Thermus thermophilus bacteriophage phiYS40 genome and proteomic characterization of virions

We determined the sequence of the 152,372 bp genome of phiYS40, a lytic tailed bacteriophage of Thermus thermophilus. The genome contains 170 putative open reading frames and three tRNA genes. Functions for 25% of phiYS40 gene products were predicted on the basis of similarity to proteins of known function from diverse phages and bacteria. phiYS40 encodes a cluster of proteins involved in nucleotide salvage, such as flavin-dependent thymidylate synthase, thymidylate kinase, ribonucleotide reductase, and deoxycytidylate deaminase, and in DNA replication, such as DNA primase, helicase, type A DNA polymerase, and predicted terminal protein involved in initiation of DNA synthesis. The structural genes of phiYS40, most of which have no similarity to sequences in public databases, were identified by mass spectrometric analysis of purified virions. Various phiYS40 proteins have different phylogenetic neighbors, including myovirus, podovirus, and siphovirus gene products, bacterial genes and, in one case, a dUTPase from a eukaryotic virus. phiYS40 has apparently arisen through multiple acts of recombination between different phage genomes as well as through acquisition of bacterial genes.     

Cleavage of Bacteriophage λ cI Repressor Involves the RecA C-Terminal Domain

The SOS response to DNA damage in Escherichia coli involves at least 43 genes, all under the control of the LexA repressor. Activation of these genes occurs when the LexA repressor cleaves itself, a reaction catalyzed by an active, extended RecA filament formed on DNA. It has been shown that the LexA repressor binds within the deep groove of this nucleoprotein filament, and presumably, cleavage occurs in this groove. Bacteriophages, such as λ, have repressors (cI) that are structural homologs of LexA and also undergo self-cleavage when SOS is induced. It has been puzzling that some mutations in RecA that affect the cleavage of repressors are in the C-terminal domain (CTD) far from the groove where cleavage is thought to occur. In addition, it has been shown that the rate of cleavage of cI by RecA is dependent upon both the substrate on which RecA is polymerized and the ATP analog used. Electron microscopy and three-dimensional reconstructions show that the conformation and dynamics of RecA's CTD are also modulated by the polynucleotide substrate and ATP analog. Under conditions where the repressor cleavage rates are the highest, cI is coordinated within the groove by contacts with RecA's CTD. These observations provide a framework for understanding previous genetic and biochemical observations.     

The Capsid Proteins of a Large, Icosahedral dsDNA Virus

Chilo iridescent virus (CIV) is a large (∼ 1850 Å diameter) insect virus with an icosahedral, T = 147 capsid, a double-stranded DNA (dsDNA) genome, and an internal lipid membrane. The structure of CIV was determined to 13 Å resolution by means of cryoelectron microscopy (cryoEM) and three-dimensional image reconstruction. A homology model of P50, the CIV major capsid protein (MCP), was built based on its amino acid sequence and the structure of the homologous Paramecium bursaria chlorella virus 1 Vp54 MCP. This model was fitted into the cryoEM density for each of the 25 trimeric CIV capsomers per icosahedral asymmetric unit. A difference map, in which the fitted CIV MCP capsomers were subtracted from the CIV cryoEM reconstruction, showed that there are at least three different types of minor capsid proteins associated with the capsomers outside the lipid membrane. “Finger” proteins are situated at many, but not all, of the spaces between three adjacent capsomers within each trisymmetron, and “zip” proteins are situated between sets of three adjacent capsomers at the boundary between neighboring trisymmetrons and pentasymmetrons. Based on the results of segmentation and density correlations, there are at least eight finger proteins and three dimeric and two monomeric zip proteins in one asymmetric unit of the CIV capsid. These minor proteins appear to stabilize the virus by acting as intercapsomer cross-links. One transmembrane “anchor” protein per icosahedral asymmetric unit, which extends from beneath one of the capsomers in the pentasymmetron to the internal leaflet of the lipid membrane, may provide additional stabilization for the capsid. These results are consistent with the observations for other large, icosahedral dsDNA viruses that also utilize minor capsid proteins for stabilization and for determining their assembly.     

Infectious Bursal Disease Virus: Ribonucleoprotein Complexes of a Double-Stranded RNA Virus

Genome-binding proteins with scaffolding and/or regulatory functions are common in living organisms and include histones in eukaryotic cells, histone-like proteins in some double-stranded DNA (dsDNA) viruses, and the nucleocapsid proteins of single-stranded RNA viruses. dsRNA viruses nevertheless lack these ribonucleoprotein (RNP) complexes and are characterized by sharing an icosahedral T = 2 core involved in the metabolism and insulation of the dsRNA genome. The birnaviruses, with a bipartite dsRNA genome, constitute a well-established exception and have a single-shelled T = 13 capsid only. Moreover, as in many negative single-stranded RNA viruses, the genomic dsRNA is bound to a nucleocapsid protein (VP3) and the RNA-dependent RNA polymerase (VPg). We used electron microscopy and functional analysis to characterize these RNP complexes of infectious bursal disease virus, the best characterized member of the Birnaviridae family. Mild disruption of viral particles revealed that VP3, the most abundant core protein, present at ∼ 450 copies per virion, is found in filamentous material tightly associated with the dsRNA. We developed a method to purify RNP and VPg-dsRNA complexes. Analysis of these complexes showed that they are linear molecules containing a constant amount of protein. Sensitivity assays to nucleases indicated that VP3 renders the genomic dsRNA less accessible for RNase III without introducing genome compaction. Additionally, we found that these RNP complexes are functionally competent for RNA synthesis in a capsid-independent manner, in contrast to most dsRNA viruses.     

The Bipolar Filaments Formed by Herpes Simplex Virus Type 1 SSB/Recombination Protein (ICP8) Suggest a Mechanism for DNA Annealing

Herpes simplex virus type 1 encodes a multifunctional protein, ICP8, which serves both as a single-strand binding protein and as a recombinase, catalyzing reactions involved in replication and recombination of the viral genome. In the presence of divalent ions and at low temperature, previous electron microscopic studies showed that ICP8 will form long left-handed helical filaments. Here, electron microscopic image reconstruction reveals that the filaments are bipolar, with an asymmetric unit containing two subunits of ICP8 that constitute a symmetrical dimer. This organization of the filament has been confirmed using scanning transmission electron microscopy. The pitch of the filaments is ∼ 250 Å, with ∼ 6.2 dimers per turn. Docking of a crystal structure of ICP8 into the reconstructed filament shows that the C-terminal domain of ICP8, attached to the body of the subunit by a flexible linker containing ∼ 10 residues, is packed into a pocket in the body of a neighboring subunit in the crystal in a similar manner as in the filament. However, the interactions between the large N-terminal domains are quite different in the filament from that observed in the crystal. A previously proposed model for ICP8 binding single-stranded DNA (ssDNA), based upon the crystal structure, leads to a model for a continuous strand of ssDNA near the filament axis. The bipolar nature of the ICP8 filaments means that a second strand of ssDNA would be running through this filament in the opposite orientation, and this provides a potential mechanism for how ICP8 anneals complementary ssDNA into double-stranded DNA, where each strand runs in opposite directions.     

Topologies of Complexes Containing O-Alkylguanine-DNA Alkyltransferase and DNA

The mutagenic and cytotoxic effects of many alkylating agents are reduced by O⁶-alkylguanine-DNA alkyltransferase (AGT). In humans, this protein not only protects the integrity of the genome, but also contributes to the resistance of tumors to DNA-alkylating chemotherapeutic agents. Here we describe and test models for cooperative multiprotein complexes of AGT with single-stranded and duplex DNAs that are based on in vitro binding data and the crystal structure of a 1:1 AGT-DNA complex. These models predict that cooperative assemblies contain a three-start helical array of proteins with dominant protein-protein interactions between the amino-terminal face of protein n and the carboxy-terminal face of protein n + 3, and they predict that binding duplex DNA does not require large changes in B-form DNA geometry. Experimental tests using protein cross-linking analyzed by mass spectrometry, electrophoretic and analytical ultracentrifugation binding assays, and topological analyses with closed circular DNA show that the properties of multiprotein AGT-DNA complexes are consistent with these predictions.     

Visualizing the Disassembly of S. cerevisiae Rad51 Nucleoprotein Filaments

Rad51 is the core component of the eukaryotic homologous recombination machinery and assembles into elongated nucleoprotein filaments on DNA. We have used total internal reflection fluorescence microscopy and a DNA curtain assay to investigate the dynamics of individual Saccharomyces cerevisiae Rad51 nucleoprotein filaments. For these experiments the DNA molecules were end-labeled with single fluorescent semiconducting nanocrystals. The assembly and disassembly of the Rad51 nucleoprotein filaments were visualized by tracking the location of the labeled DNA end in real time. Using this approach, we have analyzed yeast Rad51 under a variety of different reaction conditions to assess parameters that impact the stability of the nucleoprotein filament. We show that Rad51 readily dissociates from DNA in the presence of ADP or in the absence of nucleotide cofactor, but that free ATP in solution confers a fivefold increase in the stability of the nucleoprotein filaments. We also probe how protein dissociation is coupled to ATP binding and hydrolysis by examining the effects of ATP concentration, and by the use of the nonhydrolyzable ATP analogue adenosine 5'-(beta, gamma-imido) triphosphate and ATPase active-site mutants. Finally, we demonstrate that the Rad51 gain-of-function mutant I345T dissociates from DNA with kinetics nearly identical to that of wild-type Rad51, but assembles 30% more rapidly. Together, these results provide a framework for studying the biochemical behaviors of S. cerevisiae Rad51 nucleoprotein filaments at the single-molecule level.     

ATP Binding and Hydrolysis by Mcm2 Regulate DNA Binding by Mcm Complexes

The essential minichromosome maintenance (Mcm) proteins Mcm2 through Mcm7 likely comprise the replicative helicase in eukaryotes. In addition to Mcm2-7, other subcomplexes, including one comprising Mcm4, Mcm6, and Mcm7, unwind DNA. Using Mcm4/6/7 as a tool, we reveal a role for nucleotide binding by Saccharomyces cerevisiae Mcm2 in modulating DNA binding by Mcm complexes. Previous studies have shown that Mcm2 inhibits DNA unwinding by Mcm4/6/7. Here, we show that interaction of Mcm2 and Mcm4/6/7 is not sufficient for inhibition; rather, Mcm2 requires nucleotides for its regulatory role. An Mcm2 mutant that is defective for ATP hydrolysis (K549A), as well as ATP analogues, was used to show that ADP binding by Mcm2 is required to inhibit DNA binding and unwinding by Mcm4/6/7. This Mcm2-mediated regulation of Mcm4/6/7 is independent of Mcm3/5. Furthermore, the importance of ATP hydrolysis by Mcm2 to the regulation of the native complex was apparent from the altered DNA binding properties of Mcm2^KA-7. Moreover, together with the finding that Mcm2_K549A does not support yeast viability, these results indicate that the nucleotide-bound state of Mcm2 is critical in regulating the activities of Mcm4/6/7 and Mcm2-7 complexes.     

Conformational Adaptability of Redβ during DNA Annealing and Implications for Its Structural Relationship with Rad52

Single-strand annealing proteins, such as Redβ from λ phage or eukaryotic Rad52, play roles in homologous recombination. Here, we use atomic force microscopy to examine Redβ quaternary structure and Redβ-DNA complexes. In the absence of DNA, Redβ forms a shallow right-handed helix. The presence of single-stranded DNA (ssDNA) disrupts this structure. Upon addition of a second complementary ssDNA, annealing generates a left-handed helix that incorporates 14 Redβ monomers per helical turn, with each Redβ monomer annealing ≈ 11 bp of DNA. The smallest stable annealing intermediate requires 20 bp DNA and two Redβ monomers. Hence, we propose that Redβ promotes base pairing by first increasing the number of transient interactions between ssDNAs. Then, annealing is promoted by the binding of a second Redβ monomer, which nucleates the formation of a stable annealing intermediate. Using threading, we identify sequence similarities between the RecT/Redβ and the Rad52 families, which strengthens previous suggestions, based on similarities of their quaternary structures, that they share a common mode of action. Hence, our findings have implications for a common mechanism of DNA annealing mediated by single-strand annealing proteins including Rad52.     

A Pseudo-Atomic Model for the Capsid Shell of Bacteriophage Lambda Using Chemical Cross-Linking/Mass Spectrometry and Molecular Modeling

Bacteriophage lambda is one of the most exhaustively studied of the double-stranded DNA viruses. Its assembly pathway is highly conserved among the herpesviruses and many of the bacteriophages, making it an excellent model system. Despite extensive genetic and biophysical characterization of many of the lambda proteins and the assembly pathways in which they are implicated, there is a relative dearth of structural information on many of the most critical proteins involved in lambda assembly and maturation, including that of the lambda major capsid protein. Toward this end, we have utilized a combination of chemical cross-linking/mass spectrometry and computational modeling to construct a pseudo-atomic model of the lambda major capsid protein as a monomer, as well as in the context of the assembled procapsid shell. The approach described here is generalizable and can be used to provide structural models for any biological complex of interest. The procapsid structural model is in good agreement with published biochemical data indicating that procapsid expansion exposes hydrophobic surface area and that this serves to nucleate assembly of capsid decoration protein, gpD. The model further implicates additional molecular interactions that may be critical to the assembly of the capsid shell and for the stabilization of the structure by the gpD decoration protein.