The yeast CDC9 gene encodes both a nuclear and a mitochondrial form of DNA ligase I.

BACKGROUND: The yeast CDC9 gene encodes a DNA ligase I activity required during nuclear DNA replication to ligate the Okazaki fragments formed when the lagging DNA strand is synthesised. The only other DNA ligase predicted from the yeast genome sequence, DNL4/LIG4, is specifically involved in a non-homologous DNA end-joining reaction. What then is the source of the DNA ligase activity required for replication of the yeast mitochondrial genome? RESULTS: We report that CDC9 encodes two distinct polypeptides expressed from consecutive in-frame AUG codons. Translational initiation at these two sites gives rise to polypeptides differing by a 23 residue amino-terminal extension, which corresponds to a functional mitochondrial pre-sequence sufficient to direct import into yeast mitochondria. Initiation at the first AUG codon results in a 755 amino-acid polypeptide that is imported into mitochondria, whereupon the pre-sequence is proteolytically removed to yield the mature mitochondrial form of Cdc9p. Initiation at the second AUG codon produces a 732 amino-acid polypeptide, which is localised to the nucleus. Cells expressing only the nuclear isoform were found to be specifically defective in the maintenance of the mitochondrial genome. CONCLUSIONS: CDC9 encodes two distinct forms of DNA ligase I. The first is targeted to the mitochondrion and is required for propagation and maintenance of mitochondrial DNA, the second localises to the nucleus and is sufficient for the essential cell-division function associated with this gene.     

Functional analysis of subcellular localization and protein-protein interaction sequences in the essential DNA ligase I protein of fission yeast

DNA ligase I (Lig I) has key roles in chromosomal DNA replication and repair in the eukaryotic cell nucleus. In the budding yeast Saccharomyces cerevisiae the Lig I enzyme Cdc9p is also required for mitochondrial DNA replication and repair. In this report, dual nuclear–mitochondrial localization is demonstrated to be a property of the essential Lig I enzyme Cdc17 from the distantly related fission yeast Schizosaccharomyces pombe. Expression of nuclear and mitochondrial forms of Cdc17 from separate genes shows that, whereas expression of either protein alone is insufficient to restore viability to cells lacking endogenous Cdc17, co-expression restores full viability. In the nucleus, Lig I interacts with the sliding clamp proliferating cell nuclear antigen (PCNA) via a conserved PCNA interacting sequence motif known as a PIP box. Deletion of the PIP motif from the N-terminus of the nuclear form of Cdc17 fails to abolish Cdc17 function, indicating that PCNA binding by Cdc17 is not an absolute requirement for completion of S-phase.     

The human DNA ligase III gene encodes nuclear and mitochondrial proteins

We provide evidence that the human DNA ligase III gene encodes a mitochondrial form of this enzyme. First, the DNA ligase III cDNA contains an in-frame ATG located upstream from the putative translation initiation start site. The DNA sequence between these two ATG sites encodes an amphipathic helix similar to previously identified mitochondrial targeting peptides. Second, recombinant green fluorescent protein harboring this sequence at its amino terminus was efficiently targeted to the mitochondria of Cos-1 monkey kidney cells. In contrast, native green fluorescent protein distributed to the cytosol. Third, a series of hemagglutinin-DNA ligase III minigene constructs were introduced into Cos-1 cells, and immunocytochemistry was used to determine subcellular localization of the epitope-tagged DNA ligase III protein. These experiments revealed that inactivation of the upstream ATG resulted in nuclear accumulation of the DNA ligase III protein, whereas inactivation of the downstream ATG abolished nuclear localization and led to accumulation within the mitochondrial compartment. Fourth, mitochondrial protein extracts prepared from human cells overexpressing antisense DNA ligase III mRNA possessed substantially less DNA ligase activity than did mitochondrial extracts prepared from control cells. DNA end-joining activity was also substantially reduced in extracts prepared from antisense mRNA-expressing cells. From these results, we conclude that the human DNA ligase III gene encodes both nuclear and mitochondrial enzymes. DNA ligase plays a central role in DNA replication, recombination, and DNA repair. Thus, identification of a mitochondrial form of this enzyme provides a tool with which to dissect mammalian mitochondrial genome dynamics.     

Lif1p targets the DNA ligase Lig4p to sites of DNA double-strand breaks

DNA ligases catalyse the joining of DNA single- and double-strand breaks. Saccharomyces cerevisiae Cdc9p is a homologue of mammalian DNA ligase I and is required for DNA replication, recombination and single-strand break repair. The other yeast ligase, Lig4p/Dnl4p, is a homologue of mammalian DNA ligase IV, and functions in the non-homologous end-joining (NHEJ) pathway of DNA double-strand break repair [1] [2] [3] [4]. Lig4p interacts with Lif1p, the yeast homologue of the human ligase IV-associated protein, XRCC4 [5]. This interaction takes place through the carboxy-terminal domain of Lig4p and is required for Lig4p stability. We show that the carboxy-terminal interaction region of Lig4p is necessary for NHEJ but, when fused to Cdc9p, is insufficient to confer NHEJ function to Cdc9p. Also, Lif1p stimulates the in vitro catalytic activity of Lig4p in adenylation and DNA ligation. Nevertheless, Lig4p is inactive in NHEJ in the absence of Lif1p in vivo, even when Lig4p is stably expressed. We show that Lif1p binds DNA in vitro and, through in vivo cross-linking and chromatin immuno precipitation assays, demonstrate that it targets Lig4p to chromosomal DNA double-strand breaks. Furthermore, this targeting requires another key NHEJ protein, Ku.     

DNA ligase I from Saccharomyces cerevisiae: physical and biochemical characterization of the CDC9 gene product.

Genetic studies have previously demonstrated that the Saccharomyces cerevisiae CDC9 gene product, which is functionally homologous to mammalian DNA ligase I, is required for DNA replication and is also involved in DNA repair and genetic recombination. In the present study we have purified the yeast enzyme. When measured under denaturing conditions, Cdc9 protein has a polypeptide molecular mass of 87 kDa. The native form of the enzyme is an 80-kDa asymmetric monomer. Both estimates are in good agreement with the M(r) = 84,406 predicted from the translated sequence of the CDC9 gene. Cdc9 DNA ligase acts via the same basic reaction mechanism employed by all known ATP-dependent DNA ligases. The catalytic functions reside in a 70-kDa C-terminal domain that is conserved in mammalian DNA ligase I and in Cdc17 DNA ligase from Schizosaccharomyces pombe. The ATP analog ATP alpha S inhibits the ligation reaction, although Cdc9 protein does form an enzyme-thioadenylate intermediate. Since Cdc9 DNA ligase exhibited the same substrate specificity as mammalian DNA ligase I, this enzyme can be considered to be the DNA ligase I of S. cerevisiae. There is genetic evidence suggesting that DNA ligase may be directly involved in error-prone DNA repair. We examined the ability of Cdc9 DNA ligase to join nicks with mismatches at the termini. Mismatches at the 5' termini of nicks had very little effect on ligation, whereas mismatches opposite a purine at 3' termini inhibited DNA ligation. The joining of DNA molecules with mismatched termini by DNA ligase may be responsible for the generation of mutations.     

A single-stranded DNA binding protein required for mitochondrial DNA replication in S. cerevisiae is homologous to E. coli SSB.

It has previously been shown that the mitochondrial DNA (mtDNA) of Saccharomyces cerevisiae becomes thermosensitive due to the inactivation of the mitochondrial DNA helicase gene, PIF1. A suppressor of this thermosensitive phenotype was isolated from a wild-type plasmid library by transforming a pif1 null strain to growth on glycerol at the non-permissive temperature. This suppressor is a nuclear gene encoding a 135 amino acid protein that is itself essential for mtDNA replication; cells lacking this gene are totally devoid of mtDNA. We therefore named this gene RIM1 for replication in mitochondria. The primary structure of the RIM1 protein is homologous to the single-stranded DNA binding protein (SSB) from Escherichia coli and to the mitochondrial SSB from Xenopus laevis. The mature RIM1 gene product has been purified from yeast extracts using a DNA unwinding assay dependent upon the DNA helicase activity of SV40 T-antigen. Direct amino acid sequencing of the protein reveals that RIM1 is a previously uncharacterized SSB. Antibodies against this purified protein localize RIM1 to mitochondria. The SSB encoded by RIM1 is therefore an essential component of the yeast mtDNA replication apparatus.     

The C-terminal domain of yeast PCNA is required for physical and functional interactions with Cdc9 DNA ligase

There is compelling evidence that proliferating cell nuclear antigen (PCNA), a DNA sliding clamp, co-ordinates the processing and joining of Okazaki fragments during eukaryotic DNA replication. However, a detailed mechanistic understanding of functional PCNA:ligase I interactions has been incomplete. Here we present the co-crystal structure of yeast PCNA with a peptide encompassing the conserved PCNA interaction motif of Cdc9, yeast DNA ligase I. The Cdc9 peptide contacts both the inter-domain connector loop (IDCL) and residues near the C-terminus of PCNA. Complementary mutational and biochemical results demonstrate that these two interaction interfaces are required for complex formation both in the absence of DNA and when PCNA is topologically linked to DNA. Similar to the functionally homologous human proteins, yeast RFC interacts with and inhibits Cdc9 DNA ligase whereas the addition of PCNA alleviates inhibition by RFC. Here we show that the ability of PCNA to overcome RFC-mediated inhibition of Cdc9 is dependent upon both the IDCL and the C-terminal interaction interfaces of PCNA. Together these results demonstrate the functional significance of the β-zipper structure formed between the C-terminal domain of PCNA and Cdc9 and reveal differences in the interactions of FEN-1 and Cdc9 with the two PCNA interfaces that may contribute to the co-ordinated, sequential action of these enzymes.     

Genetic instability induced by overexpression of DNA ligase I in budding yeast

Recombination and microsatellite mutation in humans contribute to disorders including cancer and trinucleotide repeat (TNR) disease. TNR expansions in wild-type yeast may arise by flap ligation during lagging-strand replication. Here we show that overexpression of DNA ligase I (CDC9) increases the rates of TNR expansion, of TNR contraction, and of mitotic recombination. Surprisingly, this effect is observed with catalytically inactive forms of Cdc9p protein, but only if they possess a functional PCNA-binding site. Furthermore, in vitro analysis indicates that the interaction of PCNA with Cdc9p and Rad27p (Fen1) is mutually exclusive. Together our genetic and biochemical analysis suggests that, although DNA ligase I seals DNA nicks during replication, repair, and recombination, higher than normal levels can yield genetic instability by disrupting the normal interplay of PCNA with other proteins such as Fen1.     

Cdc6 and DNA replication: Limited to humble origins

The budding yeast Cdc6 protein is important for regulating DNA replication intiation. Cdc6p acts at replication origins, and cdc6-1 mutants arrest with unreplicated DNA and show elevated minichromosome loss rates. Overexpression of the related Cdc 18 protein in fission yeast results in DNA rereplication; however, Cdc6p overexpression does not cause this result. A recent paper⁽¹⁾ further defines the role of Cdc6p in DNA replication. Cdc6p only promotes DNA replication between the end of mitosis and late G₁, and although the Cdc6 protein is highly unstable, neither degradation nor nuclear localization is critical for limiting DNA replication to this interval.     

DNA ligation during excision repair in yeast cell-free extracts is specifically catalyzed by the CDC9 gene product

Excision repair of DNA is an important cellular response to DNA damage induced by radiation and many chemicals. In eukaryotes, base excision repair (BER) and nucleotide excision repair (NER) are two major excision repair pathways which are completed by a DNA ligation step. Using a cell-free system, we have determined the DNA ligase requirement during BER and NER of the yeast S. cerevisiae. Under nonpermissive conditions in extracts of the cdc9-2 temperature-sensitive mutant, DNA ligation in both BER and NER pathways was defective, and the repair patches were enlarged. At the permissive temperature (23 degrees C), DNA ligation during excision repair was only partially functional in the mutant extracts. In contrast, deleting the DNA ligase IV gene did not affect DNA ligation of BER or NER. Defective DNA ligation of BER and NER in cdc9-2 mutant extracts was complemented in vitro by purified yeast Cdc9 protein, but not by DNA ligase IV even when overexpressed. These results demonstrate that the ligation step of excision repair in yeast cell-free extracts is catalyzed specifically by the Cdc9 protein, the homologue of mammalian DNA ligase I.     

Crucial mitochondrial impairment upon CDC48 mutation in apoptotic yeast

Mutation in CDC48 (cdc48(S565G)), a gene essential in the endo-plasmic reticulum (ER)-associated protein degradation (ERAD) pathway, led to the discovery of apoptosis as a mechanism of cell death in the unicellular organism Saccharomyces cerevisiae. Elucidating Cdc48p-mediated apoptosis in yeast is of particular interest, because Cdc48p is the highly conserved yeast orthologue of human valosin-containing protein (VCP), a pathological effector for polyglutamine disorders and myopathies. Here we show distinct proteomic alterations in mitochondria in the cdc48(S565G) yeast strain. These observed molecular alterations can be related to functional impairment of these organelles as suggested by respiratory deficiency of cdc48(S565G) cells. Mitochondrial dysfunction in the cdc48(S565G) strain is accompanied by structural damage of mitochondria indicated by the accumulation of cytochrome c in the cytosol and mitochondrial enlargement. We demonstrate accumulation of reactive oxygen species produced predominantly by the cytochrome bc1 complex of the mitochondrial respiratory chain as suggested by the use of inhibitors of this complex. Concomitantly, emergence of caspase-like enzymatic activity occurs suggesting a role for caspases in the cell death process. These data strongly point for the first time to a mitochondrial involvement in Cdc48p/VCP-dependent apoptosis.     

Separate SCF(CDC4) recognition elements target Cdc6 for proteolysis in S phase and mitosis

The Cdc6 DNA replication initiation factor is targeted for ubiquitin-mediated proteolysis by the E3 ubiquitin ligase SCF(CDC4) from the end of G1phase until mitosis in the budding yeast Saccharomyces cerevisiae. Here we describe a dominant-negative CDC6 mutant that, when overexpressed, arrests the cell cycle by inhibiting cyclin-dependent kinases (CDKs) and, thus, prevents passage through mitosis. This mutant protein inhibits CDKs more efficiently than wild-type Cdc6, in part because it is completely refractory to SCF(CDC4)-mediated proteolysis late in the cell cycle and consequently accumulates to high levels. The mutation responsible for this phenotype destroys a putative CDK phosphorylation site near the middle of the Cdc6 primary amino acid sequence. We show that this site lies within a novel Cdc4-interacting domain distinct from a Cdc4-interacting site identified previously near the N-terminus of the protein. We show that both sites can target Cdc6 for proteolysis in late G1/early S phase whilst only the newly identified site can target Cdc6 for proteolysis during mitosis.     

Mitochondrial quality control by the ubiquitin-proteasome system

Mitochondria perform multiple functions critical to the maintenance of cellular homoeostasis and their dysfunction leads to disease. Several lines of evidence suggest the presence of a MAD (mitochondria-associated degradation) pathway that regulates mitochondrial protein quality control. Internal mitochondrial proteins may be retrotranslocated to the OMM (outer mitochondrial membrane), multiple E3 ubiquitin ligases reside at the OMM and inhibition of the proteasome causes accumulation of ubiquitinated proteins at the OMM. Reminiscent of ERAD [ER (endoplasmic reticulum)-associated degradation], Cdc48 (cell division cycle 42)/p97 is recruited to stressed mitochondria, extracts ubiquitinated proteins from the OMM and presents ubiquitinated proteins to the proteasome for degradation. Recent research has provided mechanistic insights into the interaction of the UPS (ubiquitin-proteasome system) with the OMM. In yeast, Vms1 [VCP (valosin-containing protein) (p97)/Cdc48-associated mitochondrial-stress-responsive 1] protein recruits Cdc48/p97 to the OMM. In mammalian systems, the E3 ubiquitin ligase parkin regulates the recruitment of Cdc48/p97 to mitochondria, subsequent mitochondrial protein degradation and mitochondrial autophagy. Disruption of the Vms1 or parkin systems results in the hyper-accumulation of ubiquitinated proteins at mitochondria and subsequent mitochondrial dysfunction. The emerging MAD pathway is important for the maintenance of cellular and therefore organismal viability.     

Role of the putative structural protein Sed1p in mitochondrial genome maintenance

The nuclear gene MIP1 encodes the mitochondrial DNA polymerase responsible for replicating the mitochondrial genome in Saccharomyces cerevisiae. A number of other factors involved in replicating and segregating the mitochondrial genome are yet to be identified. Here, we report that a bacterial two-hybrid screen using the mitochondrial polymerase, Mip1p, as bait identified the yeast protein Sed1p. Sed1p is a cell surface protein highly expressed in the stationary phase. We find that several modified forms of Sed1p are expressed and the largest of these forms interacts with the mitochondrial polymerase in vitro. Deletion of SED1 causes a 3.5-fold increase in the rate of mitochondrial DNA point mutations as well as a 4.3-fold increase in the rate of loss of respiration. In contrast, we see no change in the rate of nuclear point mutations indicating the specific role of Sed1p function in mitochondrial genome stability. Indirect immunofluorescence analysis of Sed1p localization shows that Sed1p is targeted to the mitochondria. Moreover, Sed1p is detected in purified mitochondrial fractions and the localization to the mitochondria of the largest modified form is insensitive to the action of proteinase K. Deletion of the sed1 gene results in a reduction in the quantity of Mip1p and also affects the levels of a mitochondrially-expressed protein, Cox3p. Our results point towards a role for Sed1p in mitochondrial genome maintenance.     

Budding yeast Cdc6p induces re-replication in fission yeast by inhibition of SCFPop-mediated proteolysis

In fission yeast, overexpression of the replication initiator protein Cdc18p induces re-replication, a phenotype characterized by continuous DNA synthesis in the absence of cell division. In contrast, overexpression of Cdc6p, the budding yeast homolog of Cdc18p, does not cause re-replication in S. cerevisiae. However, we have found that Cdc6p has the ability to induce re-replication in fission yeast. Cdc6p cannot functionally replace Cdc18p, but instead interferes with the proteolysis of both Cdc18p and Rum1p, the inhibitor of the protein kinase Cdc2p. This activity of Cdc6p is entirely contained within a short N-terminal peptide, which forms a tight complex with Cdc2p and the F-box/WD-repeat protein Sud1p/Pop2p, a component of the SCF^Pop ubiquitin ligase in fission yeast. These interactions are mediated by two distinct regions within the N-terminal region of Cdc6p and depend on the integrity of its Cdc2p phosphorylation sites. The data suggest that disruption of re-replication control by overexpression of Cdc6p in fission yeast is a consequence of sequestration of Cdc2p and Pop2p, two factors involved in the negative regulation of Rum1p, Cdc18p and potentially other replication proteins.     

Targeted destruction of DNA replication protein Cdc6 by cell death pathways in mammals and yeast

The highly conserved Cdc6 protein is required for initiation of eukaryotic DNA replication and, in yeast and Xenopus, for the coupling of DNA replication to mitosis. Herein, we show that human Cdc6 is rapidly destroyed by a p53-independent, proteasome-, and ubiquitin-dependent pathway during early stages of programmed cell death induced by the DNA-damaging drug adozelesin, or by a separate caspase-dependent pathway in cells undergoing apoptosis through an extrinsic pathway induced by tumor necrosis factor-alpha and cycloheximide. The proteasome-dependent pathway induced by adozelesin is conserved in the budding yeast Saccharomyces cerevisiae. The destruction of Cdc6 may be a primordial programmed death response that uncouples DNA replication from the cell division cycle, which is reinforced in metazoans by the evolution of caspases and p53.     

Characterization of the yeast Cdc7p/Dbf4p complex purified from insect cells. Its protein kinase activity is regulated by Rad53p

The yeast Saccharomyces cerevisiae Cdc7p/Dbf4p protein kinase complex was purified to near homogeneity from insect cells. The complex efficiently phosphorylated yeast Mcm2p and less efficiently the remaining Mcm proteins or other replication proteins. Significantly, when pretreated with alkaline phosphatase, Mcm2p became completely inactive as a substrate, suggesting that it must be phosphorylated by other protein kinase(s) to be a substrate for the Cdc7p/Dbf4p complex. Mutant Cdc7p/Dbf4p complexes containing either Cdc7-1p or Dbf4-1 approximately 5p were also partially purified from insect cells and characterized in vitro. Furthermore, the autonomously replicating sequence binding activity of various dbf4 mutants was also analyzed. These studies suggest that the autonomously replicating sequence-binding and Cdc7p protein kinase activation domains of Dbf4p collaborate to form an active Cdc7p/Dbf4p complex and function during S phase in S. cerevisiae. It is shown that Rad53p phosphorylates the Cdc7p/Dbf4p complex in vitro and that this phosphorylation greatly inhibits the kinase activity of Cdc7p/Dbf4p. This result suggests that Rad53p controls the initiation of chromosomal DNA replication by regulating the protein kinase activity associated with the Cdc7p/Dbf4p complex.     

Budding yeast Cdc6p induces re-replication in fission yeast by inhibition of SCF(Pop)-mediated proteolysis

In fission yeast, overexpression of the replication initiator protein Cdc18p induces re-replication, a phenotype characterized by continuous DNA synthesis in the absence of cell division. In contrast, overexpression of Cdc6p, the budding yeast homolog of Cdc18p, does not cause re-replication in S. cerevisiae. However, we have found that Cdc6p has the ability to induce re-replication in fission yeast. Cdc6p cannot functionally replace Cdc18p, but instead interferes with the proteolysis of both Cdc18p and Rum1p, the inhibitor of the protein kinase Cdc2p. This activity of Cdc6p is entirely contained within a short N-terminal peptide, which forms a tight complex with Cdc2p and the F-box/WD-repeat protein Sud1p/Pop2p, a component of the SCF^Pop ubiquitin ligase in fission yeast. These interactions are mediated by two distinct regions within the N-terminal region of Cdc6p and depend on the integrity of its Cdc2p phosphorylation sites. The data suggest that disruption of re-replication control by overexpression of Cdc6p in fission yeast is a consequence of sequestration of Cdc2p and Pop2p, two factors involved in the negative regulation of Rum1p, Cdc18p and potentially other replication proteins. Received: 29 April 1999 / Accepted: 27 June 1999