In vitro and In vivo evidence demonstrating chronic absence of Ref-1 Cysteine 65 impacts Ref-1 folding configuration, redox signaling, proliferation and metastasis in pancreatic cancer.

Ref-1/APE1 (Redox Effector/Apurinic Endonuclease 1) is a multifunctional enzyme that serves as a redox factor for several transcription factors (TFs), e.g., NF-kB, HIF-1α, which in an oxidized state fail to bind DNA. Conversion of these TFs to a reduced state serves to regulate various biological responses such as cell growth, inflammation, and cellular metabolism. The redox activity involves a thiol exchange reaction for which Cys65 (C65) serves as the nucleophile. Using CRISPR editing in human pancreatic ductal adenocarcinoma (PDAC) cells, we changed C65 to Ala (C65A) in Ref-1 to evaluate alteration of Ref-1 redox dynamics as well as chronic loss of Ref-1 redox activity on cell signaling pathways, specifically those regulated by NF-kB and HIF-1α. The redox activity of Ref-1 requires partial unfolding to expose C65, which is buried in the folded structure. Labeling of Ref-1 with polyethylene glycol-maleimide (PEGm) provides a readout of reduced Cys residues in Ref-1 and thereby an assessment of partial unfolding in Ref-1. In comparing Ref-1WT vs Ref-1C65A cell lines, we found an altered distribution of oxidized versus reduced states of Ref-1. Accordingly, activation of NF-kB and HIF-1α in Ref-1C65A lines was significantly lower compared to Ref-1WT lines. The bioinformatic data revealed significant downregulation of metabolic pathways including OXPHOS in Ref-1C65A expressing clones compared to Ref-1WT line. Ref-1C65A also demonstrated reduced cell proliferation and use of tricarboxylic acid (TCA) substrates compared to Ref-1WT lines. A subcutaneous as well as PDAC orthotopic in vivo model demonstrated a significant reduction in tumor size, weight, and growth in the Ref-1C65A lines compared to the Ref-1WT lines. Moreover, mice implanted with Ref-1C65A redox deficient cells demonstrate significantly reduced metastatic burden to liver and lung compared to mice implanted with Ref-1 redox proficient cells. These results from the current study provide direct evidence that the chronic absence of Cys65 in Ref-1 results in redox inactivity of the protein in human PDAC cells, and subsequent biological results confirm a critical involvement of Ref-1 redox signaling and tumorigenic phenotype.

Evolution of the redox function in mammalian apurinic/apyrimidinic endonuclease.

Human apurinic/apyrimidinic endonuclease (hApe1) encodes two important functional activities: an essential base excision repair (BER) activity and a redox activity that regulates expression of a number of genes through reduction of their transcription factors, AP-1, NFkappaB, HIF-1alpha, CREB, p53 and others. The BER function is highly conserved from prokaryotes (E. coli exonuclease III) to humans (hApe1). Here, we provide evidence supporting a redox function unique to mammalian Apes. An evolutionary analysis of Ape sequences reveals that, of the 7 Cys residues, Cys 93, 99, 208, 296, and 310 are conserved in both mammalian and non-mammalian vertebrate Apes, while Cys 65 is unique to mammalian Apes. In the zebrafish Ape (zApe), selected as the vertebrate sequence most distant from human, the residue equivalent to Cys 65 is Thr 58. The wild-type zApe enzyme was tested for redox activity in both in vitro EMSA and transactivation assays and found to be inactive, similar to C65A hApe1. Substitution of Thr 58 with Cys in zApe, however, resulted in a redox active enzyme, suggesting that a Cys residue in this position is indeed critical for redox function. In order to further probe differences between redox active and inactive enzymes, we have determined the crystal structures of vertebrate redox inactive enzymes, the C65A human Ape1 enzyme and the zApe enzyme at 1.9 and 2.3A, respectively. Our results provide new insights on the redox function and highlight a dramatic gain-of-function activity for Ape1 in mammals not found in non-mammalian vertebrates or lower organisms.

A directed approach to improving the solubility of Moloney murine leukemia virus reverse transcriptase.

One of the difficulties that can impede structural work on a molecule of interest is limited solubility. Although functionally similar to the human immunodeficiency virus type-1 reverse transcriptase (HIV-1 RT), the Moloney murine leukemia virus reverse transcriptase (MMLV RT) differs both in architecture and solubility properties. Reverse transcriptase is an essential retroviral enzyme that replicates the single-stranded RNA genome of the retrovirus producing a double-stranded DNA copy, which is subsequently integrated into the host's genome. We have introduced a single amino acid substitution in the connection domain of an N-terminally truncated MMLV RT (L435K) that significantly improves the solubility of the enzyme eliminating the need for nonionic detergents in buffering storage solutions. The substituted enzyme retains near wild-type polymerase activity. An important consequence of the improved solubility of the L435K MMLV RT has been the ability to obtain diffraction quality crystals.

Structure of a pseudo-16-mer DNA with stacked guanines and two G-A mispairs complexed with the N-terminal fragment of Moloney murine leukemia virus reverse transcriptase.

The X-ray crystal structure at 2.0 A resolution of a DNA molecule complexed with the N-terminal fragment of Moloney murine leukemia virus reverse transcriptase (MMLV RT) has been determined. This method allows the study of nucleic acids in a unique and largely unfettered environment without the complicated lattice interactions typically observed in DNA-only crystal structures. Molecular-replacement phasing using only the protein provided readily interpretable electron density with no model bias for the DNA. The asymmetric unit of the structure consists of the protein molecule bound to the blunt end of a DNA 6/10-mer, which is composed of a six-base strand (5'-GTCGTC-3') and a ten-base strand (3'-CAGCAGGGCA-5'), resulting in a six-base-pair duplex with a four-base single-stranded overhang. In the crystal structure, the bases of the overhang reciprocally pair to yield a doubly nicked pseudo-hexadecamer primarily B-form DNA molecule. The pairing between the single strands gives two standard (G-C) Watson-Crick pairs and two G(anti)-A(anti) mispairs. The mispairs reside in a G-C-rich environment and the three consecutive guanines on the 10-mer impart interesting structural features to the pseudo-hexadecamer, such as the preference for a guanine stack, stretching the C-G base pairs flanking the mispair to the point of loss of intra-base-pair hydrogen bonding. The DNA was designed for the purpose of comparison with a previous structure, which was determined in the same crystal lattice. In all of the authors' previous fragment-DNA complexes, the nucleotide at the blunt-ended 3'-hydroxyl was a purine. Consistent with the proposed mechanistic role of interactions with the 3'-hydroxyl in processive DNA synthesis by RT, it was found that a pyrimidine at this position in the DNA makes indentical interactions with the strictly conserved Gly191 and the main chain of Leu115 of MMLV RT.

Using viral species specificity to define a critical protein/RNA interaction surface.

The Tap protein mediates the sequence-specific nuclear export of mRNAs bearing the retroviral constitutive transport element (CTE) and also plays a critical role in the sequence nonspecific export of cellular mRNAs. Previously, we have demonstrated that CTE function displays species specificity, that is, the CTE functions in human but not quail cells. Here, we demonstrate that quail Tap fails to support CTE function because it cannot bind the CTE. However, changing a single residue in quail Tap, glutamine 246, to arginine, the residue found in human Tap, rescues both CTE function and CTE binding. This residue, which is located on the exterior of a recently reported molecular structure of Tap, defines a surface on Tap that is critical for CTE binding. These data emphasize the potential importance of cross-species genetic complementation in the identification and characterization of cellular factors that are critical for different aspects of viral replication.

Substitution of Asp114 or Arg116 in the fingers domain of moloney murine leukemia virus reverse transcriptase affects interactions with the template-primer resulting in decreased processivity.

Reverse transcriptase, an essential retroviral DNA polymerase, replicates the single-stranded RNA genome of the retrovirus, producing a double-stranded DNA copy, which is subsequently integrated into the host's genome. Substitution of Ala for either Asp114 or Arg116, two highly conserved residues in the fingers domain of Moloney murine leukemia virus reverse transcriptase, results in enzymes (D114A or R116A) with significant defects in their abilities to processively synthesize DNA using RNA or DNA as a template. D114A and R116A enzymes also bind more weakly to template-primer in the presence of added deoxyribonucleotides, as seen by gel-shift analysis, but retain the ability to strand transfer and accumulate smaller RNase H cleavage products when compared to the wild-type enzyme. In addition, mutant proviruses, including D114A and R116A substitutions in Moloney murine leukemia virus reverse transcriptase, are not viable despite the presence of processed reverse transcriptase in the viral particles. A potential mechanistic role in processive synthesis for D114 and R116 is discussed in the context of our results, related studies on HIV-1 reverse transcriptase, and previous structural studies.

Structure-based moloney murine leukemia virus reverse transcriptase mutants with altered intracellular direct-repeat deletion frequencies.

Template switching rates of Moloney murine leukemia virus reverse transcriptase mutants were tested using a retroviral vector-based direct-repeat deletion assay. The reverse transcriptase mutants contained alterations in residues that modeling of substrates into the catalytic core had suggested might affect interactions with primer and/or template strands. As assessed by the frequency of functional lacZ gene generation from vectors in which lacZ was disrupted by insertion of a sequence duplication, the frequency of template switching varied more than threefold among fully replication-competent mutants. Some mutants displayed deletion rates that were lower and others displayed rates that were higher than that of wild-type virus. Replication for the mutants with the most significant alterations in template switching frequencies was similar to that of the wild type. These data suggest that reverse transcriptase template switching rates can be altered significantly without destroying normal replication functions.

Use of an N-terminal fragment from moloney murine leukemia virus reverse transcriptase to facilitate crystallization and analysis of a pseudo-16-mer DNA molecule containing G-A mispairs.

Complexation with the N-terminal fragment of Moloney murine leukemia virus reverse transcriptase offers a novel method of obtaining crystal structures of nucleic acid duplexes, which can be phased by molecular replacement. This method is somewhat similar to the method of using a monoclonal antibody Fab fragment complexed to the molecule of interest in order to obtain crystals suitable for X-ray crystallographic analysis. Here a novel DNA structure including two G-A mispairs in a pseudo-hexadecamer determined at 2.3 A resolution in a complex with the N-terminal fragment is reported. This structure has an asymmetric unit consisting of the protein molecule bound to the blunt end of a DNA 6/10-mer, which is composed of a six-base strand (5'-CTCGTG-3') and a ten-base strand (3'-GAGCACGGCA-5'). The 6/10-mer is thus composed of a six-base-pair duplex with a four-base single-stranded overhang. In the crystal structure, the bases of the overhang are reciprocally paired (symmetry element -x - 1, -y, z), yielding a doubly nicked pseudo-hexadecamer primarily B-form DNA molecule, which has some interesting A-like structural features. The pairing between the single strands results in two standard (G-C) Watson-Crick pairs and two G-A mispairs. The structural DNA model can accommodate either a standard syn or a standard anti conformation for the 5'-terminal adenine of the ten-base strand of the DNA based on analysis of simulated-annealing omit maps. Although the DNA model here includes nicks in the phosphodiester backbone, modeling of an intact phosphodiester backbone results in a very similar DNA model and indicates that the structure is biologically relevant.

Crystal structures of an N-terminal fragment from Moloney murine leukemia virus reverse transcriptase complexed with nucleic acid: functional implications for template-primer binding to the fingers domain.

Reverse transcriptase (RT) serves as the replicative polymerase for retroviruses by using RNA and DNA-directed DNA polymerase activities coupled with a ribonuclease H activity to synthesize a double-stranded DNA copy of the single-stranded RNA genome. In an effort to obtain detailed structural information about nucleic acid interactions with reverse transcriptase, we have determined crystal structures at 2.3 A resolution of an N-terminal fragment from Moloney murine leukemia virus reverse transcriptase complexed to blunt-ended DNA in three distinct lattices. This fragment includes the fingers and palm domains from Moloney murine leukemia virus reverse transcriptase. We have also determined the crystal structure at 3.0 A resolution of the fragment complexed to DNA with a single-stranded template overhang resembling a template-primer substrate. Protein-DNA interactions, which are nearly identical in each of the three lattices, involve four conserved residues in the fingers domain, Asp114, Arg116, Asn119 and Gly191. DNA atoms involved in the interactions include the 3'-OH group from the primer strand and minor groove base atoms and sugar atoms from the n-2 and n-3 positions of the template strand, where n is the template base that would pair with an incoming nucleotide. The single-stranded template overhang adopts two different conformations in the asymmetric unit interacting with residues in the beta4-beta5 loop (beta3-beta4 in HIV-1 RT). Our fragment-DNA complexes are distinct from previously reported complexes of DNA bound to HIV-1 RT but related in the types of interactions formed between protein and DNA. In addition, the DNA in all of these complexes is bound in the same cleft of the enzyme. Through site-directed mutagenesis, we have substituted residues that are involved in binding DNA in our crystal structures and have characterized the resulting enzymes. We now propose that nucleic acid binding to the fingers domain may play a role in translocation of nucleic acid during processive DNA synthesis and suggest that our complex may represent an intermediate in this process.

Cloning, expression, and purification of a catalytic fragment of Moloney murine leukemia virus reverse transcriptase: crystallization of nucleic acid complexes.

Reverse transcriptase is an essential retroviral enzyme that uses RNA- and DNA-directed DNA polymerase activities as well as an RNaseH activity to synthesize a double-stranded DNA copy of the single-stranded RNA genome. In an effort to obtain high-resolution structural information regarding the polymerase active site of reverse transcriptase, we have pursued studies on a catalytic fragment from Moloney murine leukemia virus reverse transcriptase. DNA encoding the catalytic fragment, defined originally by limited proteolytic digestion, has been cloned, and the protein has been expressed and purified from Escherichia coli. The fragment obtained by limited proteolytic digestion and the bacterially expressed fragnment retain polymerase activity. Crystallization studies involving nucleic acid complexes with a catalytic fragment from both sources are reported, including variables screened to improve crystals and cryocooling. Three crystal forms of catalytic fragment-nucleic acid complexes have been characterized, which all contain at least two protein molecules in the asymmetric unit. As isolated, the catalytic fragment is monomeric. This analysis indicates that the enzyme dimerizes in the presence of nucleic acid.

Conferring RNA polymerase activity to a DNA polymerase: a single residue in reverse transcriptase controls substrate selection.

The traditional classification of nucleic acid polymerases as either DNA or RNA polymerases is based, in large part, on their fundamental preference for the incorporation of either deoxyribonucleotides or ribonucleotides during chain elongation. The refined structure determination of Moloney murine leukemia virus reverse transcriptase, a strict DNA polymerase, recently allowed the prediction that a single amino acid residue at the active site might be responsible for the discrimination against the 2'OH group of an incoming ribonucleotide. Mutation of this residue resulted in a variant enzyme now capable of acting as an RNA polymerase. In marked contrast to the wild-type enzyme, the K(m) of the mutant enzyme for ribonucleotides was comparable to that for deoxyribonucleotides. The results are consistent with proposals of a common evolutionary origin for both classes of enzymes and support models of a common mechanism of nucleic acid synthesis underlying catalysis by all such polymerases.

Mechanistic implications from the structure of a catalytic fragment of Moloney murine leukemia virus reverse transcriptase.

BACKGROUND: Reverse transcriptase (RT) converts the single-stranded RNA genome of a retrovirus into a double-stranded DNA copy for integration into the host genome. This process requires ribonuclease H as well as RNA- and DNA-directed DNA polymerase activities. Although the overall organization of HIV-1 RT is known from previously reported crystal structures, no structure of a complex including a metal ion, which is essential for its catalytic activity, has been reported. RESULTS: Here we describe the structures at 1.8 Angstrum resolution of a catalytically active fragment of RT from Moloney murine leukemia virus (MMLV) and at 2.6 Angstrum of a complex of this fragment with Mn2+ coordinated in the polymerase active site. On the basis of similarities with HIV-1 RT and rat DNA polymerase beta, we have modeled template/primer and deoxyribonucleoside 5'-triphosphate substrates into the MMLV RT structure. CONCLUSIONS: Our model, in the context of the disposition of evolutionarily conserved residues seen here at high resolution, provides new insights into the mechanisms of catalysis, fidelity, processivity and discrimination between deoxyribose and ribose nucleotides.

Footprint analysis of replicating murine leukemia virus reverse transcriptase.

Replication complexes that contained either murine leukemia virus reverse transcriptase (MLV RT) or a variant reverse transcriptase without a ribonuclease (RNase) H domain (delta RH MLV RT) were visualized by enzymatic footprinting. Wild-type MLV RT protected template nucleotides +6 to -27, and primer nucleotides -1 to -26 of primers that had first been extended by one or four nucleotides. Although it catalyzed DNA synthesis, delta RH MLV RT stably bound template-primer only under conditions of reduced ionic strength and protected the duplex portion only as far as position -15. Despite altered hydrolysis profiles, both enzymes covered primarily the template-primer duplex, contradicting recent predictions based on the structure of rat DNA polymerase beta.

Crystallographic structure of the nitrogenase iron protein from Azotobacter vinelandii.

The nitrogenase enzyme system catalyzes the ATP (adenosine triphosphate)-dependent reduction of dinitrogen to ammonia during the process of nitrogen fixation. Nitrogenase consists of two proteins: the iron (Fe)-protein, which couples hydrolysis of ATP to electron transfer, and the molybdenum-iron (MoFe)-protein, which contains the dinitrogen binding site. In order to address the role of ATP in nitrogen fixation, the crystal structure of the nitrogenase Fe-protein from Azotobacter vinelandii has been determined at 2.9 angstrom (A) resolution. Fe-protein is a dimer of two identical subunits that coordinate a single 4Fe:4S cluster. Each subunit folds as a single alpha/beta type domain, which together symmetrically ligate the surface exposed 4Fe:4S cluster through two cysteines from each subunit. A single bound ADP (adenosine diphosphate) molecule is located in the interface region between the two subunits. Because the phosphate groups of this nucleotide are approximately 20 A from the 4Fe:4S cluster, it is unlikely that ATP hydrolysis and electron transfer are directly coupled. Instead, it appears that interactions between the nucleotide and cluster sites must be indirectly coupled by allosteric changes occurring at the subunit interface. The coupling between protein conformation and nucleotide hydrolysis in Fe-protein exhibits general similarities to the H-Ras p21 and recA proteins that have been recently characterized structurally. The Fe-protein structure may be relevant to the functioning of other biochemical energy-transducing systems containing two nucleotide-binding sites, including membrane transport proteins.

Cross-linking of nitrogenase components. Structure and activity of the covalent complex.

The nitrogenase complex from Azotobacter vinelandii is composed of the MoFe protein (Av1), an alpha 2 beta 2 tetramer, and the Fe protein (Av2), a gamma 2 dimer. During turnover of the enzyme, electrons are transferred from Av2 to Av1 in parallel with the hydrolysis of MgATP. Using the cross-linking reagent, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide, we have identified some of the properties of the complex between the two components. The cross-linking reaction was highly specific yielding a single apparent Mr = 97,000 protein. The amount of cross-linked product was essentially independent of whether MgATP or MgADP were in the reaction. Also, the amount was maximum at high ratios of Av2 to Av1. The Mr = 97,000 protein was characterized by amino acid analysis and Edman degradation and was found to be consistent with a 1:1 complex of an Av2 gamma subunit and an Av1 beta subunit (the amino terminal serine subunit). The complex was no longer active in the nitrogenase reaction which supports, but does not prove, the requirement for dissociation of the complex after each electron transferred. Nitrogenase activity and cross-linking were inhibited in an identical way by NaCl, which suggests that electrostatic forces are critical to the formation of the electron transfer complex.