Structural basis for the calmodulin-mediated activation of eukaryotic elongation factor 2 kinase.

Translation is a tightly regulated process that ensures optimal protein quality and enables adaptation to energy/nutrient availability. The α-kinase eukaryotic elongation factor 2 kinase (eEF-2K), a key regulator of translation, specifically phosphorylates the guanosine triphosphatase eEF-2, thereby reducing its affinity for the ribosome and suppressing the elongation phase of protein synthesis. eEF-2K activation requires calmodulin binding and autophosphorylation at the primary stimulatory site, T348. Biochemical studies predict a calmodulin-mediated activation mechanism for eEF-2K distinct from other calmodulin-dependent kinases. Here, we resolve the atomic details of this mechanism through a 2.3-Å crystal structure of the heterodimeric complex of calmodulin and the functional core of eEF-2K (eEF-2KTR). This structure, which represents the activated T348-phosphorylated state of eEF-2KTR, highlights an intimate association of the kinase with the calmodulin C-lobe, creating an "activation spine" that connects its amino-terminal calmodulin-targeting motif to its active site through a conserved regulatory element.

Convergent evolution in two bacterial replicative helicase loaders.

Dedicated loader proteins play essential roles in bacterial DNA replication by opening ring-shaped DnaB-family helicases and chaperoning single-stranded (ss)DNA into a central motor chamber as a prelude to DNA unwinding. Although unrelated in sequence, the Escherichia coli DnaC and bacteriophage λ P loaders feature a similar overall architecture: a globular domain linked to an extended lasso/grappling hook element, located at their N and C termini, respectively. Both loaders remodel a closed DnaB ring into nearly identical right-handed open conformations. The sole element shared by the loaders is a single alpha helix, which binds to the same site on the helicase. Physical features of the loaders establish that DnaC and λ P evolved independently to converge, through molecular mimicry, on a common helicase-opening mechanism.

A Peek Inside the Machines of Bacterial Nucleotide Excision Repair.

Double stranded DNA (dsDNA), the repository of genetic information in bacteria, archaea and eukaryotes, exhibits a surprising instability in the intracellular environment; this fragility is exacerbated by exogenous agents, such as ultraviolet radiation. To protect themselves against the severe consequences of DNA damage, cells have evolved at least six distinct DNA repair pathways. Here, we review recent key findings of studies aimed at understanding one of these pathways: bacterial nucleotide excision repair (NER). This pathway operates in two modes: a global genome repair (GGR) pathway and a pathway that closely interfaces with transcription by RNA polymerase called transcription-coupled repair (TCR). Below, we discuss the architecture of key proteins in bacterial NER and recent biochemical, structural and single-molecule studies that shed light on the lesion recognition steps of both the GGR and the TCR sub-pathways. Although a great deal has been learned about both of these sub-pathways, several important questions, including damage discrimination, roles of ATP and the orchestration of protein binding and conformation switching, remain to be addressed.

Real-time investigation of the roles of ATP hydrolysis by UvrA and UvrB during DNA damage recognition in nucleotide excision repair.

Nucleotide excision repair (NER) stands out among other DNA repair systems for its ability to process a diverse set of unrelated DNA lesions. In bacteria, NER damage detection is orchestrated by the UvrA and UvrB proteins, which form the UvrA2-UvrB2 (UvrAB) damage sensing complex. The highly versatile damage recognition is accomplished in two ATP-dependent steps. In the first step, the UvrAB complex samples the DNA in search of lesion. Subsequently, the presence of DNA damage is verified within the UvrB-DNA complex after UvrA has dissociated. Although the mechanism of bacterial NER damage detection has been extensively investigated, the role of ATP binding and hydrolysis by UvrA and UvrB during this process remains incompletely understood. Here, we report a pre-steady state kinetics Förster resonance energy transfer (FRET) study of the real-time interaction between UvrA, UvrB, and damaged DNA during lesion detection. By using UvrA and UvrB mutants harboring site-specific mutations in the ATP binding sites, we show for the first time that the dissociation of UvrA from the UvrAB-DNA complex does not require ATP hydrolysis by UvrB. We find that ATP hydrolysis by UvrA is not essential, but somehow facilitates the formation of UvrB-DNA complex, with ATP hydrolysis at the proximal site of UvrA playing a more critical role. Consistent with previous reports, our results indicated that the ATPase activity of UvrB is essential for the formation of UvrB-DNA complex but is not required for the binding of the UvrAB complex to DNA.

Wss1 homolog from Candida albicans and its role in DNA-protein crosslink tolerance.

Candida albicans is an opportunistic yeast that can cause life-threatening systemic infection in immunocompromised individuals. During infections, C. albicans has to cope with genotoxic stresses generated by the host immune system. DNA-protein crosslink (DPC), the covalent linkage of proteins with DNA, is one type of DNA damages that can be caused by the host immune response. DPCs are bulky lesions that interfere with the progression of replication and transcription machineries, and hence threaten genomic integrity. Accordingly, either a DPC tolerance mechanism or a DPC repair pathway is essential for C. albicans to maintain genomic stability and survive in the host. Here, we identified Wss1 (weak suppressor of Smt3) in C. albicans (CaWss1) using bioinformatics, genetic complementation, and biochemical studies. We showed that CaWss1 promotes cell survival under genotoxic stress conditions that generate DPCs and that the catalytic metalloprotease domain of CaWss1 is essential for its cellular function. Interactions of CaWss1 with Cdc48 and small ubiquitin-like modifier, although not strictly required, contribute to the function of CaWss1 in the suppression of the growth defects under DPC-inducing conditions. This report is the first investigation of the role of CaWss1 in DPC tolerance in C. albicans.

The ATPase mechanism of UvrA2 reveals the distinct roles of proximal and distal ATPase sites in nucleotide excision repair.

The UvrA2 dimer finds lesions in DNA and initiates nucleotide excision repair. Each UvrA monomer contains two essential ATPase sites: proximal (P) and distal (D). The manner whereby their activities enable UvrA2 damage sensing and response remains to be clarified. We report three key findings from the first pre-steady state kinetic analysis of each site. Absent DNA, a P2ATP-D2ADP species accumulates when the low-affinity proximal sites bind ATP and enable rapid ATP hydrolysis and phosphate release by the high-affinity distal sites, and ADP release limits catalytic turnover. Native DNA stimulates ATP hydrolysis by all four sites, causing UvrA2 to transition through a different species, P2ADP-D2ADP. Lesion-containing DNA changes the mechanism again, suppressing ATP hydrolysis by the proximal sites while distal sites cycle through hydrolysis and ADP release, to populate proximal ATP-bound species, P2ATP-Dempty and P2ATP-D2ATP. Thus, damaged and native DNA trigger distinct ATPase site activities, which could explain why UvrA2 forms stable complexes with UvrB on damaged DNA compared with weaker, more dynamic complexes on native DNA. Such specific coupling between the DNA substrate and the ATPase mechanism of each site provides new insights into how UvrA2 utilizes ATP for lesion search, recognition and repair.

Mechanisms of opening and closing of the bacterial replicative helicase.

Assembly of bacterial ring-shaped hexameric replicative helicases on single-stranded (ss) DNA requires specialized loading factors. However, mechanisms implemented by these factors during opening and closing of the helicase, which enable and restrict access to an internal chamber, are not known. Here, we investigate these mechanisms in the Escherichia coli DnaB helicase•bacteriophage λ helicase loader (λP) complex. We show that five copies of λP bind at DnaB subunit interfaces and reconfigure the helicase into an open spiral conformation that is intermediate to previously observed closed ring and closed spiral forms; reconfiguration also produces openings large enough to admit ssDNA into the inner chamber. The helicase is also observed in a restrained inactive configuration that poises it to close on activating signal, and transition to the translocation state. Our findings provide insights into helicase opening, delivery to the origin and ssDNA entry, and closing in preparation for translocation.

Routine single particle CryoEM sample and grid characterization by tomography.

Single particle cryo-electron microscopy (cryoEM) is often performed under the assumption that particles are not adsorbed to the air-water interfaces and in thin, vitreous ice. In this study, we performed fiducial-less tomography on over 50 different cryoEM grid/sample preparations to determine the particle distribution within the ice and the overall geometry of the ice in grid holes. Surprisingly, by studying particles in holes in 3D from over 1000 tomograms, we have determined that the vast majority of particles (approximately 90%) are adsorbed to an air-water interface. The implications of this observation are wide-ranging, with potential ramifications regarding protein denaturation, conformational change, and preferred orientation. We also show that fiducial-less cryo-electron tomography on single particle grids may be used to determine ice thickness, optimal single particle collection areas and strategies, particle heterogeneity, and de novo models for template picking and single particle alignment.

Movement of the ß-hairpin in the third zinc-binding module of UvrA is required for DNA damage recognition.

Nucleotide excision repair (NER) is distinguished from other DNA repair pathways by its ability to process various DNA lesions. In bacterial NER, UvrA is the key protein that detects damage and initiates the downstream NER cascade. Although it is known that UvrA preferentially binds to damaged DNA, the mechanism for damage recognition is unclear. A ß-hairpin in the third Zn-binding module (Zn3hp) of UvrA has been suggested to undergo a conformational change upon DNA binding, and proposed to be important for damage sensing. Here, we investigate the contribution of the dynamics in the Zn3hp structural element to various activities of UvrA during the early steps of NER. By restricting the movement of the Zn3hp using disulfide crosslinking, we showed that the movement of the Zn3hp is required for damage-specific binding, UvrB loading and ATPase activities of UvrA. We individually inactivated each of the nucleotide binding sites in UvrA to investigate its role in the movement of the Zn3hp. Our results suggest that the conformational change of the Zn3hp is controlled by ATP hydrolysis at the distal nucleotide binding site. We propose a bi-phasic damage inspection model of UvrA in which movement of the Zn3hp plays a key role in damage recognition.

The replication initiator of the cholera pathogen's second chromosome shows structural similarity to plasmid initiators.

The conserved DnaA-oriC system is used to initiate replication of primary chromosomes throughout the bacterial kingdom; however, bacteria with multipartite genomes evolved distinct systems to initiate replication of secondary chromosomes. In the cholera pathogen, Vibrio cholerae, and in related species, secondary chromosome replication requires the RctB initiator protein. Here, we show that RctB consists of four domains. The structure of its central two domains resembles that of several plasmid replication initiators. RctB contains at least three DNA binding winged-helix-turn-helix motifs, and mutations within any of these severely compromise biological activity. In the structure, RctB adopts a head-to-head dimeric configuration that likely reflects the arrangement in solution. Therefore, major structural reorganization likely accompanies complex formation on the head-to-tail array of binding sites in oriCII. Our findings support the hypothesis that the second Vibrionaceae chromosome arose from an ancestral plasmid, and that RctB may have evolved additional regulatory features.

Small-angle X-ray scattering reveals architecture and A2B2 stoichiometry of the UvrA-UvrB DNA damage sensor.

The UvrA-UvrB (AB) protein complex operates in the bacterial nucleotide excision repair pathway as the main sensor of DNA damage. Crystallographic analysis of the AB complex revealed a linear UvrB-UvrA-UvrA-UvrB arrangement of subunits with an internal two-fold axis that became incorporated into the crystal. Here, we have used small-angle X-ray scattering (SAXS) to show close correspondence between the crystal structure and the entity in solution. This result confirms the number and disposition of subunits in the crystallographic model and rules out other possible arrangements suggested by packing in the crystal. The current SAXS analysis failed to detect significant changes to the structure as a function of nucleotide.

Structure and mechanism of the UvrA-UvrB DNA damage sensor.

Nucleotide excision repair (NER) is used by all organisms to eliminate DNA lesions. We determined the structure of the Geobacillus stearothermophilus UvrA-UvrB complex, the damage-sensor in bacterial NER and a new structure of UvrA. We observe that the DNA binding surface of UvrA, previously found in an open shape that binds damaged DNA, also exists in a closed groove shape compatible with native DNA only. The sensor contains two UvrB molecules that flank the UvrA dimer along the predicted path for DNA, ~80 Å from the lesion. We show that the conserved signature domain II of UvrA mediates a nexus of contacts among UvrA, UvrB and DNA. Further, in our new structure of UvrA, this domain adopts an altered conformation while an adjacent nucleotide binding site is vacant. Our findings raise unanticipated questions about NER and also suggest a revised picture of its early stages.

Crystal structure of the three tandem FF domains of the transcription elongation regulator CA150.

FF domains are small protein-protein interaction modules that have two flanking conserved phenylalanine residues. They are present in proteins involved in transcription, RNA splicing, and signal transduction, and often exist in tandem arrays. Although several individual FF domain structures have been determined by NMR, the tandem nature of most FF domains has not been revealed. Here we report the 2.7-A-resolution crystal structure of the first three FF domains of the human transcription elongation factor CA150. Each FF domain is composed of three alpha-helices and a 3(10) helix between alpha-helix 2 and alpha-helix 3. The most striking feature of the structure is that an FF domain is connected to the next by an alpha-helix that continues from helix 3 to helix 1 of the next. The consequent elongated arrangement allows exposure of many charged residues within the region that can be engaged in interaction with other molecules. Binding studies using a peptide ligand suggest that a specific conformation of the FF domains might be required to achieve higher-affinity binding. Additionally, we explore potential DNA binding of the FF construct used in this study. Overall, we provide the first crystal structure of an FF domain and insights into the tandem nature of the FF domains and suggest that, in addition to protein binding, FF domains might be involved in DNA binding.

A biochemically active MCM-like helicase in Bacillus cereus.

The mini-chromosome maintenance (MCM) proteins serve as the replicative helicases in archaea and eukaryotes. Interestingly, an MCM homolog was identified, by BLAST analysis, within a phage integrated in the bacterium Bacillus cereus (Bc). BcMCM is only related to the AAA region of MCM-helicases; the typical amino-terminus is missing and is replaced by a segment with weak homology to primases. We show that BcMCM displays 3'-->5' helicase and ssDNA-stimulated ATPase activity, properties that arise from its conserved AAA domain. Isolated BcMCM is a monomer in solution but likely forms the functional oligomer in vivo. We found that the BcMCM amino-terminus can bind ssDNA and harbors a zinc atom, both hallmarks of the typical MCM amino-terminus. No BcMCM-catalyzed primase activity could be detected. We propose that the divergent amino-terminus of BcMCM is a paralog of the corresponding region of MCM-helicases. A divergent amino terminus makes BcMCM a useful model for typical MCM-helicases since it accomplishes the same function using an apparently unrelated structure.

A structural model for the damage-sensing complex in bacterial nucleotide excision repair.

Nucleotide excision repair is distinguished from other DNA repair pathways by its ability to process a wide range of structurally unrelated DNA lesions. In bacteria, damage recognition is achieved by the UvrA.UvrB ensemble. Here, we report the structure of the complex between the interaction domains of UvrA and UvrB. These domains are necessary and sufficient for full-length UvrA and UvrB to associate and thereby form the DNA damage-sensing complex of bacterial nucleotide excision repair. The crystal structure and accompanying biochemical analyses suggest a model for the complete damage-sensing complex.

Enzymatic synthesis of multi-milligram quantities of large, linear DNA molecules for structural studies.

Structural analyses of large protein-DNA complexes (such as those associated with replication initiation, eukaryotic transcription activation or chromatin remodeling, among others) remain a challenge because of difficulties in obtaining multi-milligram quantities of high-quality preparations of large, linear DNA molecules. This protocol describes a three-stage DNA amplification procedure for making such molecules in amounts that are suitable for structural studies. In the first step, conventional polymerase chain reaction (PCR) using specialized primer sequences is used to prepare a DNA molecule suitable for self-primed DNA synthesis. This molecule, which consists of the sequence of interest flanked by the cohesive end sequences from bacteriophage lambda as well as endonuclease recognition sites, is then submitted to self-primed DNA synthesis in the second step. Amplification produces long polymers of DNA, tens of kilobases in length, which harbor many copies of the sequence of interest. The yield from the second step is increased in the third phase, which consists of another round of amplification. Finally, endonuclease digestion of these polymers, followed by chromatographic purification, yields high-quality preparations of DNA. The molecules produced by this procedure consist of the DNA sequence of interest with three base pairs at either end. This procedure typically yields 400-800 microg of purified DNA per milliliter of amplification reaction.

Preparation of multimilligram quantities of large, linear DNA molecules for structural studies.

We describe a method for preparing large, linear DNA molecules in amounts that are suitable for structural studies. The procedure employs self-primed DNA amplification on a starting molecule that consists of the sequence of interest flanked by the cohesive end sequences from bacteriophage lambda as well as endonuclease recognition sites. Amplification produces long polymers of DNA, tens of kilobases in length, which harbor many copies of the sequence of interest. Endonuclease digestion of these polymers, followed by chromatographic purification, yields high-quality preparations of the DNA molecule of interest. Reliance on the cohesive end sequences to initiate self-primed amplification effectively enables the synthesis of DNA molecules of interest with minimal restriction on length and sequence.

Crystal structure of Bacillus stearothermophilus UvrA provides insight into ATP-modulated dimerization, UvrB interaction, and DNA binding.

The nucleotide excision repair pathway corrects many structurally unrelated DNA lesions. Damage recognition in bacteria is performed by UvrA, a member of the ABC ATPase superfamily whose functional form is a dimer with four nucleotide-binding domains (NBDs), two per protomer. In the 3.2 A structure of UvrA from Bacillus stearothermophilus, we observe that the nucleotide-binding sites are formed in an intramolecular fashion and are not at the dimer interface as is typically found in other ABC ATPases. UvrA also harbors two unique domains; we show that one of these is required for interaction with UvrB, its partner in lesion recognition. In addition, UvrA contains three zinc modules, the number and ligand sphere of which differ from previously published models. Structural analysis, biochemical experiments, surface electrostatics, and sequence conservation form the basis for models of ATP-modulated dimerization, UvrA-UvrB interaction, and DNA binding during the search for lesions.