Allele-specific suppression in C. elegans reveals details of EMS mutagenesis and a possible moonlighting interaction between the vesicular acetylcholine transporter and ERD2 receptors

A missense mutant, unc-17(e245), which affects the Caenorhabditis elegans vesicular acetylcholine transporter UNC-17, has a severe uncoordinated phenotype, allowing efficient selection of dominant suppressors that revert this phenotype to wild-type. Such selections permitted isolation of numerous suppressors after EMS (ethyl methanesulfonate) mutagenesis, leading to demonstration of delays in mutation fixation after initial EMS treatment, as has been shown in T4 bacteriophage but not previously in eukaryotes. Three strong dominant extragenic suppressor loci have been defined, all of which act specifically on allele e245, which causes a G347R mutation in UNC-17. Two of the suppressors (sup-1 and sup-8/snb-1) have previously been shown to encode synaptic proteins able to interact directly with UNC-17. We found that the remaining suppressor, sup-2, corresponds to a mutation in erd-2.1, which encodes an endoplasmic reticulum retention protein; sup-2 causes a V186E missense mutation in transmembrane helix 7 of ERD-2.1. The same missense change introduced into the redundant paralogous gene erd-2.2 also suppressed unc-17(e245). Suppression presumably occurred by compensatory charge interactions between transmembrane helices of UNC-17 and ERD-2.1 or ERD-2.2, as previously proposed in work on suppression by SUP-1(G84E) or SUP-8(I97D)/synaptobrevin. erd-2.1(V186E) homozygotes were fully viable, but erd-2.1(V186E); erd-2.2(RNAi) exhibited synthetic lethality (like erd-2.1(RNAi); erd-2.2(RNAi)), indicating that the missense change in ERD-2.1 impairs its normal function in the secretory pathway but may allow it to adopt a novel moonlighting function as an unc-17 suppressor.

Systematic phenomics analysis of autism-associated genes reveals parallel networks underlying reversible impairments in habituation

A major challenge facing the genetics of autism spectrum disorders (ASDs) is the large and growing number of candidate risk genes and gene variants of unknown functional significance. Here, we used Caenorhabditis elegans to systematically functionally characterize ASD-associated genes in vivo. Using our custom machine vision system, we quantified 26 phenotypes spanning morphology, locomotion, tactile sensitivity, and habituation learning in 135 strains each carrying a mutation in an ortholog of an ASD-associated gene. We identified hundreds of genotype-phenotype relationships ranging from severe developmental delays and uncoordinated movement to subtle deficits in sensory and learning behaviors. We clustered genes by similarity in phenomic profiles and used epistasis analysis to discover parallel networks centered on CHD8•chd-7 and NLGN3•nlg-1 that underlie mechanosensory hyperresponsivity and impaired habituation learning. We then leveraged our data for in vivo functional assays to gauge missense variant effect. Expression of wild-type NLG-1 in nlg-1 mutant C. elegans rescued their sensory and learning impairments. Testing the rescuing ability of conserved ASD-associated neuroligin variants revealed varied partial loss of function despite proper subcellular localization. Finally, we used CRISPR-Cas9 auxin-inducible degradation to determine that phenotypic abnormalities caused by developmental loss of NLG-1 can be reversed by adult expression. This work charts the phenotypic landscape of ASD-associated genes, offers in vivo variant functional assays, and potential therapeutic targets for ASD.

UNC-41/stonin functions with AP2 to recycle synaptic vesicles in Caenorhabditis elegans

The recycling of synaptic vesicles requires the recovery of vesicle proteins and membrane. Members of the stonin protein family (Drosophila Stoned B, mammalian stonin 2) have been shown to link the synaptic vesicle protein synaptotagmin to the endocytic machinery. Here we characterize the unc-41 gene, which encodes the stonin ortholog in the nematode Caenorhabditis elegans. Transgenic expression of Drosophila stonedB rescues unc-41 mutant phenotypes, demonstrating that UNC-41 is a bona fide member of the stonin family. In unc-41 mutants, synaptotagmin is present in axons, but is mislocalized and diffuse. In contrast, UNC-41 is localized normally in synaptotagmin mutants, demonstrating a unidirectional relationship for localization. The phenotype of snt-1 unc-41 double mutants is stronger than snt-1 mutants, suggesting that UNC-41 may have additional, synaptotagmin-independent functions. We also show that unc-41 mutants have defects in synaptic vesicle membrane endocytosis, including a ∼50% reduction of vesicles in both acetylcholine and GABA motor neurons. These endocytic defects are similar to those observed in apm-2 mutants, which lack the µ2 subunit of the AP2 adaptor complex. However, no further reduction in synaptic vesicles was observed in unc-41 apm-2 double mutants, suggesting that UNC-41 acts in the same endocytic pathway as µ2 adaptin.

Neuroligin-deficient mutants of C. elegans have sensory processing deficits and are hypersensitive to oxidative stress and mercury toxicity

Neuroligins are postsynaptic cell adhesion proteins that bind specifically to presynaptic membrane proteins called neurexins. Mutations in human neuroligin genes are associated with autism spectrum disorders in some families. The nematode Caenorhabditis elegans has a single neuroligin gene (nlg-1), and approximately a sixth of C. elegans neurons, including some sensory neurons, interneurons and a subset of cholinergic motor neurons, express a neuroligin transcriptional reporter. Neuroligin-deficient mutants of C. elegans are viable, and they do not appear deficient in any major motor functions. However, neuroligin mutants are defective in a subset of sensory behaviors and sensory processing, and are hypersensitive to oxidative stress and mercury compounds; the behavioral deficits are strikingly similar to traits frequently associated with autism spectrum disorders. Our results suggest a possible link between genetic defects in synapse formation or function, and sensitivity to environmental factors in the development of autism spectrum disorders.

Choline transport and de novo choline synthesis support acetylcholine biosynthesis in Caenorhabditis elegans cholinergic neurons

The cho-1 gene in Caenorhabditis elegans encodes a high-affinity plasma-membrane choline transporter believed to be rate limiting for acetylcholine (ACh) synthesis in cholinergic nerve terminals. We found that CHO-1 is expressed in most, but not all cholinergic neurons in C. elegans. cho-1 null mutants are viable and exhibit mild deficits in cholinergic behavior; they are slightly resistant to the acetylcholinesterase inhibitor aldicarb, and they exhibit reduced swimming rates in liquid. cho-1 mutants also fail to sustain swimming behavior; over a 33-min time course, cho-1 mutants slow down or stop swimming, whereas wild-type animals sustain the initial rate of swimming over the duration of the experiment. A functional CHO-1GFP fusion protein rescues these cho-1 mutant phenotypes and is enriched at cholinergic synapses. Although cho-1 mutants clearly exhibit defects in cholinergic behaviors, the loss of cho-1 function has surprisingly mild effects on cholinergic neurotransmission. However, reducing endogenous choline synthesis strongly enhances the phenotype of cho-1 mutants, giving rise to a synthetic uncoordinated phenotype. Our results indicate that both choline transport and de novo synthesis provide choline for ACh synthesis in C. elegans cholinergic neurons.

Differential expression and function of synaptotagmin 1 isoforms in Caenorhabditis elegans

Synaptotagmin 1, encoded by the snt-1 gene in Caenorhabditis elegans, is a major synaptic vesicle protein containing two Ca(2+)-binding (C2) domains. Alternative splicing gives rise to two synaptotagmin 1 isoforms, designated SNT-1A and SNT-1B, which differ in amino acid sequence in the third, fourth, and fifth beta-strands of the second C2 domain (C2B). We report here that expression of either SNT-1 isoform under control of a strong pan-neural promoter fully rescues the snt-1 null phenotype. Furthermore, C-terminal fusions of either isoform with GFP are trafficked properly to synapses and are fully functional, unlike synaptotagmin 1Colon, two colonsGFP fusions in mice. Analysis of isoform expression with genomic GFP reporter constructs revealed that the SNT-1A and-1B isoforms are differentially expressed and localized in the C. elegans nervous system. We also report molecular, behavioral, and immunocytochemical analyses of twenty snt-1 mutations. One of these mutations, md259, specifically disrupts expression of the SNT-1A isoform and has defects in a subset of synaptotagmin 1-mediated behaviors. A second mutation, md220, is an in-frame 9-bp deletion that removes a conserved tri-peptide sequence (VIL) in the second beta-strand of the C2B domain and disrupts the proper intracellular trafficking of synaptotagmin. Site-directed mutagenesis of a functional SNT-1Colon, two colonsGFP fusion protein was used to examine the potential role of the VIL sequence in synaptotagmin trafficking. Although our results suggest the VIL sequence is most likely not a specific targeting motif, the use of SNT-1Colon, two colonsGFP fusions has great potential for investigating synaptotagmin trafficking and localization.

The Caenorhabditis elegans snf-11 gene encodes a sodium-dependent GABA transporter required for clearance of synaptic GABA

Sodium-dependent neurotransmitter transporters participate in the clearance and/or recycling of neurotransmitters from synaptic clefts. The snf-11 gene in Caenorhabditis elegans encodes a protein of high similarity to mammalian GABA transporters (GATs). We show here that snf-11 encodes a functional GABA transporter; SNF-11-mediated GABA transport is Na+ and Cl- dependent, has an EC50 value of 168 microM, and is blocked by the GAT1 inhibitor SKF89976A. The SNF-11 protein is expressed in seven GABAergic neurons, several additional neurons in the head and retrovesicular ganglion, and three groups of muscle cells. Therefore, all GABAergic synapses are associated with either presynaptic or postsynaptic (or both) expression of SNF-11. Although a snf-11 null mutation has no obvious effects on GABAergic behaviors, it leads to resistance to inhibitors of acetylcholinesterase. In vivo, a snf-11 null mutation blocks GABA uptake in at least a subset of GABAergic cells; in a cell culture system, all GABA uptake is abolished by the snf-11 mutation. We conclude that GABA transport activity is not essential for normal GABAergic function in C. elegans and that the localization of SNF-11 is consistent with a GABA clearance function rather than recycling.

Identification of small molecule synthetic inhibitors of DNA polymerase beta by NMR chemical shift mapping

DNA polymerase beta (beta-pol) plays a central role in repair of damaged DNA bases by base excision repair (BER) pathways. A predominant phenotype of beta-pol null mouse fibroblasts is hypersensitivity to the DNA-methylating agent methyl methanesulfonate. Residues in the 8-kDa domain of beta-pol that seem to interact with a known natural product beta-pol inhibitor, koetjapic acid, were identified by NMR chemical shift mapping. The data implicate the binding pocket as the hydrophobic cleft between helix-2 and helix-4, which provides the DNA binding and deoxyribose phosphate lyase activities of the enzyme. Nine structurally related synthetic compounds, containing aromatic or other hydrophobic groups in combination with two carboxylate groups, were then tested. They were found to bind to the same or a very similar region on the surface of the enzyme. The ability of these compounds to potentiate methyl methanesulfonate cytotoxicity, an indicator of cellular BER capacity, in wild-type and beta-pol null mouse fibroblasts, was next ascertained. The most active and beta-pol-specific of these agents, pamoic acid, was further characterized and found to be an inhibitor of the deoxyribose phosphate lyase and DNA polymerase activities of purified beta-pol on a BER substrate. Our results illustrate that NMR-based mapping techniques can be used in the design of small molecule enzyme inhibitors including those with potential use in a clinical setting.

Critical residues of the Caenorhabditis elegans unc-2 voltage-gated calcium channel that affect behavioral and physiological properties

The Caenorhabditis elegans unc-2 gene encodes a voltage-gated calcium channel alpha1 subunit structurally related to mammalian dihydropyridine-insensitive high-threshold channels. In the present paper we describe the characterization of seven alleles of unc-2. Using an unc-2 promoter-tagged green fluorescent protein construct, we show that unc-2 is primarily expressed in motor neurons, several subsets of sensory neurons, and the HSN and VC neurons that control egg laying. Examination of behavioral phenotypes, including defecation, thrashing, and sensitivities to aldicarb and nicotine suggests that UNC-2 acts presynaptically to mediate both cholinergic and GABAergic neurotransmission. Sequence analysis of the unc-2 alleles shows that e55, ra605, ra606, ra609, and ra610 all are predicted to prematurely terminate and greatly reduce or eliminate unc-2 function. In contrast, the ra612 and ra614 alleles are missense mutations resulting in the substitution of highly conserved residues in the C terminus and the domain IVS4-IVS5 linker, respectively. Heterologous expression of a rat brain P/Q-type channel containing the ra612 mutation shows that the glycine to arginine substitution affects a variety of channel characteristics, including the voltage dependence of activation, steady-state inactivation, as well as channel kinetics. Overall, our findings suggest that UNC-2 plays a pivotal role in mediating a number of physiological processes in the nematode and also defines a number of critical residues important for calcium channel function in vivo.

Site-directed mutagenesis analysis of the structural interaction of the single-strand-break repair protein, X-ray cross-complementing group 1, with DNA polymerase beta

Human X-ray cross-complementing group 1 (XRCC1) is a single-strand DNA break repair protein which forms a base excision repair (BER) complex with DNA polymerase beta (beta-Pol). Here we report a site- directed mutational analysis in which 16 mutated versions of the XRCC1 N-terminal domain (XRCC1-NTD) were constructed on the basis of previous NMR results that had implicated the proximity of various surface residues to beta-Pol. Mutant proteins defective in XRCC1-NTD interaction with beta-Pol and with a beta-Pol-gapped DNA complex were determined by gel filtration chromatography and a gel mobility shift assay. The interaction surface determined from the mutated residues was found to encompass beta-strand D and E of the five-stranded beta-sheet (betaABGDE) and the protruding alpha2 helix of the XRCC1-NTD. Mutations that included F67A (betaD), E69K (betaD), V86R (betaE) on the five-stranded beta-sheet and deletion of the alpha2 helix, but not mutations within alpha2, abolished binding of the XRCC1-NTD to beta-Pol. A Y136A mutant abolished beta-Pol binding, and a R109S mutant reduced beta-Pol binding. E98K, E98A, N104A, Y136A, R109S, K129E, F142A, R31A/K32A/R34A and delta-helix-2 mutants displayed temperature dependent solubility. These findings confirm the importance of the alpha2 helix and the betaD and betaE strands of XRCC1-NTD to the energetics of beta-Pol binding. Establishing the direct contacts in the beta-Pol XRCC1 complex is a critical step in understanding how XRCC1 fulfills its numerous functions in DNA BER.

Relaxation-based structure refinement and backbone molecular dynamics of the dynein motor domain-associated light chain

The light chain 1 (LC1) polypeptide is a member of the leucine-rich repeat protein family and binds at or near the ATP hydrolytic site within the motor domain of the gamma heavy chain from Chlamydomonas outer arm dynein. It consists of an N-terminal helix, a central barrel formed from six leucine-rich repeats that fold as beta beta alpha units, and a C-terminal helical domain that protrudes from the main axis defined by the leucine-rich repeats. Interaction with the gamma heavy chain is likely mediated through a hydrophobic patch on the larger beta sheet face, and the C-terminal region is predicted to insert into the dynein ATP hydrolytic site. Here we have used 1H-15N heteronuclear relaxation measurements obtained at 500 and 600 MHz to refine and validate the LC1 solution structure. In this refined structure, the C-terminal helix is significantly reoriented by more than 20 degrees as compared to the control and provides a more precise understanding of the potential regulatory role of this domain. We also employed the refined structure to perform a dynamic analysis of LC1 using the 600 MHz data set. These results, which were cross validated using the 500 MHz data set, strongly support identification of the predicted LC1 binding surfaces and provide additional insight into the interaction mechanisms of leucine-rich repeat proteins.

Mapping of the interaction interface of DNA polymerase beta with XRCC1

Residues of DNA polymerase beta (beta-Pol) that interact with the DNA repair protein XRCC1 have been determined by NMR chemical shift mapping (CSM) and mutagenesis. 15N/(13)C/(2)H/(1)H,(13)C-methyl(Leu,Ile,Val)-labeled beta-Pol palm-thumb domain was used for assignments of the 1H, 15N, and 13C resonances used for CSM of the palm-thumb on forming the 40 kDa complex with the XRCC1 N-terminal domain (NTD). Large chemical shift changes were observed in the thumb on complexation. 15N relaxation data indicate reduction in high-frequency motion for a thumb loop and three palm turn/loops, which showed concomitant chemical shift changes on complexation. A deltaV303-V306 deletion and an L301R/V303R/V306R triple mutation abolished complex formation due to loss in hydrophobicity. In an updated model, the thumb-loop of beta-Pol contacts an edge/face region of the beta sheet of the XRCC1 NTD, while the beta-Pol palm weakly contacts the alpha2 helix.

Solution structure of a viral DNA repair polymerase

DNA polymerase X (Pol X) from the African swine fever virus (ASFV) specifically binds intermediates in the single-nucleotide base-excision repair process, an activity indicative of repair function. In addition, Pol X catalyzes DNA polymerization with low nucleotide-insertion fidelity. The structural mechanisms by which DNA polymerases confer high or low fidelity in DNA polymerization remain to be elucidated. The three-dimensional structure of Pol X has been determined. Unlike other DNA polymerases, Pol X is formed from only a palm and a C-terminal subdomain. Pol X has a novel palm subdomain fold, containing a positively charged helix at the DNA binding surface. Purine deoxynucleoside triphosphate (dNTP) substrates bind between the palm and C-terminal subdomain, at a dNTP-binding helix, and induce a unique conformation in Pol X. The purine dNTP-bound conformation and high binding affinity for dGTP-Mg(2+) of Pol X may contribute to its low fidelity.

UNC-52/perlecan isoform diversity and function in Caenorhabditis elegans

The unc-52 gene encodes the nematode homologue of mammalian perlecan, the major heparan sulphate proteoglycan of the extracellular matrix. This is a large complex protein with regions similar to low-density lipoprotein receptors, laminin and neural cell-adhesion molecules. Three major classes of UNC-52/perlecan isoforms are produced through alternative splicing, and these distinct proteins exhibit complex spatial and temporal expression patterns throughout development. The unc-52 gene plays an essential role in myofilament assembly in body-wall muscle during embryonic development.

Solution structure of the catalytic domain of gammadelta resolvase. Implications for the mechanism of catalysis

The site-specific DNA recombinase, gammadelta resolvase, from Escherichia coli catalyzes recombination of res site-containing plasmid DNA to two catenated circular DNA products. The catalytic domain (residues 1-105), lacking a C-terminal dimerization interface, has been constructed and the NMR solution structure of the monomer determined. The RMSD of the NMR conformers for residues 2-92 excluding residues 37-45 and 64-73 is 0.41 A for backbone atoms and 0.88 A for all heavy atoms. The NMR solution structure of the monomeric catalytic domain (residues 1-105) was found to be formed by a four-stranded parallel beta-sheet surrounded by three helices. The catalytic domain (residues 1-105), deficient in the C-terminal dimerization domain, was monomeric at high salt concentration, but displayed unexpected dimerization at lower ionic strength. The unique solution dimerization interface at low ionic strength was mapped by NMR. With respect to previous crystal structures of the dimeric catalytic domain (residues 1-140), differences in the average conformation of active-site residues were found at loop 1 containing the catalytic S10 nucleophile, the beta1 strand containing R8, and at loop 3 containing D67, R68 and R71, which are required for catalysis. The active-site loops display high-frequency and conformational backbone dynamics and are less well defined than the secondary structures. In the solution structure, the D67 side-chain is proximal to the S10 side-chain making the D67 carboxylate group a candidate for activation of S10 through general base catalysis. Four conserved Arg residues can function in the activation of the phosphodiester for nucleophilic attack by the S10 hydroxyl group. A mechanism for covalent catalysis by this class of recombinases is proposed that may be related to dimer interface dissociation.

Structural basis for the topological specificity function of MinE

Correct positioning of the division septum in Escherichia coli depends on the coordinated action of the MinC, MinD and MinE proteins. Topological specificity is conferred on the MinCD division inhibitor by MinE, which counters MinCD activity only in the vicinity of the preferred midcell division site. Here we report the structure of the homodimeric topological specificity domain of Escherichia coli MinE and show that it forms a novel alphabeta sandwich. Structure-directed mutagenesis of conserved surface residues has enabled us to identify a spatially restricted site on the surface of the protein that is critical for the topological specificity function of MinE.

The UNC-112 gene in Caenorhabditis elegans encodes a novel component of cell-matrix adhesion structures required for integrin localization in the muscle cell membrane

Embryos homozygous for mutations in the unc-52, pat-2, pat-3, and unc-112 genes of C. elegans exhibit a similar Pat phenotype. Myosin and actin are not organized into sarcomeres in the body wall muscle cells of these mutants, and dense body and M-line components fail to assemble. The unc-52 (perlecan), pat-2 (alpha-integrin), and pat-3 (beta-integrin) genes encode ECM or transmembrane proteins found at the cell-matrix adhesion sites of both dense bodies and M-lines. This study describes the identification of the unc-112 gene product, a novel, membrane-associated, intracellular protein that colocalizes with integrin at cell-matrix adhesion complexes. The 720-amino acid UNC-112 protein is homologous to Mig-2, a human protein of unknown function. These two proteins share a region of homology with talin and members of the FERM superfamily of proteins. We have determined that a functional UNC-112::GFP fusion protein colocalizes with PAT-3/beta-integrin in both adult and embryonic body wall muscle. We also have determined that UNC-112 is required to organize PAT-3/beta-integrin after it is integrated into the basal cell membrane, but is not required to organize UNC-52/perlecan in the basement membrane, nor for DEB-1/vinculin to localize with PAT-3/beta-integrin. Furthermore, UNC-112 requires the presence of UNC-52/perlecan and PAT-3/beta-integrin, but not DEB-1/vinculin to become localized to the muscle cell membrane.

Solution structure of a dynein motor domain associated light chain

Dyneins are molecular motors that translocate towards the minus ends of microtubules. In Chlamydomonas flagellar outer arm dynein, light chain 1 (LC1) associates with the nucleotide binding region within the gamma heavy chain motor domain and consists of a central leucine-rich repeat section that folds as a cylindrical right handed spiral formed from six beta-beta-alpha motifs. This central cylinder is flanked by terminal helical subdomains. The C-terminal helical domain juts out from the cylinder and is adjacent to a hydrophobic surface within the repeat region that is proposed to interact with the dynein heavy chain. The position of the C-terminal domain on LC1 and the unexpected structural similarity between LC1 and U2A' from the human spliceosome suggest that this domain interacts with the dynein motor domain.

Domain specific interaction in the XRCC1-DNA polymerase beta complex

XRCC1 (X-ray cross-complementing group 1) is a DNA repair protein that forms complexes with DNA polymerase beta (beta-Pol), DNA ligase III and poly-ADP-ribose polymerase in the repair of DNA single strand breaks. The domains in XRCC1 have been determined, and characterization of the domain-domain interaction in the XRCC1-beta-Pol complex has provided information on the specificity and mechanism of binding. The domain structure of XRCC1, determined using limited proteolysis, was found to include an N-terminal domain (NTD), a central BRCT-I (breast cancer susceptibility protein-1) domain and a C-terminal BRCT-II domain. The BRCT-I-linker-BRCT-II C-terminal fragment and the linker-BRCT-II C-terminal fragment were relatively stable to proteolysis suggestive of a non-random conformation of the linker. A predicted inner domain was found not to be stable to proteolysis. Using cross-linking experiments, XRCC1 was found to bind intact beta-Pol and the beta-Pol 31 kDa domain. The XRCC1-NTD(1-183)(residues 1-183) was found to bind beta-Pol, the beta-Pol 31 kDa domain and the beta-Pol C-terminal palm-thumb (residues 140-335), and the interaction was further localized to XRCC1-NTD(1-157)(residues 1-157). The XRCC1-NTD(1-183)-beta-Pol 31 kDa domain complex was stable at high salt (1 M NaCl) indicative of a hydrophobic contribution. Using a yeast two-hybrid screen, polypeptides expressed from two XRCC1 constructs, which included residues 36-355 and residues 1-159, were found to interact with beta-Pol, the beta-Pol 31 kDa domain, and the beta-Pol C-terminal thumb-only domain polypeptides expressed from the respective beta-Pol constructs. Neither the XRCC1-NTD(1-159), nor the XRCC1(36-355)polypeptide was found to interact with a beta-Pol thumbless polypeptide. A third XRCC1 polypeptide (residues 75-212) showed no interaction with beta-Pol. In quantitative gel filtration and analytical ultracentrifugation experiments, the XRCC1-NTD(1-183)was found to bind beta-Pol and its 31 kDa domain in a 1:1 complex with high affinity (K(d) of 0.4-2.4 microM). The combined results indicate a thumb-domain specific 1:1 interaction between the XRCC1-NTD(1-159)and beta-Pol that is of an affinity comparable to other binding interactions involving beta-Pol.

Mapping of the 5'-2-deoxyribose-5-phosphate lyase active site in DNA polymerase beta by mass spectrometry

The mechanism of the 5'-2-deoxyribose-5-phosphate lyase reaction catalyzed by mammalian DNA beta-polymerase (beta-pol) was investigated using a cross-linking methodology in combination with mass spectrometric analyses. The approach included proteolysis of the covalently cross-linked protein-DNA complex with trypsin, followed by isolation, peptide mapping, and mass spectrometric and tandem mass spectrometric analyses. The 8-kDa domain of beta-pol was covalently cross-linked to a 5'-2-deoxyribose-5-phosphate-containing DNA substrate by sodium borohydride reduction. Using tandem mass spectrometry, the location of the DNA adduct on the 8-kDa domain was unequivocally determined to be at the Lys(72) residue. No additional amino acid residues were found as minor cross-linked species. These data allow assignment of Lys(72) as the sole Schiff base nucleophile in the 8-kDa domain of beta-pol. These results provide the first direct evidence in support of a catalytic mechanism involving nucleophilic attack by Lys(72) at the abasic site.

Backbone dynamics and refined solution structure of the N-terminal domain of DNA polymerase beta. Correlation with DNA binding and dRP lyase activity

Mammalian DNA polymerase beta functions in the base excision DNA repair pathway filling in short patches (1-5 nt) in damaged DNA and removing deoxyribose 5'-phosphate from the 5'-side of damaged DNA. The backbone dynamics and the refined solution structure of the N-terminal domain of beta-Pol have been characterized in order to establish the potential contribution(s) of backbone motion to the DNA binding and deoxyribose 5'-phosphate lyase function of this domain. The N-terminal domain is formed from four helices packed as two antiparallel pairs with a 60 degrees crossing between the pairs. The RMSD of the NMR conformers (residues 13-80) is 0.37 A for the backbone heavy atoms and 0.78 A for all heavy atoms. NMR characterization of the binding site(s) for a ssDNA-5mer, ssDNA-8mer, ssDNA-9mer, and dsDNA-12mer shows a consensus surface for the binding of these various DNA oligomers, that surrounds and includes the deoxyribose 5'-phosphate lyase active site region. Connection segments between helices 1 and 2 and between helices 3 and 4 each contribute to DNA binding. Helix-3-turn-helix-4 forms a helix-hairpin-helix motif. The highly conserved hairpin sequence (LPGVG) displays a significant degree of picosecond time-scale motion within the backbone, that is possibly important for DNA binding at the phosphodiester backbone. An Omega-loop connecting helices 1 and 2 and helix-2 itself display significant exchange contributions (R(ex)) at the backbone amides due to apparent conformational type motion on a millisecond time-scale. This motion is likely important in allowing the Omega-loop and helix-2 to shift toward, and productively interact with, gapped DNA. The deoxyribose 5'-phosphate lyase catalytic residues that include K72 which forms the Schiff's base, Y39 which is postulated to promote proton transfer to the aldehyde, and K35 which assists in phosphate elimination, show highly restricted backbone motion. H34, which apparently participates in detection of the abasic site hole and assists in the opening of the hemiacetal, shows conformational exchange.

Complex patterns of alternative splicing mediate the spatial and temporal distribution of perlecan/UNC-52 in Caenorhabditis elegans

The unc-52 gene encodes the nematode homologue of mammalian perlecan, the major heparan sulfate proteoglycan of the extracellular matrix. This is a large complex protein with regions similar to low-density lipoprotein receptors, laminin, and neural cell adhesion molecules (NCAMs). In this study, we extend our earlier work and demonstrate that a number of complex isoforms of this protein are expressed through alternative splicing. We identified three major classes of perlecan isoforms: a short form lacking the NCAM region and the C-terminal agrin-like region; a medium form containing the NCAM region, but still lacking the agrin-like region; and a newly identified long form that contains all five domains present in mammalian perlecan. Using region-specific antibodies and unc-52 mutants, we reveal a complex spatial and temporal expression pattern for these UNC-52 isoforms. As well, using a series of mutations affecting different regions and thus different isoforms of UNC-52, we demonstrate that the medium NCAM-containing isoforms are sufficient for myofilament lattice assembly in developing nematode body-wall muscle. Neither short isoforms nor isoforms containing the C-terminal agrin-like region are essential for sarcomere assembly or muscle cell attachment, and their role in development remains unclear.

Solution structure of the single-strand break repair protein XRCC1 N-terminal domain

XRCC1 functions in the repair of single-strand DNA breaks in mammalian cells and forms a repair complex with beta-Pol, ligase III and PARP. Here we describe the NMR solution structure of the XRCC1 N-terminal domain (XRCC1 NTD). The structural core is a beta-sandwich with beta-strands connected by loops, three helices and two short two-stranded beta-sheets at each connection side. We show, for the first time, that the XRCC1 NTD specifically binds single-strand break DNA (gapped and nicked). We also show that the XRCC1 NTD binds a gapped DNA-beta-Pol complex. The DNA binding and beta-Pol binding surfaces were mapped by NMR and found to be well suited for interaction with single-strand gap DNA containing a 90 degrees bend, and for simultaneously making contacts with the palm-thumb of beta-Pol in a ternary complex. The findings suggest a mechanism for preferential binding of the XRCC1 NTD to flexible single-strand break DNA.

The dimerization and topological specificity functions of MinE reside in a structurally autonomous C-terminal domain

Correct placement of the division septum in Escherichia coli requires the co-ordinated action of three proteins, MinC, MinD and MinE. MinC and MinD interact to form a non-specific division inhibitor that blocks septation at all potential division sites. MinE is able to antagonize MinCD in a topologically sensitive manner, as it restricts MinCD activity to the unwanted division sites at the cell poles. Here, we show that the topological specificity function of MinE residues in a structurally autonomous, trypsin-resistant domain comprising residues 31-88. Nuclear magnetic resonance (NMR) and circular dichroic spectroscopy indicate that this domain includes both alpha and beta secondary structure, while analytical ultracentrifugation reveals that it also contains a region responsible for MinE homodimerization. While trypsin digestion indicates that the anti-MinCD domain of MinE (residues 1-22) does not form a tightly folded structural domain, NMR analysis of a peptide corresponding to MinE1-22 indicates that this region forms a nascent helix in which the peptide rapidly interconverts between disordered (random coil) and alpha-helical conformations. This suggests that the N-terminal region of MinE may be poised to adopt an alpha-helical conformation when it interacts with the target of its anti-MinCD activity, presumably MinD.

Functional analysis of the amino-terminal 8-kDa domain of DNA polymerase beta as revealed by site-directed mutagenesis. DNA binding and 5'-deoxyribose phosphate lyase activities

The amino-terminal 8-kDa domain of DNA polymerase beta functions in binding single-stranded DNA (ssDNA), recognition of a 5'-phosphate in gapped DNA structures, and as a 5'-deoxyribose phosphate (dRP) lyase. NMR and x-ray crystal structures of this domain have suggested several residues that may interact with ssDNA or play a role in the dRP lyase reaction. Nine of these residues were altered by site-directed mutagenesis. Each mutant was expressed in Escherichia coli, and the recombinant protein was purified to near homogeneity. CD spectra of these mutant proteins indicated that the alteration did not adversely affect the global protein structure. Single-stranded DNA binding was probed by photochemical cross-linking to oligo(dT)16. Several mutants (F25W, K35A, K60A, and K68A) were impaired in ssDNA binding activity, whereas other mutants (H34G, E71Q, K72A, E75A, and K84A) retained near wild-type binding activity. The 5'-phosphate recognition activity of these mutants was examined by UV cross-linking to a 5-nucleotide gap DNA where the 5' terminus in the gap was either phosphorylated or unphosphorylated. The results indicate that Lys35 is involved in 5'-phosphate recognition of DNA polymerase beta. Finally, the dRP lyase activity of these mutants was evaluated using a preincised apurinic/apyrimidinic DNA. Alanine mutants of Lys35 and Lys60 are significantly reduced in dRP lyase activity, consistent with the lower ssDNA binding activity. More importantly, alanine substitution for Lys72 resulted in a greater than 90% loss of dRP lyase activity, without affecting DNA binding. Alanine mutants of Lys68 and Lys84 had wild-type dRP lyase activity. The triple alanine mutant, K35A/K68A/K72A, was devoid of dRP lyase activity, suggesting that the effects of the alanine substitution at Lys72 and Lys35 were additive. The results suggest that Lys72 is directly involved in formation of a covalent imino intermediate and are consistent with Lys72 as the predominant Schiff base nucleophile in the dRP lyase beta-elimination catalytic reaction.

Secondary and tertiary structural changes in gamma delta resolvase: comparison of the wild-type enzyme, the I110R mutant, and the C-terminal DNA binding domain in solution

gamma delta Resolvase is a site-specific DNA recombinase (M(r) 20.5 kDa) in Escherichia coli that shares homology with a family of bacterial resolvases and invertases. We have characterized the secondary and tertiary structural behavior of the cloned DNA binding domain (DBD) and a dimerization defective mutant in solution. Low-salt conditions were found to destabilize the tertiary structure of the DBD dramatically, with concomitant changes in the secondary structure that were localized near the hinge regions between the helices. The molten tertiary fold appears to contribute significantly to productive DNA interactions and supports a mechanism of DNA-induced folding of the tertiary structure, a process that enables the DBD to adapt in conformation for each of the three imperfect palindromic sites. At high salt concentrations, the monomeric I110R resolvase shows a minimal perturbation to the three helices of the DBD structure and changes in the linker segment in comparison to the cloned DBD containing the linker. Comparative analysis of the NMR spectra suggest that the I110R mutant contains a folded catalytic core of approximately 60 residues and that the segment from residues 100 to 149 are devoid of regular structure in the I110R resolvase. No increase in the helicity of the linker region of I110R resolvase occurs on binding DNA. These results support a subunit rotation model of strand exchange that involves the partial unfolding of the catalytic domains.

Three-dimensional solution structure of the N-terminal domain of DNA polymerase beta and mapping of the ssDNA interaction interface

DNA polymerase beta (beta-Pol) consists of an N-terminal ssDNA binding domain with deoxyribose phosphodiesterase activity and a C-terminal domain with nucleotidyltransferase activity. The solution structure of the cloned N-terminal domain of beta-Pol has been determined by multidimensional heteronuclear NMR using experimental restraints that included 1030 distances based on analysis of NOE connectivities, 68 phi, chi 1, and chi 2 torsion angles based on analysis of couplings, and 22 hydrogen bonds. Hydrogen bonds were assessed only within helices by the absence of saturation transfer from water at pH 6.7, by NOEs and JNH alpha couplings indicative of well-structured helices, and by 13C alpha chemical shifts characteristic of helices. The root mean square deviation for heavy backbone atoms within the helices was 0.64 A in 55 structures. The solution structure of the N-terminal domain is formed from four helices packed as two antiparallel pairs crossing at 50 degrees in a V-like shape. The domain binds p(dT)8, a template analogue, as a 1:1 complex in 100 mM NaCl (KD = 10 microM). Analysis of the binding equilibria at increasing NaCl concentrations indicated that ionic contacts contribute to the complex. The binding interaction was mapped to one face of the domain by characterizing backbone 1H and 15N chemical shift changes. Assigned intermolecular NOEs from 2D NOESY support the assessment of the binding interface. The structure that forms the interaction surface includes an antiparallel helix-3-turn-helix-4 motif and residues adjacent to an omega-type loop connecting helix-1 and helix-2. Sites appropriate for nucleotide contact on the structure are described. The mapped interaction interface for a ssDNA template is the first described for a DNA polymerase.

The mec-8 gene of C. elegans encodes a protein with two RNA recognition motifs and regulates alternative splicing of unc-52 transcripts

Mutations in the mec-8 gene of Caenorhabditis elegans were previously shown to affect the functions of body wall muscle and mechanosensory and chemosensory neurons. Mutations in mec-8 also strongly enhance the mutant phenotype of specific mutations in unc-52, a gene that encodes, via alternative splicing of pre-mRNA, a set of basement membrane proteins, homologs of perlecan, that are important for body wall muscle assembly and attachment to basement membrane, hypodermis and cuticle. We have cloned mec-8 and found that it encodes a protein with two RNA recognition motifs, characteristic of RNA binding proteins. We have used reverse transcription-PCR and RNase protection experiments to show that mec-8 regulates the accumulation of a specific subset of alternatively spliced unc-52 transcripts. We have also shown with antibodies to UNC-52 that mec-8 affects the abundance of a subset of UNC-52 isoforms. We propose that mec-8 encodes a trans-acting factor that regulates the alternative splicing of the pre-mRNA of unc-52 and one or more additional genes that affect mechanosensory and chemosensory neuron function.

Cell autonomous expression of perlecan and plasticity of cell shape in embryonic muscle of Caenorhabditis elegans

Perlecan, a component of the extracellular matrix (ECM), is essential for myofilament formation and muscle attachment in Caenorhabditis elegans. We show here that perlecan is a product of muscle and that it behaves in a cell autonomous fashion. That is, perlecan expressed in an individual muscle cell does not spread beyond the borders of the ECM underlying that cell. Using a polyclonal antibody that recognizes all isoforms of perlecan, we demonstrate that this protein first appears extracellularly at the comma stage (approx. 350 min) of development. We also show that during morphogenesis muscle cells have a heretofore undescribed plasticity of shape. This ability to regulate cell shape allows cells within a muscle quadrant to compensate for missing cells and to form a functional quadrant. A dramatic example of this morphological flexibility can be observed in animals in which the D blastomere has been removed by laser ablation. Such animals, lacking 20 of the 81 embryonic body wall muscle cells, can survive to become viable adult animals indistinguishable from wildtype animals. This demonstrates that the assembly of an embryo via a stereotypic lineage does not preclude a more general regulation during morphogenesis. It appears that embryos are flexible enough to immediately compensate for drastic alterations in tissue composition, a feature of development that may be of general importance during evolution.

Mutations in the unc-52 gene responsible for body wall muscle defects in adult Caenorhabditis elegans are located in alternatively spliced exons

The unc-52 gene in Caenorhabditis elegans produces several large proteins that function in the basement membrane underlying muscle cells. Mutations in this gene result in defects in myofilament assembly and in the attachment of the myofilament lattice to the muscle cell membrane. The st549 and ut111 alleles of unc-52 produce a lethal (Pat) terminal phenotype whereas the e444, e669, e998, e1012 and e1421 mutations result in viable, paralyzed animals. We have identified the sequence alterations responsible for these mutant phenotypes. The st549 allele has a premature stop codon in exon 7 that should result in the complete elimination of unc-52 gene function, and the ut111 allele has a Tc1 transposon inserted into the second exon of the gene. The five remaining mutations are clustered in a small interval containing three adjacent, alternatively spliced exons (16, 17 and 18). These mutations affect some, but not all of the unc-52-encoded proteins. Thirteen intragenic revertants of the e669, e998, e1012 and e1421 alleles have also been sequenced. The majority of these carry the original mutation plus a G to A transition in the conserved splice acceptor site of the affected exon. This result suggests that reversion of the mutant phenotype in these strains may be the result of exon-skipping.

Assignments of 1H, 15N, and 13C resonances for the backbone and side chains of the N-terminal domain of DNA polymerase beta. Determination of the secondary structure and tertiary contacts

DNA polymerase beta consists of an N-terminal single-stranded DNA binding domain and a C-terminal catalytic domain separable by mild proteolysis [Kumar et al. (1990) J. Biol. Chem. 265, 2124-2131]. The N-terminal domain participates in template and gapped DNA recognition and contributes significantly to catalysis. The secondary structure and tertiary contacts within the cloned N-terminal domain (residues 2-87) of mammalian DNA polymerase beta have been determined using multidimensional NMR. Assignments of backbone 1H, 15N, and 13C resonances and side chain 1H and 13C resonances have been obtained from double- and triple-resonance 3D NMR experiments. The 13C-edited TOCSY experiment has allowed nearly complete assignments of 1H and 13C resonances within side chains. The 13C-edited NOESY experiment has been used for determination of medium- and long-range NOEs and a determination of tertiary contacts. The N-terminal domain is found to consist of four helices, helix-1 (15-26), helix-2 (36-47), helix-3 (56-61), and helix-4 (69-78), which on the basis of long-range NOEs are tightly packed of form a hydrophobic core. The remainder of the domain consists of two turns (48-51 and 62-65), an omega-type loop (27-35), and extended structure. The aromatic side chains of Y36, Y39, Y49, and F76 display tertiary contacts indicative of at least partial hydrophobic packing. The S30 and H34 residues which cross-link to single-stranded DNA [Prasad et al. (1993) J. Biol. Chem. 268, 15906-15911] are contained within the K27-K35 loop.(ABSTRACT TRUNCATED AT 250 WORDS)

Sequential proton resonance assignments and metal cluster topology of lobster metallothionein-1

NMR studies of 111Cd6-MT 1 from lobster have been conducted to determine coordination structure of Cd-thiolate binding in the protein. Sequential proton resonance assignments were made using standard two-dimensional 1H NMR methods. Two-dimensional 1H-111Cd HMQC experiments were then carried out to determine the cadmium-cysteine connectivities in the protein. With this information, it was established that the six Cd ions exist in two different Cd3S9 clusters, each involving three bridging and six terminal thiolate ligands. Sequential cysteines in the sequence provide the sulfhydryl ligands for each cluster and do not overlap, as has been found in mammalian metallothionein. Comparison of the N-terminal, Cd3S9 B-type cluster of lobster MT 1 with the Cd3S9 cluster from rabbit MT 2 shows that while eight of the nine cysteine residues occupy homologous positions in their sequences, three of the 12 Cd-thiolate connectivities are different. Similarly, the C-terminal B-cluster of lobster MT 1 was compared with the Cd4S11 cluster of mammalian MT 2, excluding the two terminal cysteine sulfhydryl groups that convert this cluster from A- to B-type. As above, eight of nine cysteine positions are identical, yet five of 12 Cd-sulfhydryl connections are different. These differences are expanded when the role of each cysteine as bridging or terminal ligands in the clusters is considered.

Determination of the structure of the DNA binding domain of gamma delta resolvase in solution

The DNA binding domain (DBD) of gamma delta resolvase (residues 141-183) is responsible for the interaction of this site-specific DNA recombinase with consensus site DNA within the gamma delta transposable element in Escherichia coli. Based on chemical-shift comparisons, the proteolytically isolated DBD displays side-chain interactions within a hydrophobic core that are highly similar to those of this domain when part of the intact enzyme (Liu T, Liu DJ, DeRose EF, Mullen GP, 1993, J Biol Chem 268:16309-16315). The structure of the DBD in solution has been determined using restraints obtained from 2-dimensional proton NMR data and is represented by 17 conformers. Experimental restraints included 458 distances based on analysis of nuclear Overhauser effect connectivities, 17 phi and chi 1 torsion angles based on analysis of couplings, and 17 backbone hydrogen bonds determined from NH exchange data. With respect to the computed average structure, these conformers display an RMS deviation of 0.67 A for the heavy backbone atoms and 1.49 A for all heavy atoms within residues 149-180. The DBD consists of 3 alpha-helices comprising residues D149-Q157, S162-T167, and R172-N183. Helix-2 and helix-3 form a backbone fold, which is similar to the canonical helix-turn-helix motif. The conformation of the NH2-terminal residues, G141-R148, appears flexible in solution. A hydrophobic core is formed by side chains donated by essentially all hydrophobic residues within the helices and turns. Helix-1 and helix-3 cross with a right-handed folding topology. The structure is consistent with a mechanism of DNA binding in which contacts are made by the hydrophilic face of helix-3 in the major groove and the amino-terminal arm in the minor groove. This structure represents an important step toward analysis of the mechanism of DNA interaction by gamma delta resolvase and provides initial structure-function comparisons among the divergent DBDs of related resolvases and invertases.

Interaction of the bHLH-zip domain of c-Myc with H1-type peptides. Characterization of helicity in the H1 peptides by NMR

The carboxyl-terminal 92 residues of c-Myc-92 display site-specific DNA binding specificity for the consensus sequence 5'-CACCACGTGGTG-3' (Blackwell, T. K., Kretzner, L., Blackwood, E. M., Eisenman, R. N., and Weintraub, H. (1990) Science 250, 1149-1151). Size exclusion high pressure liquid chromatography analysis of the purified fusion protein, glutathione S-transferase-c-Myc-92, indicates that c-Myc-92 is tetrameric with a dissociation constant of < 60 nM. Helix-1 (H1) and leucine zipper peptides from the basic-helix-loop-helix-zipper domain of c-Myc and Max were assayed as potential inhibitors of c-Myc-92 DNA binding. H1 peptides with substitutions that confer greater helicity are found to inhibit c-Myc-92 DNA binding. The mechanism of inhibition involves the cooperative binding of H1 peptides with tetrameric c-Myc-92 as determined by a spectrophotometric assay employing 2,4-dinitrophenyl-H1-F8A. NMR structural characterization reveals a correlation between helicity and inhibition. In a partially hydrophobic environment, H1-Mx (from Max) is a random coil, while H1-WT, H1-F8A, and H1-F8A,S6A (from c-Myc) display differing degrees of helicity. Structure determination on the basis of nuclear Overhauser effect data indicates that the H1-F8A helix is significantly more ordered than H1-WT. Analysis on the basis of the Max x-ray structure (Ferré-D'Amaré, R., Prendergast, G. C., Ziff, E. B., and Burley, S. K. (1993) Nature 363, 38-45) suggests that H1 peptide binding to c-Myc-92 may occur through an alteration in the packing of helix-1 in c-Myc-92 or through an interaction with an exposed hydrophobic cluster of residues at each H1-H2 interface. This binding site for H1 peptides may be of significance in the interaction of c-Myc with proteins involved in transcriptional regulation.

Studies of the dimerization and domain structure of gamma delta resolvase

gamma delta Resolvase is a site-specific recombinase (20.5 kDa) that catalyzes the resolution of a negatively supercoiled plasmid to a catenated pair of circular DNA products (Reed, R. R. (1981) Cell 25, 713-719). Cross-linking experiments and size exclusion high pressure liquid chromatography analysis of isolated fragments corresponding to specific proteolytic cleavage indicate that the intact enzyme and the large fragment exist in a monomer-dimer equilibrium (KDdimer = 8.0 microM, intact enzyme; KDdimer = 0.1 microM, large fragment) and that the small fragment, which displays DNA binding specificity, is a monomer. Dimerization is further supported by line width comparisons in one-dimensional NMR spectra and determinations of the correlation time of the protein. The one-dimensional proton NMR spectra spectroscopy spectra indicate that the overall structure of the two isolated fragments is highly similar to the structure present in the domains of the intact enzyme. The rotational correlation time of resolvase, determined from relaxation data obtained from each domain, indicates that the small domain has a limited degree of additional motion with respect to the large domain of the enzyme. The monomer-dimer equilibrium and small domain mobility may assist in the binding of resolvase to palindromic-type sites with variable spacers and in subunit exchange during catalysis.

Products of the unc-52 gene in Caenorhabditis elegans are homologous to the core protein of the mammalian basement membrane heparan sulfate proteoglycan

Mutations in the unc-52 gene of Caenorhabditis elegans affect attachment of the myofilament lattice to the muscle cell membrane. Here, we demonstrate that the unc-52 gene encodes a nematode homolog of perlecan, the mammalian basement membrane heparan sulfate proteoglycan. The longest potential open reading frame of this gene encodes a 2482-amino-acid protein with a signal peptide and four domains. The first domain is unique to the unc-52 polypeptide, whereas the three remaining domains contain sequences found in the LDL receptor (domain II) laminin (domain III) and N-CAM (domain IV). We have identified three alternatively spliced transcripts that encode different carboxy-terminal sequences. The two larger transcripts encode proteins containing all or part of domain IV, whereas the smaller transcript encodes a shortened polypeptide that completely lacks domain IV. We have determined that the disorganized muscle phenotype observed in unc-52(st196) animals is caused by the insertion of a Tc1 transposon into domain IV. Two monoclonal antibodies that recognize an extracellular component of all contractile tissues in C. elegans fail to stain embryos homozygous for a lethal unc-52 allele. We have mapped the epitopes recognized by both monoclonal antibodies to a region of domain IV in the unc-52-encoded protein sequence.

Sequential proton NMR resonance assignments, circular dichroism, and structural properties of a 50-residue substrate-binding peptide from DNA polymerase I

Peptide I, a 50-amino acid synthetic peptide based on residues 728 to 777 of DNA polymerase I, binds dNTP substrates and duplex DNA (G. Mullen, P. Shenbagamurthi, and A.S. Mildvan, J. Biol. Chem. 264, 19637-19647, 1988). The structural properties of peptide I at pH 3.9 have been studied by CD spectroscopy and by 2D proton NMR at 600 MHz. The CD spectra are fit by assuming that peptide I contains 17% helix, 17% beta-structure, and 66% coil. The substrate dATP binds tightly to peptide I under these conditions (KD = 0.5 microM) as determined by fluorescence quenching but induces no change in peptide conformation, as detected by CD spectroscopy. Proton resonances of peptide I have been assigned by double quantum filtered correlated spectroscopy, total correlated spectroscopy, and nuclear Overhauser effect spectroscopy. As found with other peptides, peptide I is best characterized by both extended and partially folded secondary structures which equilibrate rapidly on the NMR time scale. A region from residues 3 through 10 displays nuclear Overhauser effects (NOEs) consistent with the rapid equilibration of a nascent helix with a random extended structure. Alternatively this segment of residues is consistent with a series of three opened-out turns. A nonclassical turn is found between residues 14 and 17 and from residues 44 to 47, the latter closing irregular antiparallel strands from residues 42 to 48. The remainder of the peptide is a coil. A residue-by-residue comparison of the best-fit solution structure of the peptide with that of the corresponding sequence in the X-ray structure of the complete enzyme reveals that 36% of the amino acids are found to be in a conformation similar to that in the enzyme. Such partial and transient folding of the peptide indicates that the major role of the remainder of the protein is to provide structural support for the active site region of the enzyme. As detected by interresidue NOEs and NOEs to water protons, the homologous sequence Leu-37-Ile-38-Tyr-39-Gly-40, together with Phe-15 of the peptide, provides an exposed hydrophobic cluster of residues which may constitute the substrate binding site. An exposed cluster of cationic residues consisting of Arg-27, Arg-28, Lys-31, and possibly Arg-48 may provide the binding site for duplex DNA.

NMR docking of a substrate into the X-ray structure of staphylococcal nuclease

The conformation of the staphylococcal nuclease-bound metal-dTdA complex, previously determined by NMR methods [Weber, D.J., Mullen, G.P., Mildvan, A.S. (1991) Biochemistry 30:7425-7437] was docked into the X-ray structure of the enzyme-Ca(2+)-3',5'-pdTp complex [Loll, P.J., Lattman, E.E. (1989) Proteins: Struct., Funct., Genet. 5:183-201] by superimposing the metal ions, taking into account intermolecular nuclear Overhauser effects from assigned aromatic proton resonances of Tyr-85, Tyr-113, and Tyr-115 to proton resonances of the leaving dA moiety of dTdA, and energy minimization to relieve small overlaps. The proton resonances of the Phe, Tyr, and Trp residues of the enzyme in the ternary enzyme-La(3+)-dTdA complex were sequence specifically assigned by 2D phase-sensitive NOESY, with and without deuteration of the aromatic protons of the Tyr residues, and by 2D heteronuclear multiple quantum correlation (HMQC) spectroscopy and 3D NOESY-HMQC spectroscopy with 15N labeling. While resonances of most Phe, Tyr and Trp residues were unshifted by the substrate dTdA from those found in the enzyme-La(3+)-3',5'-pdTp complex and the enzyme-Ca(2+)-3',5'-pdTp complex, proton resonances of Tyr-85, Tyr-113, Tyr-115, and Phe-34 were shifted by 0.08 to 0.33 ppm and the 15N resonance of Tyr-113 was shifted by 2.1 ppm by the presence of substrate. The optimized position of enzyme-bound dTdA shows the 5'-dA leaving group to partially overlap the inhibitor, 3',5'-pdTp (in the X-ray structure). The 3'-TMP moiety of dTdA points toward the solvent in a channel defined by Ile-18, Asp-19, Thr-22, Lys-45, and His-46. The phosphate of dTdA is coordinated by the metal, and an adjacent inner sphere water ligand is positioned to donate a hydrogen bond to the general base Glu-43 and to attack the phosphorus with inversion. Arg-35 and Arg-87 donate monodentate hydrogen bonds to different phosphate oxygens of dTdA, with Arg-87 positioned to protonate the leaving 5'-oxygen of dA, thus clarifying the mechanism of hydrolysis. Model building of an additional 5'-dGMP onto the 3'-oxygen of dA placed this third nucleotide onto a surface cleft near residues Glu-80, Asp-83, Lys-84, and Tyr-115 with its 3'-OH group accessible to the solvent, thus defining the size of the substrate binding site as accommodating a trinucleotide.