complex and cyclin-dependent kinases and determined the sites required for the phosphorylation of Mcm4. Six Ser and Thr residues, in all, were required for the phosphorylation. Inhibition of Mcm4,6,7 helicase activity by Cdk2/cyclin A was largely relieved by introducing mutations in these residues of Mcm4. Anti-phosphothreonine antibodies raised against one of these sites reacted with Mcm4 prepared from HeLa cells at mitotic phase but did not bind to those at G(1) and G(1)/S, suggesting that this site is mainly phosphorylated in the mitotic phase. Mcm4,6,7 complex purified from HeLa cells at the mitotic phase exhibited a low level of DNA helicase activity, compared with the complexes prepared from cells at other phases. These results suggest that phosphorylation of Mcm4 at specific sites leads to loss of Mcm4,6,7 DNA helicase activity.     

Topoisomerase I associates specifically with simian virus 40 large-T-antigen double hexamer-origin complexes

Topoisomerase I (topo I) is required for releasing torsional stress during simian virus 40 (SV40) DNA replication. Recently, it has been demonstrated that topo I participates in initiation of replication as well as in elongation. Although T antigen and topo I can bind to one another in vitro, there is no direct evidence that topo I is a component of the replication initiation complex. We demonstrate in this report that topo I associates with T-antigen double hexamers bound to SV40 origin DNA (T(DH)) but not to single hexamers. This association has the same nucleotide and DNA requirements as those for the formation of double hexamers on DNA. Interestingly, topo I prefers to bind to fully formed T(DH) complexes over other oligomerized forms of T antigen associated with the origin. High ratios of topo I to origin DNA destabilize T(DH). The partial unwinding of a small-circular-DNA substrate is dependent on the presence of both T antigen and topo I but is inhibited at high topo I concentrations. Competition experiments with a topo I-binding fragment of T antigen indicate that an interaction between T antigen and topo I occurs during the unwinding reaction. We propose that topo I is recruited to the initiation complex after the assembly of T(DH) and before unwinding to facilitate DNA replication.     

Levels of MCM4 phosphorylation and DNA synthesis in DNA replication block checkpoint control

Blockage of a DNA replication fork movement not only stabilizes the fork structure but also prevents initiation of DNA replication. We reported that MCM4, a subunit of a putative replicative DNA helicase, is extensively phosphorylated in the presence of hydroxyurea (HU) or after exposure to UV irradiation. Here we examined the relationship between levels of MCM4 phosphorylation and DNA synthesis during DNA replication checkpoint control and after release of the control. The results suggest that there is roughly inverse correlation between these two levels; namely the higher the level of MCM4 phosphorylation, the lower the level of DNA synthesis. The presence of HU or UV irradiation can stimulate phosphorylation at several cyclin-dependent kinase (CDK) sites in MCM4, which can lead to inhibition of MCM4/6/7 helicase activity. These results are consistent with the notion that the phosphorylation of MCM4 is involved in regulation of DNA synthesis in the checkpoint control.