Structural and functional analysis of a bipolar replication terminus. Implications for the origin of polarity of fork arrest.

We have delineated the amino acid to nucleotide contacts made by two interacting dimers of the replication terminator protein (RTP) of Bacillus subtilis with a novel naturally occurring bipolar replication terminus by converting RTP to a site-directed chemical nuclease and mapping its cleavage sites on the terminus. The data show a relatively symmetrical arrangement of the amino acid to base contacts, and a comparison of the bipolar contacts with that of a normal unipolar terminus suggests that the DNA-protein contacts play an important determinative role in generating polarity from structurally symmetrical RTP dimers. The amino acid to nucleotide contacts provided distance constraints that enabled us to build a three-dimensional model of the protein-DNA complex. The model is consistent with features of the bipolar Ter.RTP complex derived from mutational and cross-linking data. The bipolar terminus arrested Escherichia coli DNA replication and DnaB helicase and T7 RNA polymerase in vitro in both orientations. RTP arrested the unwinding of duplex DNA on the bipolar Ter DNA substrate regardless of the length of the duplex DNA. The latter result suggested further that the terminus arrested authentic DNA unwinding by the helicase rather than just translocation of helicase on DNA.

Structural genomics in the post-genomics era - the shapes of things to come.

The overwhelming success of the current genomic sequencing efforts has spawned analogous efforts in the structural biology community. These new research efforts, termed 'structural genomics', seek to create and execute high-throughput structure determination that would allow scientists to obtain hundreds to thousands of relevant macromolecular structures in a fraction of the time required today. Groups in academia, national laboratories and industry are launching such efforts, each examining a different set of model organisms and each with a different research model. This review will present the current structural genomics efforts and the data that have been derived from these efforts to date. The utility of these projects to pharmaceutical drug discovery efforts will also be presented.

The role of macromolecular crystallography and structure for drug discovery: advances and caveats.

In the last decade, macromolecular crystallography has become a standard technique used by the pharmaceutical and biotechnology industries in their drug discovery projects. This technique offers atomic level detail of drug-target:ligand interactions, the resolution of which is currently unmatched by other methodologies. However, this high level of detail also presents special pitfalls, and requires critical evaluation of the structures. This review will highlight recent advances in crystallography and the use of macromolecular structures in pharmaceutical and biotechnology research. It will also outline the current limitations of the method both generally and as it pertains to drug discovery.

Termination of DNA replication of bacterial and plasmid chromosomes.

Sequence-specific replication termini occur in many bacterial and plasmid chromosomes and consist of two components: a cis-acting ter site and a trans-acting replication terminator protein. The interaction of a terminator protein with the ter site creates a protein-DNA complex that arrests replication forks in a polar fashion by antagonizing the action of the replicative helicase (thereby exhibiting a contrahelicase activity). Terminator proteins also arrest RNA polymerases in a polar fashion. Passage of an RNA transcript through a terminus from the non-blocking direction abrogates replication termination function, a mechanism that is likely to be used in conditional termini or replication check points.

Homologs of the vancomycin resistance D-Ala-D-Ala dipeptidase VanX in Streptomyces toyocaensis, Escherichia coli and Synechocystis: attributes of catalytic efficiency, stereoselectivity and regulation with implications for function.

BACKGROUND: Vancomycin-resistant enterococci are pathogenic bacteria that have altered cell-wall peptidoglycan termini (D-alanyl-D-lactate [D-Ala-D-lactate] instead of D-alanyl-D-alanine [D-Ala-D-Ala]), which results in a 1000-fold decreased affinity for binding vancomycin. The metallodipeptidase VanX (EntVanX) is key enzyme in antibiotic resistance as it reduces the cellular pool of the D-Ala-D-Ala dipeptide. RESULTS: A bacterial genome search revealed vanX homologs in Streptomyces toyocaensis (StoVanX), Escherichia coli (EcoVanX), and Synechocystis sp. strain PCC6803 (SynVanX). Here, the D,D-dipeptidase catalytic activity of all three VanX homologs is validated, and the catalytic efficiencies and diastereoselectivity ratios for dipeptide cleavage are reported. The ecovanX gene is shown to have an RpoS (sigma(s))-dependent promoter typical of genes turned on in stationary phase. Expression of ecovanX and an associated cluster of dipeptide permease genes permitted growth of E. coli using D-Ala-D-Ala as the sole carbon source. CONCLUSIONS: The key residues of the EntVanX active site are strongly conserved in the VanX homologs, suggesting their active-site topologies are similar. StoVanX is a highly efficient D-Ala-D-Ala dipeptidase; its gene is located in a vanHAX operon, consistent with a vancomycin-immunity function. StoVanX is a potential source for the VanX found in gram-positive enterococci. The catalytic efficiencies of D-Ala-D-Ala hydrolysis for EcoVanX and SynVanX are 25-fold lower than for EntVanX, suggesting they have a role in cell-wall turnover. Clustered with the ecovanX gene is a putative dipeptide permease system that imports D-Ala-D-Ala into the cell. The combined action of EcoVanX and the permease could permit the use of D-Ala-D-Ala as a bacterial energy source under starvation conditions.

The structure of VanX reveals a novel amino-dipeptidase involved in mediating transposon-based vancomycin resistance.

VanX is a zinc-dependent D-alanyl-D-alanine dipeptidase that is a critical component in a system that mediates transposon-based vancomycin resistance in enterococci. It is also a key drug target in circumventing clinical vancomycin resistance. The structure of VanX from E. faecium has been solved by X-ray crystallography and reveals a Zn(2+)-dipeptidase with a unique overall fold and a well-defined active site confined within a cavity of limited size. The crystal structures of VanX, the VanX:D-alanyl-D-alanine complex, the VanX:D-alanine complex, and VanX in complex with phosphonate and phosphinate transition-state analog inhibitors, are also presented at high resolution. Structural homology searches of known structures revealed that the fold of VanX is similar to those of two proteins: the N-terminal fragment of murine Sonic hedgehog and the Zn(2+)-dependent N-acyl-D-alanyl-D-alanine carboxypeptidase of S. albus G.

Ribosomal proteins S5 and L6: high-resolution crystal structures and roles in protein synthesis and antibiotic resistance.

Antibiotic resistance is rapidly becoming a major medical problem. Many antibiotics are directed against bacterial ribosomes, and mutations within both the RNA and protein components can render them ineffective. It is well known that the majority of these antibiotics act by binding to the ribosomal RNA, and it is of interest to understand how mutations in the ribosomal proteins can produce resistance. Translational accuracy is one important target of antibiotics, and a number of ribosomal protein mutations in Escherichia coli are known to modulate the proofreading mechanism of the ribosome. Here we describe the high-resolution structures of two such ribosomal proteins and characterize these mutations. The S5 protein, from the small ribosomal unit, is associated with two types of mutations: those that reduce translational fidelity and others that produce resistance to the antibiotic spectinomycin. The L6 protein, from the large subunit, has mutations that cause resistance to several aminoglycoside antibiotics, notably gentamicin. In both proteins, the mutations occur within their putative RNA-binding sites. The L6 mutations are particularly drastic because they result in large deletions of an RNA-binding region. These results support the hypothesis that the mutations create local distortions of the catalytic RNA component.When combined with a variety of structural and biochemical data, these mutations also become important probes of the architecture and function of the translational machinery. We propose that the C-terminal half of S5, which contains the accuracy mutations, organizes RNA structures associated with the decoding region, and the N-terminal half, which contains the spectinomycin-resistance mutations, directly interacts with an RNA helix that binds this antibiotic. As regards L6, we suggest that the mutations indirectly affect proofreading by locally distorting the EF-Tu.GTP.aminoacyl tRNA binding site on the large subunit.

Crystal structure of ErmC', an rRNA methyltransferase which mediates antibiotic resistance in bacteria.

The prevalent mechanism of bacterial resistance to erythromycin and other antibiotics of the macrolide-lincosamide-streptogramin B group (MLS) is methylation of the 23S rRNA component of the 50S subunit in bacterial ribosomes. This sequence-specific methylation is catalyzed by the Erm group of methyltransferases (MTases). They are found in several strains of pathogenic bacteria, and ErmC is the most studied member of this class. The crystal structure of ErmC' (a naturally occurring variant of ErmC) from Bacillus subtilis has been determined at 3.0 A resolution by multiple anomalous diffraction phasing methods. The structure consists of a conserved alpha/beta amino-terminal domain which binds the cofactor S-adenosyl-l-methionine (SAM), followed by a smaller, alpha-helical RNA-recognition domain. The beta-sheet structure of the SAM-binding domain is well-conserved between the DNA, RNA, and small-molecule MTases. However, the C-terminal nucleic acid binding domain differs from the DNA-binding domains of other MTases and is unlike any previously reported RNA-recognition fold. A large, positively charged, concave surface is found at the interface of the N- and C-terminal domains and is proposed to form part of the protein-RNA interaction surface. ErmC' exhibits the conserved structural motifs previously found in the SAM-binding domain of other methyltransferases. A model of SAM bound to ErmC' is presented which is consistent with the motif conservation among MTases.

Structure of the E2 DNA-binding domain from human papillomavirus serotype 31 at 2.4 A.

The papillomaviruses are a family of small double-stranded DNA viruses which exclusively infect epithelial cells and stimulate the proliferation of those cells. A key protein within the papillomavirus life-cycle is known as the E2 (Early 2) protein and is responsible for regulating viral transcription from all viral promoters as well as for replication of the papillomavirus genome in tandem with another protein known as E1. The E2 protein itself consists of three functional domains: an N-terminal trans-activation domain, a proline-rich linker, and a C-terminal DNA-binding domain. The first crystal structure of the human papillomavirus, serotype 31 (HPV-31), E2 DNA-binding domain has been determined at 2.4 A resolution. The HPV DNA-binding domain monomer consists of two beta-alpha-beta repeats of approximately equal length and is arranged as to have an anti-parallel beta-sheet flanked by the two alpha-helices. The monomers form the functional in vivo dimer by association of the beta-sheets of each monomer so as to form an eight-stranded anti-parallel beta-barrel at the center of the dimer, with the alpha-helices lining the outside of the barrel. The overall structure of HVP-31 E2 DNA-binding domain is similar to both the bovine papillomavirus E2-binding domain and the Epstein-Barr nuclear antigen-1 DNA-binding domain.

Helicase-contrahelicase interaction and the mechanism of termination of DNA replication.

Termination of DNA replication at a sequence-specific replication terminus is potentiated by the binding of the replication terminator protein (RTP) to the terminus sequence, causing polar arrest of the replicative helicase (contrahelicase activity). Two alternative models have been proposed to explain the mechanism of replication fork arrest. In the first model, the RTP-terminus DNA interaction simply imposes a polar barrier to helicase movement without involving any specific interaction between the helicase and the terminator proteins. The second model proposes that there is a specific interaction between the two proteins, and that the DNA-protein interaction both restricts the fork arrest to the replication terminus and determines the polarity of the process. The evidence presented in this paper strongly supports the second model.

Structure of the replication terminus-terminator protein complex as probed by affinity cleavage.

The replication terminator protein (RTP) of Bacillus subtilis is a homodimer that binds to each replication terminus and impedes replication fork movement in only one orientation with respect to the replication origin. The three-dimensional structure of the RTP-DNA complex needs to be determined to understand how structurally symmetrical dimers of RTP generate functional asymmetry. The functional unit of each replication terminus of Bacillus subtilis consists of four turns of DNA complexed with two interacting dimers of RTP. Although the crystal structure of the RTP apoprotein dimer has been determined at 2.6-A resolution, the functional unit of the terminus is probably too large and too flexible to lend itself to cocrystallization. We have therefore used an alternative strategy to delineate the three dimensional structure of the RTP-DNA complex by converting the protein into a site-directed chemical nuclease. From the pattern of base-specific cleavage of the terminus DNA by the chemical nuclease, we have mapped the amino acid to base contacts. Using these contacts as distance constraints, with the crystal structure of RTP, we have constructed a model of the DNA-protein complex. The biological implications of the model have been discussed.

The structure and function of the replication terminator protein of Bacillus subtilis: identification of the 'winged helix' DNA-binding domain.

The replication terminator protein (RTP) of Bacillus subtilis impedes replication fork movement in a polar mode upon binding as two interacting dimers to each of the replication termini. The mode of interaction of RTP with the terminus DNA is of considerable mechanistic significance because the DNA-protein complex not only localizes the helicase-blocking activity to the terminus, but also generates functional asymmetry from structurally symmetric protein dimers. The functional asymmetry is manifested in the polar impedance of replication fork movement. Although the crystal structure of the apoprotein has been solved, hitherto there was no direct evidence as to which parts of RTP were in contact with the replication terminus. Here we have used a variety of approaches, including saturation mutagenesis, genetic selection for DNA-binding mutants, photo cross-linking, biochemical and functional characterizations of the mutant proteins, and X-ray crystallography, to identify the regions of RTP that are either in direct contact with or are located within 11 angstroms of the replication terminus. The data show that the unstructured N-terminal arm, the alpha3 helix and the beta2 strand are involved in DNA binding. The mapping of amino acids of RTP in contact with DNA, confirms a 'winged helix' DNA-binding motif.

The dimer-dimer interaction surface of the replication terminator protein of Bacillus subtilis and termination of DNA replication.

The replication terminator protein (RTP) of Bacillus subtilis causes polar fork arrest at replication termini by sequence-specific interaction of two dimeric proteins with the terminus sequence. The crystal structure of the RTP protein has been solved, and the structure has already provide valuable clues regarding the structural basis of its function. However, it provides little information as to the surface of the protein involved in dimer-dimer interaction. Using site-directed mutagenesis, we have identified three sites on the protein that appear to mediate the dimer-dimer interaction. Crystallographic analysis of one of the mutant proteins (Y88F) showed that its structure is unaltered when compared to the wild-type protein. The locations of the three sites suggested a model for the dimer-dimer interaction that involves an association between two beta-ribbon motifs. This model is supported by a fourth mutation that was predicted to disrupt the interaction and was shown to do so. Biochemical analyses of these mutants provide compelling evidence that cooperative protein-protein interaction between two dimers of RTP is essential to impose polar blocks to the elongation of both DNA and RNA chains.

Crystal structure of the replication terminator protein from B. subtilis at 2.6 A.

The crystal structure of the replication terminator protein (RTP) of B. subtilis has been determined at 2.6 A resolution. As previously suggested by both biochemical and biophysical studies, the molecule exists as a symmetric dimer and is in the alpha + beta protein-folding class. The protein has several uncommon features, including an antiparallel coiled-coil, which serves as the dimerization domain, and both an alpha-helix and a beta-ribbon suitably positioned to interact with the major and minor grooves of B-DNA. A site has been identified on the surface of RTP that is biochemically and positionally suitable for interaction with the replication-specific helicase. Other features of the structure are consistent with the polar contrahelicase mechanism of the protein. A model of the interaction between RTP and its cognate DNA is presented.

Crystallization and preliminary structural analysis of the replication terminator protein of Bacillus subtilis.

The replication terminator protein (RTP) is a dimeric molecule that binds specific sequences within the replication terminus of the Bacillus subtilis chromosome and prevents the passage of replication forks. The gene for RTP has been expressed in Escherichia coli, and the protein has been purified in amounts sufficient for structural studies by nuclear magnetic resonance (NMR) and x-ray crystallography. One-dimensional NMR experiments show that the protein has a well-folded compact tertiary structure, as well as a high alpha-helical content. Circular dichroism (CD) studies confirm this finding and show that approximately 32% of the protein is alpha-helical. The terminator protein has been crystallized as monoclinic plates that diffract to better than 2.5 A and are suitable for high resolution structural analysis. Precession photographs show the space group to be C2 with unit cell dimensions a = 77 A, b = 53 A, c = 70 A, and beta = 90 degrees, and two molecules occupy the asymmetric unit. With a view to producing crystals of an RTP.DNA complex, gel-shift assays were performed to establish the shortest sequence of DNA that is required for tight binding to RTP. These clearly show that two turns of DNA are required, centered on an 8-base pair consensus sequence, to elicit relatively stable binding.

The biosynthesis of lipoic acid. Cloning of lip, a lipoate biosynthetic locus of Escherichia coli.

The lip gene of Escherichia coli has been cloned and sequenced. Subcloning of a 3-kilobase EcoRI/EcoRV restriction fragment from Clark-Carbon plasmid pLC15-5 into pUC18 gives a plasmid that complements two lipoate auxotrophs, W1485-lip2 and JRG33-lip9, and which expresses a protein of approximately 36,000 Da. Sequencing suggests that lip codes for a protein of 281 amino acids (31,350 Da), showing sequence similarity to biotin synthase. It is thus likely that lip encodes a sulfur insertion enzyme analogous to biotin synthase and that the sulfur insertion chemistries of the two systems are related. Unidirectional nested deletion experiments show that both lipoate auxotrophs are complemented by the same 500-base pair region at the 3' terminus of the lip gene, indicating that the mutations affecting lipoate biosynthesis are located in this region of the protein. A small open reading frame located immediately downstream of the lip gene codes for a small protein of unknown function.