Extremophiles in a changing world.

Extremophiles and their products have been a major focus of research interest for over 40 years. Through this period, studies of these organisms have contributed hugely to many aspects of the fundamental and applied sciences, and to wider and more philosophical issues such as the origins of life and astrobiology. Our understanding of the cellular adaptations to extreme conditions (such as acid, temperature, pressure and more), of the mechanisms underpinning the stability of macromolecules, and of the subtleties, complexities and limits of fundamental biochemical processes has been informed by research on extremophiles. Extremophiles have also contributed numerous products and processes to the many fields of biotechnology, from diagnostics to bioremediation. Yet, after 40 years of dedicated research, there remains much to be discovered in this field. Fortunately, extremophiles remain an active and vibrant area of research. In the third decade of the twenty-first century, with decreasing global resources and a steadily increasing human population, the world's attention has turned with increasing urgency to issues of sustainability. These global concerns were encapsulated and formalized by the United Nations with the adoption of the 2030 Agenda for Sustainable Development and the presentation of the seventeen Sustainable Development Goals (SDGs) in 2015. In the run-up to 2030, we consider the contributions that extremophiles have made, and will in the future make, to the SDGs.

Evaluation of microbial qPCR workflows using engineered Saccharomyces cerevisiae.

AIMS: We describe the development and interlaboratory study of modified Saccharomyces cerevisiae as a candidate material to evaluate a full detection workflow including DNA extraction and quantitative polymerase chain reaction (qPCR). METHODS AND RESULTS: S. cerevisiae NE095 was prepared by stable insertion of DNA sequence External RNA Control Consortium-00095 into S. cerevisiae BY4739 to convey selectivity. For the interlaboratory study, a binomial regression model was used to select three cell concentrations, high (4 × 10(7) cells ml(-1)), intermediate (4 × 10(5) cells ml(-1)) and low (4 × 10(3) cells ml(-1)), and the number of samples per concentration. Seven participants, including potential end users, had combined rates of positive qPCR detection (quantification cycle <37) of 100%, 40%, and 0% for high, intermediate, and low concentrations, respectively. CONCLUSIONS: The NE095 strain was successfully detected by all participants, with the high concentration indicating a potential target concentration for a reference material. SIGNIFICANCE AND IMPACT OF THE STUDY: The engineered yeast has potential to support measurement assurance for the analytical process of qPCR, encompassing the method, equipment, and operator, to increase confidence in results and better inform decision-making in areas of applied microbiology. This material can also support process assessment for other DNA-based detection technologies.

Atomistic ensemble modeling and small-angle neutron scattering of intrinsically disordered protein complexes: applied to minichromosome maintenance protein.

The minichromosome maintenance (MCM) proteins are thought to function as the replicative helicases in archaea and eukarya. In this work we determined the solution structure of the N-terminal portion of the MCM complex from the archaeon Methanothermobacter thermautotrophicus (N-mtMCM) in the presence and absence of DNA using small-angle neutron scattering (SANS). N-mtMCM is a multimeric protein complex that consists of 12 monomers, each of which contains three distinct domains and two unstructured regions. Using an all-atom approach incorporating modern force field and Monte Carlo methods to allow the unstructured regions of each monomer to be varied independently, we generated an ensemble of biologically relevant structures for the complex. An examination of the subsets of structures that were most consistent with the SANS data revealed that large movements between the three domains of N-mtMCM can occur in solution. Furthermore, changes in the SANS curves upon DNA binding could be correlated to the motion of a particular N-mtMCM domain. These results provide structural support to the previously reported biochemical observations that large domain motions are required for the activation of the MCM helicase in archaea and eukarya. The methods developed here for N-mtMCM solution structure modeling should be suitable for other large protein complexes with unstructured flexible regions.

The zinc finger domain of the archaeal minichromosome maintenance protein is required for helicase activity.

The minichromosome maintenance (MCM) proteins, a family of six conserved polypeptides found in all eukaryotes, are essential for DNA replication. The archaeon Methanobacterium thermoautotrophicum Delta H contains a single homologue of MCM with biochemical properties similar to those of the eukaryotic enzyme. The amino acid sequence of the archaeal protein contains a putative zinc-binding domain of the CX(2)CX(n)CX(2)C (C(4)) type. In this study, the roles of the zinc finger domain in MCM function were examined using recombinant wild-type and mutant proteins expressed and purified from Escherichia coli. The protein with a mutation in the zinc motif forms a dodecameric complex similar to the wild-type enzyme. The mutant enzyme, however, is impaired in DNA-dependent ATPase activity and single-stranded DNA binding, and it does not possess helicase activity. These results illustrate the importance of the zinc-binding domain for archaeal MCM function and suggest a role for zinc binding in the eukaryotic MCM complex as well, since four out of the six eukaryotic MCM proteins contain a similar zinc-binding motif.

Autophosphorylation of archaeal Cdc6 homologues is regulated by DNA.

The initiator protein Cdc6 (Cdc18 in fission yeast) plays an essential role in the initiation of eukaryotic DNA replication. In yeast the protein is expressed before initiation of DNA replication and is thought to be essential for loading of the helicase onto origin DNA. The biochemical properties of the protein, however, are largely unknown. Using three archaeal homologues of Cdc6, it was found that the proteins are autophosphorylated on Ser residues. The winged-helix domain at the C terminus of Cdc6 interacts with DNA, which apparently regulates the autophosphorylation reaction. Yeast Cdc18 was also found to autophosphorylate, suggesting that this function of Cdc6 may play a widely conserved and essential role in replication initiation.

Mechanism of beta clamp opening by the delta subunit of Escherichia coli DNA polymerase III holoenzyme.

The beta sliding clamp encircles the primer-template and tethers DNA polymerase III holoenzyme to DNA for processive replication of the Escherichia coli genome. The clamp is formed via hydrophobic and ionic interactions between two semicircular beta monomers. This report demonstrates that the beta dimer is a stable closed ring and is not monomerized when the gamma complex clamp loader (gamma(3)delta(1)delta(1)chi(1)psi(1)) assembles the beta ring around DNA. delta is the subunit of the gamma complex that binds beta and opens the ring; it also does not appear to monomerize beta. Point mutations were introduced at the beta dimer interface to test its structural integrity and gain insight into its interaction with delta. Mutation of two residues at the dimer interface of beta, I272A/L273A, yields a stable beta monomer. We find that delta binds the beta monomer mutant at least 50-fold tighter than the beta dimer. These findings suggest that when delta interacts with the beta clamp, it binds one beta subunit with high affinity and utilizes some of that binding energy to perform work on the dimeric clamp, probably cracking one dimer interface open.

Characterization of an ATP-dependent DNA ligase from the thermophilic archaeon Methanobacterium thermoautotrophicum.

We report the production, purification and characterization of a DNA ligase encoded by the thermophilic archaeon Methanobacterium thermoautotrophicum. The 561 amino acid MTH: ligase catalyzed strand-joining on a singly nicked DNA in the presence of a divalent cation (magnesium, manganese or cobalt) and ATP (K(m) 1.1 microM). dATP can substitute for ATP, but CTP, GTP, UTP and NAD(+) cannot. MTH: ligase activity is thermophilic in vitro, with optimal nick-joining at 60 degrees C. Mutational analysis of the conserved active site motif I (KxDG) illuminated essential roles for Lys251 and Asp253 at different steps of the ligation reaction. Mutant K251A is unable to form the covalent ligase-adenylate intermediate (step 1) and hence cannot seal a 3'-OH/5'-PO(4) nick. Yet, K251A catalyzes phosphodiester bond formation at a pre-adenylated nick (step 3). Mutant D253A is active in ligase-adenylate formation, but defective in activating the nick via formation of the DNA-adenylate intermediate (step 2). D253A is also impaired in phosphodiester bond formation at a pre-adenylated nick. A profound step 3 arrest, with accumulation of high levels of DNA-adenylate, could be elicited for the wild-type MTH: ligase by inclusion of calcium as the divalent cation cofactor. MTH: ligase sediments as a monomer in a glycerol gradient. Structure probing by limited proteolysis suggested that MTH: ligase is a tightly folded protein punctuated by a surface-accessible loop between nucleotidyl transferase motifs III and IIIa.

Proliferating cell nuclear antigen as the cell cycle sensor for an HLA-derived peptide blocking T cell proliferation.

Synthetic peptides corresponding to structural regions of HLA molecules are novel immunosuppressive agents. A peptide corresponding to residues 65-79 of the alpha-chain of HLA-DQA03011 (DQ65-79) blocks cell cycle progression from early G1 to the G1 restriction point, which inhibits cyclin-dependent kinase-2 activity and phosphorylation of the retinoblastoma protein. A yeast two-hybrid screen identified proliferating cell nuclear Ag (PCNA) as a cellular ligand for this peptide, whose interaction with PCNA was further confirmed by in vitro biochemistry. Electron microscopy demonstrates that the DQ65-79 peptide enters the cell and colocalizes with PCNA in the T cell nucleus in vivo. Binding of the DQ65-79 peptide to PCNA did not block polymerase delta (pol delta)-dependent DNA replication in vitro. These findings support a key role for PCNA as a sensor of cell cycle progression and reveal an unanticipated function for conserved regions of HLA molecules.

Fidelity of eucaryotic DNA polymerase delta holoenzyme from Schizosaccharomyces pombe.

The fidelity of Schizosaccharomyces pombe DNA polymerase delta was measured in the presence or absence of its processivity subunits, proliferating cell nuclear antigen (PCNA) sliding clamp and replication factor C (RFC) clamp-loading complex, using a synthetic 30-mer primer/100-mer template. Synthesis by pol delta alone was distributive. Processive synthesis occurred in the presence of PCNA, RFC, and Escherichia coli single strand DNA-binding protein (SSB) and required the presence of ATP. "Passive" self-loading of PCNA onto DNA takes place in the absence of RFC, in an ATP-independent reaction, which was strongly inhibited by SSB. The nucleotide substitution error rate for pol delta holoenzyme (HE) (pol delta + PCNA + RFC) was 4.6 x 10(-4) for T.G mispairs, 5.3 x 10(-5) for G.G mispairs, and 4.5 x 10(-6) for A.G mispairs. The T.G misincorporation frequency for pol delta without the accessory proteins was unchanged. The fidelity of pol delta HE was between 1 and 2 orders of magnitude lower than that measured for the E. coli pol III HE at the same template position. This relatively low fidelity was caused by inefficient proofreading by the S. pombe polymerase-associated proofreading exonuclease. The S. pombe 3'-exonuclease activity was also extremely inefficient in excising primer-3'-terminal mismatches in the absence of dNTP substrates and in hydrolyzing single-stranded DNA. A comparison of pol delta HE with E. coli pol IIIalpha HE (lacking the proofreading exonuclease subunit) showed that both holoenzymes exhibit similar error rates for each mispair.

A unique organization of the protein subunits of the DNA polymerase clamp loader in the archaeon Methanobacterium thermoautotrophicum deltaH.

Replication factor C (RFC, also called activator 1), in conjunction with proliferating cell nuclear antigen (PCNA), is responsible for processive DNA synthesis catalyzed by the eukaryotic replicative DNA polymerases delta and epsilon. Here we report the isolation and characterization of homologues of RFC and PCNA from the archaeon, Methanobacterium thermoautotrophicum DeltaH. In contrast to the five subunit RFC complex isolated from eukaryotic cells, the mthRFC contains only two subunits. The two genes encoding the RFC subunits called, mthRFC1 and mthRFC3, were cloned, and the proteins (54.4 and 36.8 kDa, respectively) were overexpressed in Escherichia coli and purified individually and as a complex. The gene encoding PCNA was also cloned, and the protein was purified after overexpression in E. coli. Based on sizing column elution and subunit composition, the mthRFC complex appears to be a hexamer consisting of two mthRFC1 protomers and four mthRFC3 protomers. Although mthRFC differs in organization from its eukaryotic counterpart, it was shown to be functionally similar to eukaryotic RFC in: (i) catalyzing DNA-dependent ATP hydrolysis; (ii) binding preferentially to DNA primer ends; (iii) loading mthPCNA onto singly nicked circular DNA; and (iv) supporting mthPolB-catalyzed PCNA-dependent DNA chain elongation. The importance and roles of RFC and PCNA in M. thermoautotrophicum DeltaH replication are discussed.

Structure and activity associated with multiple forms of Schizosaccharomyces pombe DNA polymerase delta.

DNA polymerase delta (Pol delta) isolated from Schizosaccharomyces pombe (sp) consists of at least four subunits, Pol3, Cdc1, Cdc27, and Cdm1. We have reconstituted the four-subunit complex by simultaneously expressing these polypeptides in baculovirus-infected insect cells. The properties of the purified cloned spPol delta were identical to the native spPol delta isolated from S. pombe cells. In addition, we also isolated a three-subunit complex containing Pol3, Cdc1, and Cdm1. Both three- and four-subunit complexes required replication factor C and proliferating cell nuclear antigen for DNA replication. However, in the presence of low levels of polymerase complexes, the three-subunit complex was less efficient than the four-subunit complex in supporting DNA replication. The inefficient synthesis of DNA by the three-subunit complex can be remedied by the addition of Cdc27, the subunit missing in the three-subunit complex. Gel filtration analysis demonstrated that the three-subunit complex is a monomer of the heterotrimer (Pol3, Cdc1, and Cdm1) and that the four-subunit complex is a dimer of the heterotetramer (Pol3, Cdc1, Cdc27, and Cdm1), similar to the structure of native spPol delta. We have further shown that Cdc1 and Cdc27 interact to form a heterodimeric complex. Gel filtration studies indicate that the structure of this complex is dimeric. These observations suggest that the Cdc27 subunit may play an important role contributing to the dimerization of Pol delta.

DNA replication in the third domain (of life).

DNA replication is the process underlying evolution and the propagation of living organisms. Since the discovery of DNA-dependent DNA polymerases more than 40 years ago, the mechanisms governing DNA replication have been extensively studied in bacteria and eukarya. During the last several years, these studies have been extended to the third domain of life, the archaea. Although archaea are prokaryotes, their replication machinery and the proteins participating in the initiation of DNA replication are more similar to those found in eukarya than bacteria. It appears, however, that replication in archaea is a simpler version of the eukaryotic one as fewer polypeptides participate in each phase of the replication process. The archaeal replication apparatus also has several unique features not found in eukaryotic organisms. Furthermore, like bacteria, members of this domain thrive under a broad range of environmental conditions including extreme temperature, high salt, pH, etc. Thus, the replication machinery had to adapt to these extreme conditions. This article summarizes our current understanding of the mechanisms governing DNA replication in archaea and highlights similarities and differences between archaeal replication and that of bacteria and eukarya.

The single minichromosome maintenance protein of Methanobacterium thermoautotrophicum DeltaH contains DNA helicase activity.

Previous studies have identified an ATP-dependent DNA helicase activity intrinsic to the human minichromosome maintenance (MCM) complex, composed of MCM subunits 4, 6, and 7 [Ishimi, Y. (1997) J. Biol. Chem. 272, 24508-24513]. In contrast to the presence of multiple MCM genes (at least six) in eukaryotes, the archaeon Methanobacterium thermoautotrophicum DeltaH (mth) genome contains a single open reading frame coding for an MCM protein. In this study we report the isolation of the mthMCM protein overexpressed in Escherichia coli. The purified recombinant protein was found to exist in both multimeric ( approximately 10(3) kDa) and monomeric (76 kDa) forms. Both forms of the protein bind to single-stranded DNA, hydrolyze ATP in the presence of DNA, and possess 3'-to-5' ATP-dependent DNA helicase activities. Thus, a single mthMCM protein contains biochemical properties identical to those associated with the eukaryotic MCM4, -6, and -7 complex. These results suggest that the characterization of the mthMCM protein and its multiple forms may contribute to our understanding of the role of MCM helicase activity in eukaryotic chromosomal DNA replication.

Multiple competition reactions for RPA order the assembly of the DNA polymerase delta holoenzyme.

Processive extension of DNA in eukaryotes requires three factors to coordinate their actions. First, DNA polymerase alpha-primase synthesizes the primed site. Then replication factor C loads a proliferating cell nuclear antigen (PCNA) clamp onto the primer. Following this, DNA polymerase delta assembles with PCNA for processive extension. This report shows that these proteins each bind the primed site tightly and trade places in a highly coordinated fashion such that the primer terminus is never left free of protein. Replication protein A (RPA), the single-stranded DNA-binding protein, forms a common touchpoint for each of these proteins and they compete with one another for it. Thus these protein exchanges are driven by competition-based protein switches in which two proteins vie for contact with RPA.

Isolation and characterization of a split B-type DNA polymerase from the archaeon Methanobacterium thermoautotrophicum deltaH.

We describe here the isolation and characterization of a B-type DNA polymerase (PolB) from the archaeon Methanobacterium thermoautotrophicum DeltaH. Uniquely, the catalytic domains of M. thermoautotrophicum PolB are encoded from two different genes, a feature that has not been observed as yet in other polymerases. The two genes were cloned, and the proteins were overexpressed in Escherichia coli and purified individually and as a complex. We demonstrate that both polypeptides are needed to form the active polymerase. Similar to other polymerases constituting the B-type family, PolB possesses both polymerase and 3'-5' exonuclease activities. We found that a homolog of replication protein A from M. thermoautotrophicum inhibits the PolB activity. The inhibition of DNA synthesis by replication protein A from M. thermoautotrophicum can be relieved by the addition of M. thermoautotrophicum homologs of replication factor C and proliferating cell nuclear antigen. The possible roles of PolB in M. thermoautotrophicum replication are discussed.

The C-terminal region of Schizosaccaromyces pombe proliferating cell nuclear antigen is essential for DNA polymerase activity.

Proliferating cell nuclear antigen (PCNA), the processivity factor (sliding clamp) of DNA polymerases (Pols), plays essential roles in DNA metabolism. In this report, we examined the functional role of the C-terminal region of Schizosaccaromyces pombe PCNA both in vitro and in vivo. The deletion or Ala substitution of the last 9 aa (252-260A), as well as Ala replacement of only 4 aa (252-255A) at the C terminus, failed to substitute for the wild-type PCNA protein for cell growth in S. pombe. Two other PCNA mutant proteins, A251V and K253E, exhibited cold-sensitive phenotypes. Several yeast strains harboring mutations, including those at the acidic C-terminal region, showed elevated sensitivity to DNA damage. The ability of the mutant PCNA proteins to stimulate DNA synthesis by Poldelta and Polepsilon also was studied in vitro. The mutant proteins that did not support cell growth and a mutant protein containing a single amino acid substitution at position 252, where Pro is replaced by Ala, stimulated Poldelta and Polepsilon activities poorly. All mutant PCNA proteins, however, were assembled around DNA by the clamp loader, replication factor C, efficiently. Thus, the C-terminal region of PCNA is important for interactions with both Poldelta and Polepsilon and for cell survival after DNA damage. The C terminus of sliding clamps from other organisms has been shown to be important for clamp loading as well as polymerase interactions. The relationship between the conserved sequence in this region in different organisms is discussed.

Studies on the interactions between human replication factor C and human proliferating cell nuclear antigen.

Proliferating cell nuclear antigen (PCNA) is a processivity factor required for DNA polymerase delta (or epsilon)-catalyzed DNA synthesis. When loaded onto primed DNA templates by replication factor C (RFC), PCNA acts to tether the polymerase to DNA, resulting in processive DNA chain elongation. In this report, we describe the identification of two separate peptide regions of human PCNA spanning amino acids 36-55 and 196-215 that bind RFC by using the surface plasmon resonance technique. Site-directed mutagenesis of residues within these regions in human PCNA identified two specific sites that affected the biological activity of PCNA. Replacement of the aspartate 41 residue by an alanine, serine, or asparagine significantly impaired the ability of PCNA to (i) support the RFC/PCNA-dependent polymerase delta-catalyzed elongation of a singly primed DNA template; (ii) stimulate RFC-catalyzed DNA-dependent hydrolysis of ATP; (iii) be loaded onto DNA by RFC; and (iv) activate RFC-independent polymerase delta-catalyzed synthesis of poly dT. Introduction of an alanine at position 210 in place of an arginine also reduced the efficiency of PCNA in supporting RFC-dependent polymerase delta-catalyzed elongation of a singly primed DNA template. However, this mutation did not significantly alter the ability of PCNA to stimulate DNA polymerase delta in the absence of RFC but substantially lowered the efficiency of RFC-catalyzed reactions. These results are in keeping with a model in which surface exposed regions of PCNA interact with RFC and the subsequent loading of PCNA onto DNA orients the elongation complex in a manner essential for processive DNA synthesis.

The internal workings of a DNA polymerase clamp-loading machine.

Replicative DNA polymerases are multiprotein machines that are tethered to DNA during chain extension by sliding clamp proteins. The clamps are designed to encircle DNA completely, and they are manipulated rapidly onto DNA by the ATP-dependent activity of a clamp loader. We outline the detailed mechanism of gamma complex, a five-protein clamp loader that is part of the Escherichia coli replicase, DNA polymerase III holoenzyme. The gamma complex uses ATP to open the beta clamp and assemble it onto DNA. Surprisingly, ATP is not needed for gamma complex to crack open the beta clamp. The function of ATP is to regulate the activity of one subunit, delta, which opens the clamp simply by binding to it. The delta' subunit acts as a modulator of the interaction between delta and beta. On binding ATP, the gamma complex is activated such that the delta' subunit permits delta to bind beta and crack open the ring at one interface. The clamp loader-open clamp protein complex is now ready for an encounter with primed DNA to complete assembly of the clamp around DNA. Interaction with DNA stimulates ATP hydrolysis which ejects the gamma complex from DNA, leaving the ring to close around the duplex.

Trading places on DNA--a three-point switch underlies primer handoff from primase to the replicative DNA polymerase.

This study reports a primase-to-polymerase switch in E. coli that closely links primase action with extension by DNA polymerase III holoenzyme. We find that primase tightly grips its RNA primer, protecting it from the action of other proteins. However, primase must be displaced before the beta sliding clamp can be assembled on the primed site. A single subunit of the holoenzyme, chi, is dedicated to this primase displacement task. The displacement mechanism depends on a third protein, SSB. Primase requires contact to SSB for its grip on the primed site. The chi subunit also binds SSB, upon which the primase-to-SSB contact is destabilized leading to dissociation of primase and assembly of beta onto the RNA primer. The conservation of this three-point switch, in which two proteins exchange places on DNA via mutually exclusive interaction with a third protein, is discussed.