Multiple Replication Origins of Halobacterium sp. Strain NRC-1: Properties of the Conserved orc7-Dependent oriC1

The eukaryote-like DNA replication system of the model haloarchaeon Halobacterium NRC-1 is encoded within a circular chromosome and two large megaplasmids or minichromosomes, pNRC100 and pNRC200. We previously showed by genetic analysis that 2 (orc2 and orc10) of the 10 genes coding for Orc-Cdc6 replication initiator proteins were essential, while a third (orc7), located near a highly conserved autonomously replicating sequence, oriC1, was nonessential for cell viability. Here we used whole-genome marker frequency analysis (MFA) and found multiple peaks, indicative of multiple replication origins. The largest chromosomal peaks were located proximal to orc7 (oriC1) and orc10 (oriC2), and the largest peaks on the extrachromosomal elements were near orc9 (oriP1) in both pNRC100 and -200 and near orc4 (oriP2) in pNRC200. MFA of deletion strains containing different combinations of chromosomal orc genes showed that replication initiation at oriC1 requires orc7 but not orc6 and orc8. The initiation sites at oriC1 were determined by replication initiation point analysis and found to map divergently within and near an AT-rich element flanked by likely Orc binding sites. The oriC1 region, Orc binding sites, and orc7 gene orthologs were conserved in all sequenced haloarchaea. Serial deletion of orc genes resulted in the construction of a minimal strain containing not only orc2 and orc10 but also orc9. Our results suggest that replication in this model system is intriguing and more complex than previously thought. We discuss these results from the perspective of the replication strategy and evolution of haloarchaeal genomes.Archaea are of considerable interest due to their unusual phylogenetic position and the similarity of their information transfer system to that of eukaryotes. In particular, studies of DNA replication in archaea have revealed characteristics of both bacterial and eukaryotic systems (1). While genome sequencing has shown that archaeal and bacterial genomes are composed of a single or few circular chromosomes, comparative genomic studies have found that most components of the archaeal DNA replication machinery, such as the origin recognition proteins, DNA polymerases, helicases, and primases, are similar to eukaryotic proteins. The hybrid nature of archaeal DNA replication systems raises important questions regarding the mechanism by which they select an origin(s) for initiation and coordinate orderly DNA replication and segregation into daughter cells.Our understanding of DNA replication in archaea has thus far been based primarily on bioinformatic studies, with experimental analysis restricted to only a few tractable systems. An initial study of Pyrococcus species using GC (tetramer) skew analysis suggested that they use a single, unique origin of replication in their chromosomes. Subsequent [³H]uracil labeling analysis of Pyrococcus abyssi (21) showed that newly synthesized DNA mapped to the predicted replication origin region, which contained the only orc gene in the genome, a D family DNA polymerase gene, and a DNA sliding clamp loader subunit. In addition, two-dimensional gel analysis of replicating molecules confirmed the location of the DNA replication origin near the orc1 gene of P. abyssi, with predicted origin binding sequences and AT-rich DNA unwinding elements nearby (18). An investigation of DNA replication in Aeropyrum pernix used a combination of biochemical and two-dimensional gel electrophoresis and identified two potential sites of replication initiation, on opposite sides of the circular genome (14, 28). One of these sites (oriC1_Ap) contained four origin recognition boxes and an AT-rich region and was shown to be bound by the ORC1 gene. The other site (oriC2_Ap) contained repeat elements without an intervening AT-rich region and has been shown by two-dimensional gel electrophoresis to contain an active replication origin (28). An examination of replication in two Sulfolobus spp., Sulfolobus solfataricus and Sulfolobus acidocaldarius (16, 30), by use of a combination of bioinformatic and two-dimensional gel analysis and of marker frequency by use of DNA microarrays identified three well-separated replication origins per genome. Only two of the three origins were originally identified, due to their linkage to orc genes and conserved origin binding sequences, while the third was identified by marker frequency analysis (MFA). Using partially synchronized cells of S. acidocaldarius, the origins were shown to initiate DNA replication synchronously, indicating a highly coordinated and regulated process. Biochemical analysis has shown that either two or all three Orc proteins are able to bind to all Sulfolobus origins; however, binding at the third origin is considerably weaker (29). Replication origins were also recently identified in Methanothermobacter thermoautotrophicus (17).Our laboratory has been investigating DNA replication in a halophilic archaeon capable of growth at saturating NaCl concentrations. The model system, Halobacterium sp. strain NRC-1, was one of the earliest archaeal genomes to be sequenced (23) and provided a DNA knockout method, utilizing the selectable and counterselectable ura3 gene, for genetic analysis (25). The NRC-1 genome was found to be organized into a 2-Mbp chromosome and two large and partially redundant extrachromosomal elements, pNRC100 and pNRC200. The genome sequence showed that the orc gene family was highly expanded, with four genes (orc6, -7, -8, and -10) distributed in the chromosome and six genes (orc1, -2, -3, -4, -5, and -9) in pNRC200, one of which (orc9) was also present in pNRC100. Three rep genes thought to be important for replication initiation were present in one (repJ in pNRC100) or both (repH and repI) of the extrachromosomal elements. Regions near two of these genes, orc7 and repH, were shown to harbor autonomous replicating ability and to contain inverted repeat sequences (IRs) and an AT-rich presumptive DNA unwinding region detectable by χ² analysis (3, 22). Additionally, GC/oligomer skew analyses of Halobacterium sp. strain NRC-1 showed multiple inflection points in the chromosome, suggestive of multiple replication origins in this strain (15, 34).Halobacterium sp. strain NRC-1 is the only archaeal system where gene mutation analysis has established which predicted DNA replication genes are essential to cells (2). As expected, two DNA polymerases (one B family and one D family polymerase), the MCM DNA helicase, DNA primase (Pri1/Pri2), the sliding clamp (PCNA), and flap endonuclease (Rad2) were all found to be essential. However, one B family DNA polymerase gene and 8 of the 10 orc and cdc6 genes, including the orc7 gene, were found to be nonessential by deletion analysis. Only the orc2 gene in pNRC200 and the orc10 gene in the chromosome were found to be essential, suggesting a critical role(s) for these genes in DNA replication.In this study, we used a combination of MFA, employing whole-genome DNA microarrays, the ura3-based gene knockout method, and replication initiation point (RIP) analysis to further investigate DNA replication in Halobacterium sp. strain NRC-1. Our results indicate that initiation of DNA replication in NRC-1 is more complex than originally anticipated, with multiple origins likely present on the chromosome and the extrachromosomal elements.     

Cyanobacteria toxins in the Salton Sea

Background

Sequenced archaeal genomes contain a variety of bacterial and eukaryotic DNA repair gene homologs, but relatively little is known about how these microorganisms actually perform DNA repair. At least some archaea, including the extreme halophile Halobacterium sp. NRC-1, are able to repair ultraviolet light (UV) induced DNA damage in the absence of light-dependent photoreactivation but this 'dark' repair capacity remains largely uncharacterized. Halobacterium sp. NRC-1 possesses homologs of the bacterial uvrA, uvrB, and uvrC nucleotide excision repair genes as well as several eukaryotic repair genes and it has been thought that multiple DNA repair pathways may account for the high UV resistance and dark repair capacity of this model halophilic archaeon. We have carried out a functional analysis, measuring repair capability in uvrA, uvrB and uvrC deletion mutants.

Results

Deletion mutants lacking functional uvrA, uvrB or uvrC genes, including a uvrA uvrC double mutant, are hypersensitive to UV and are unable to remove cyclobutane pyrimidine dimers or 6–4 photoproducts from their DNA after irradiation with 150 J/m² of 254 nm UV-C. The UV sensitivity of the uvr mutants is greatly attenuated following incubation under visible light, emphasizing that photoreactivation is highly efficient in this organism. Phylogenetic analysis of the Halobacterium uvr genes indicates a complex ancestry.

Conclusion

Our results demonstrate that homologs of the bacterial nucleotide excision repair genes uvrA, uvrB, and uvrC are required for the removal of UV damage in the absence of photoreactivating light in Halobacterium sp. NRC-1. Deletion of these genes renders cells hypersensitive to UV and abolishes their ability to remove cyclobutane pyrimidine dimers and 6–4 photoproducts in the absence of photoreactivating light. In spite of this inability to repair UV damaged DNA, uvrA, uvrB and uvrC deletion mutants are substantially less UV sensitive than excision repair mutants of E. coli or yeast. This may be due to efficient damage tolerance mechanisms such as recombinational lesion bypass, bypass DNA polymerase(s) and the existence of multiple genomes in Halobacterium. Phylogenetic analysis provides no clear evidence for lateral transfer of these genes from bacteria to archaea.     

Genetic and physical mapping of DNA replication origins in Haloferax volcanii

The halophilic archaeon Haloferax volcanii has a multireplicon genome, consisting of a main chromosome, three secondary chromosomes, and a plasmid. Genes for the initiator protein Cdc6/Orc1, which are commonly located adjacent to archaeal origins of DNA replication, are found on all replicons except plasmid pHV2. However, prediction of DNA replication origins in H. volcanii is complicated by the fact that this species has no less than 14 cdc6/orc1 genes. We have used a combination of genetic, biochemical, and bioinformatic approaches to map DNA replication origins in H. volcanii. Five autonomously replicating sequences were found adjacent to cdc6/orc1 genes and replication initiation point mapping was used to confirm that these sequences function as bidirectional DNA replication origins in vivo. Pulsed field gel analyses revealed that cdc6/orc1-associated replication origins are distributed not only on the main chromosome (2.9 Mb) but also on pHV1 (86 kb), pHV3 (442 kb), and pHV4 (690 kb) replicons. Gene inactivation studies indicate that linkage of the initiator gene to the origin is not required for replication initiation, and genetic tests with autonomously replicating plasmids suggest that the origin located on pHV1 and pHV4 may be dominant to the principal chromosomal origin. The replication origins we have identified appear to show a functional hierarchy or differential usage, which might reflect the different replication requirements of their respective chromosomes. We propose that duplication of H. volcanii replication origins was a prerequisite for the multireplicon structure of this genome, and that this might provide a means for chromosome-specific replication control under certain growth conditions. Our observations also suggest that H. volcanii is an ideal organism for studying how replication of four replicons is regulated in the context of the archaeal cell cycle.     

Characterization of an essential Orc2p-associated factor that plays a role in DNA replication.

The Saccharomyces cerevisiae Orc2 protein is a subunit of the origin recognition complex, ORC, which binds in a sequence-specific manner to yeast origins of DNA replication. With screens for orc2-1 synthetic lethal mutations and Orc2p two-hybrid interactors, a novel Orc2p-associated factor (Oaf1p) was identified. OAF1 is essential, its gene product is localized to the nucleus, and an oaf1 temperature-sensitive mutant arrests as large budded cells with a single nucleus. The mutant oaf1-2, isolated in the synthetic lethal screen, loses plasmids containing a single origin of DNA replication at a high rate, but it maintains plasmids carrying multiple potential origins of DNA replication. In addition, the OAF1 gene product tagged with the hemagglutinin antigen epitope binds to a DNA affinity column containing covalently linked tandem repeats of an essential origin element. These results suggest a role for OAFI in the initiation of DNA replication. Mutant alleles of cdc7 and cdc14 were also isolated in the orc2-1 synthetic lethal screen. Cdc7p, like Oaf1p, also interacts with Orc2p in two-hybrid assays.     

Biochemical analysis of components of the pre-replication complex of Archaeoglobus fulgidus

The eukaryotic pre-replication complex is assembled at replication origins in a reaction called licensing. Licensing involves the interactions of a variety of proteins including the origin recognition complex (ORC), Cdc6 and the Mcm2-7 helicase, homologues of which are also found in archaea. The euryarchaeote Archaeoglobus fulgidus encodes two genes with homology to Orc/Cdc6 and a single Mcm homologue. The A.fulgidus Mcm protein and one Orc/Cdc6 homologue have been purified and investigated in vitro. The Mcm protein is an ATP-dependent, hexameric helicase that can unwind between 200 and 400 bp of duplex DNA. Deletion of 112 amino acids from the N-terminus of A.f Mcm produced a protein, which was still capable of forming a hexamer, was competent in DNA binding and was able to unwind at least 1 kb of duplex DNA. The purified Orc/Cdc6 homologue was also able to bind DNA. Both Mcm and Orc/Cdc6 show a preference for specific DNA structures, namely molecules containing a single stranded bubble that mimics early replication intermediates. Nuclease protection showed that the binding sites for Mcm and Orc/Cdc6 overlap. The Orc/Cdc6 protein bound more tightly to these substrates and was able to displace pre-bound Mcm hexamer.     

Genomewide and biochemical analyses of DNA-binding activity of Cdc6/Orc1 and Mcm proteins in Pyrococcus sp

The origin of DNA replication (oriC) of the hyperthermophilic archaeon Pyrococcus abyssi contains multiple ORB and mini-ORB repeats that show sequence similarities to other archaeal ORB (origin recognition box). We report here that the binding of Cdc6/Orc1 to a 5kb region containing oriC in vivo was highly specific both in exponential and stationary phases, by means of chromatin immunoprecipitation coupled with hybridization on a whole genome microarray (ChIP-chip). The oriC region is practically the sole binding site for the Cdc6/Orc1, thereby distinguishing oriC in the 1.8M bp genome. We found that the 5kb region contains a previously unnoticed cluster of ORB and mini-ORB repeats in the gene encoding the small subunit (dp1) for DNA polymerase II (PolD). ChIP and the gel retardation analyses further revealed that Cdc6/Orc1 specifically binds both of the ORB clusters in oriC and dp1. The organization of the ORB clusters in the dp1 and oriC is conserved during evolution in the order Thermococcales, suggesting a role in the initiation of DNA replication. Our ChIP-chip analysis also revealed that Mcm alters the binding specificity to the oriC region according to the growth phase, consistent with its role as a licensing factor.     

MutS and MutL Are Dispensable for Maintenance of the Genomic Mutation Rate in the Halophilic Archaeon Halobacterium salinarum NRC-1

Background

The genome of the halophilic archaeon Halobacterium salinarum NRC-1 encodes for homologs of MutS and MutL, which are key proteins of a DNA mismatch repair pathway conserved in Bacteria and Eukarya. Mismatch repair is essential for retaining the fidelity of genetic information and defects in this pathway result in the deleterious accumulation of mutations and in hereditary diseases in humans.

Methodology/Principal Findings

We calculated the spontaneous genomic mutation rate of H. salinarum NRC-1 using fluctuation tests targeting genes of the uracil monophosphate biosynthesis pathway. We found that H. salinarum NRC-1 has a low incidence of mutation suggesting the presence of active mechanisms to control spontaneous mutations during replication. The spectrum of mutational changes found in H. salinarum NRC-1, and in other archaea, appears to be unique to this domain of life and might be a consequence of their adaption to extreme environmental conditions. In-frame targeted gene deletions of H. salinarum NRC-1 mismatch repair genes and phenotypic characterization of the mutants demonstrated that the mutS and mutL genes are not required for maintenance of the observed mutation rate.

Conclusions/Significance

We established that H. salinarum NRC-1 mutS and mutL genes are redundant to an alternative system that limits spontaneous mutation in this organism. This finding leads to the puzzling question of what mechanism is responsible for maintenance of the low genomic mutation rates observed in the Archaea, which for the most part do not have MutS and MutL homologs.     

Characterization of the Replication Initiator Orc1/Cdc6 from the Archaeon Picrophilus torridus

Eukaryotic DNA replication is preceded by the assembly of prereplication complexes (pre-RCs) at or very near origins in G₁ phase, which licenses origin firing in S phase. The archaeal DNA replication machinery broadly resembles the eukaryal apparatus, though simpler in form. The eukaryotic replication initiator origin recognition complex (ORC), which serially recruits Cdc6 and other pre-RC proteins, comprises six components, Orc1-6. In archaea, a single gene encodes a protein similar to both the eukaryotic Cdc6 and the Orc1 subunit of the eukaryotic ORC, with most archaea possessing one to three Orc1/Cdc6 orthologs. Genome sequence analysis of the extreme acidophile Picrophilus torridus revealed a single Orc1/Cdc6 (PtOrc1/Cdc6). Biochemical analyses show MBP-tagged PtOrc1/Cdc6 to preferentially bind ORB (origin recognition box) sequences. The protein hydrolyzes ATP in a DNA-independent manner, though DNA inhibits MBP-PtOrc1/Cdc6-mediated ATP hydrolysis. PtOrc1/Cdc6 exists in stable complex with PCNA in Picrophilus extracts, and MBP-PtOrc1/Cdc6 interacts directly with PCNA through a PIP box near its C terminus. Furthermore, PCNA stimulates MBP-PtOrc1/Cdc6-mediated ATP hydrolysis in a DNA-dependent manner. This is the first study reporting a direct interaction between Orc1/Cdc6 and PCNA in archaea. The bacterial initiator DnaA is converted from an active to an inactive form by ATP hydrolysis, a process greatly facilitated by the bacterial ortholog of PCNA, the β subunit of Pol III. The stimulation of PtOrc1/Cdc6-mediated ATP hydrolysis by PCNA and the conservation of PCNA-interacting protein motifs in several archaeal PCNAs suggest the possibility of a similar mechanism of regulation existing in archaea. This mechanism may involve other yet to be identified archaeal proteins.     

Functional differentiation and cooperative interaction between two eukaryote-like archaeal Orc1/Cdc6 proteins on the replication origin

The DNA replication apparatus of archaea represents a core version of that in eukaryotes. Archaeal Orc1/Cdc6s can be an integral component in the replication machineries cooperatively regulating DNA replication. We investigated the DNA-binding activities of two eukaryote-like Orc1/Cdc6 proteins (SsoCdc6-1 and -2) and interactions between them on the different structural duplex DNA substrates derived from oriC1 of Sulfolobus solfataricus. The results showed that two Orc1/Cdc6 proteins stimulated mutual DNA-binding activities at lower concentrations and formed bigger SsoCdc6-1/SsoCdc6-2/DNA complex at higher concentrations. Furthermore, SsoCdc6-2 stimulated the DNA-binding activity of SsoMCM and demonstrated a high affinity to the 5-forked DNA. In contrast, SsoCdc6-1 inhibited the binding of SsoMCM and demonstrated better affinity to the sequence-specific blunt DNA substrate. Finally, we found that the two proteins physically interacted with each other and with SsoMCM. Thus, the two Orc1/Cdc6 proteins were functionally different, but they may keep the coordinated interaction on the replication origin.     

Yeast UBL-UBA proteins have partially redundant functions in cell cycle control

Abp1, and the closely related Cbh1 and Cbh2 are homologous to the human centromere-binding protein CENP-B that has been implicated in the assembly of centromeric heterochromatin. Fission yeast cells lacking Abp1 show an increase in mini-chromosome instability suggesting that Abp1 is important for chromosome segregation and/or DNA synthesis. Here we show that Abp1 interacts with the DNA replication protein Cdc23 (MCM10) in a two-hybrid assay, and that the Δabp1 mutant displays a synthetic phenotype with a cdc23 temperature-sensitive mutant. Moreover, genetic interactions were also observed between abp1 ⁺ and four additional DNA replication initiation genes cdc18 ⁺, cdc21 ⁺, orc1 ⁺, and orc2 ⁺. Interestingly, we find that S phase is delayed in cells deleted for abp1 ⁺ when released from a G1 block. However, no delay is observed when cells are released from an early S phase arrest induced by hydroxyurea suggesting that Abp1 functions prior to, or coincident with, the initiation of DNA replication.     

The human homolog of Saccharomyces cerevisiae Mcm10 interacts with replication factors and dissociates from nuclease-resistant nuclear structures in G(2) phase

Mcm10 (Dna43), first identified in Saccharomyces cerevisiae, is an essential protein which functions in the initiation of DNA synthesis. Mcm10 is a nuclear protein that is localized to replication origins and mediates the interaction of the Mcm2–7 complex with replication origins. We identified and cloned a human cDNA whose product was structurally homologous to the yeast Mcm10 protein. Human Mcm10 (HsMcm10) is a 98-kDa protein of 874 amino acids which shows 23 and 21% overall similarity to Schizosaccharomyces pombe Cdc23 and S.cerevisiae Mcm10, respectively. The messenger RNA level of HsMcm10 increased at the G₁/S-boundary when quiescent human NB1–RGB cells were induced to proliferate as is the case of many replication factors. HsMcm10 associated with nuclease-resistant nuclear structures throughout S phase and dissociated from it in G₂ phase. HsMcm10 associated with human Orc2 protein when overexpressed in COS-1 cells. HsMcm10 also interacted with Orc2, Mcm2 and Mcm6 proteins in the yeast two-hybrid system. These results suggest that HsMcm10 may function in DNA replication through the interaction with Orc and Mcm2–7 complexes.     

The regulatory function of N-terminal AAA+ ATPase domain of eukaryote-like archaeal Orc1/Cdc6 protein during DNA replication initiation

Archaeal replication machinery represents a core version of this in eukaryotes. The crenarchaeon Sulfolobus solfataricus has the potential to be a powerful model system to understand the central mechanism of eukaryotic DNA replication because it contains three active origins of replication and three eukaryote-like Orc1/Cdc6 proteins (SsoCdc6-1, SsoCdc6-2, and SsoCdc6-3). In this study, we investigate the DNA-binding activities of the N-terminal AAA⁺ ATPase domains of these Orc1/Cdc6 proteins, including their functional interactions with the other SsoCdc6 proteins, on duplex DNA substrates derived from the origins of S. solfataricus. We showed that the ATPase domain of SsoCdc6-2 retained to a great extent the origin DNA-binding activity, and likewise maintained its stimulating effect on SsoCdc6-3. Second, the ATPase domain of SsoCdc6-1, which also stimulated the DNA-binding ability of SsoCdc6-3, demonstrated a significantly improved DNA-binding activity at the forked substrate, but only showed a very weak ability towards the blunt DNA. Third, the ATPase domain of SsoCdc6-3, although having lost much of its DNA-binding activity from the origin, inhibited both SsoCdc6-1 and SsoCdc6-2. These imply that the N-terminal AAA⁺ ATPase domain of archaeal Orc1/Cdc6 protein could be differentially involved in origin recognition during DNA replication initiation even if lacking conventional C-terminal winged helix DNA-binding elements. Our findings further propose that conserved AAA⁺ ATPase domains of Orc1/Cdc6 proteins determine their defined and coordinated functions not only in the archaeon species but also in eukaryotes during the early events of DNA replication.     

Proteomic analysis of acidic chaperones, and stress proteins in extreme halophile Halobacterium NRC-1: a comparative proteomic approach to study heat shock response

Background  

Halobacterium sp. NRC-1 is an extremely halophilic archaeon and has adapted to optimal growth under conditions of extremely high salinity. Its proteome is highly acidic with a median pI of 4.9, a unique characteristic which helps the organism to adapt high saline environment. In the natural growth environment, Halobacterium NRC-1 encounters a number of stressful conditions including high temperature and intense solar radiation, oxidative and cold stress. Heat shock proteins and chaperones play indispensable roles in an organism's survival under many stress conditions. The aim of this study was to develop an improved method of 2-D gel electrophoresis with enhanced resolution of the acidic proteome, and to identify proteins with diverse cellular functions using in-gel digestion and LC-MS/MS and MALDI-TOF approach.     

Comparative EST analysis provides insights into the basal aquatic fungus Blastocladiella emersonii

Background

Whole genome amplification is an increasingly common technique through which minute amounts of DNA can be multiplied to generate quantities suitable for genetic testing and analysis. Questions of amplification-induced error and template bias generated by these methods have previously been addressed through either small scale (SNPs) or large scale (CGH array, FISH) methodologies. Here we utilized whole genome sequencing to assess amplification-induced bias in both coding and non-coding regions of two bacterial genomes. Halobacterium species NRC-1 DNA and Campylobacter jejuni were amplified by several common, commercially available protocols: multiple displacement amplification, primer extension pre-amplification and degenerate oligonucleotide primed PCR. The amplification-induced bias of each method was assessed by sequencing both genomes in their entirety using the 454 Sequencing System technology and comparing the results with those obtained from unamplified controls.

Results

All amplification methodologies induced statistically significant bias relative to the unamplified control. For the Halobacterium species NRC-1 genome, assessed at 100 base resolution, the D-statistics from GenomiPhi-amplified material were 119 times greater than those from unamplified material, 164.0 times greater for Repli-G, 165.0 times greater for PEP-PCR and 252.0 times greater than the unamplified controls for DOP-PCR. For Campylobacter jejuni, also analyzed at 100 base resolution, the D-statistics from GenomiPhi-amplified material were 15 times greater than those from unamplified material, 19.8 times greater for Repli-G, 61.8 times greater for PEP-PCR and 220.5 times greater than the unamplified controls for DOP-PCR.

Conclusion

Of the amplification methodologies examined in this paper, the multiple displacement amplification products generated the least bias, and produced significantly higher yields of amplified DNA.