Vaccinia virus DNA topoisomerase: a model eukaryotic type IB enzyme

Vaccinia topoisomerase has proven to be an instructive model system for mechanistic studies of the type IB family of DNA topoisomerases. The catalytically relevant functional groups at the active site and the circumferential topoisomerase-DNA interface were correctly surmised by mutational and footprint analysis of vaccinia topoisomerase in advance of structure determinations by X-ray crystallography. It is now evident from multiple crystal structures that the catalytic domains of type IB topoisomerases and site specific recombinases derive from a common ancestral strand transferase capable of forming a DNA-(3'-phosphotyrosyl)-enzyme intermediate. A constellation of conserved amino acids catalyzes attack of the tyrosine nucleophile on the scissile phosphate. Domain dynamics and DNA-induced conformational changes within the catalytic domain are likely to play a role in triggering strand scission and coordinating the strand exchange or strand passage steps.     

Analysis of the subunit assembly of the typeIC restriction-modification enzyme EcoR124I

Type I restriction-modification (R-M) enzymes are composed of three different subunits, of which HsdS determines DNA specificity, HsdM is responsible for DNA methylation and HsdR is required for restriction. The HsdM and HsdS subunits can also form an independent DNA methyltransferase with a subunit stoichiometry of M2S1. We found that the purified Eco R124I R-M enzyme was a mixture of two species as detected by the presence of two differently migrating specific DNA-protein complexes in a gel retardation assay. An analysis of protein subunits isolated from the complexes indicated that the larger species had a stoichiometry of R2M2S1and the smaller species had a stoichiometry of R1M2S1. In vitro analysis of subunit assembly revealed that while binding of the first HsdR subunit to the M2S1complex was very tight, the second HsdR subunit was bound weakly and it dissociated from the R1M2S1complex with an apparent K d of approximately 2.4 x 10(-7) M. Functional assays have shown that only the R2M2S1complex is capable of DNA cleavage, however, the R1M2S1complex retains ATPase activity. The relevance of this situation is discussed in terms of the regulation of restriction activity in vivo upon conjugative transfer of a plasmid-born R-M system into an unmodified host cell.     

Removal of beta subunit of the eukaryotic polypeptide chain initiation factor 2 by limited proteolysis

It is generally considered that the eukaryotic polypeptide chain initiation factor 2 (eIF-2) from rabbit reticulocytes consists of three nonidentical subunits termed alpha, beta, and gamma, in order of increasing molecular weight. However, a recent report [Stringer, E. A., Chaudhuri, A., Valenzuela, D. & Maitra, U. (1980) Proc. Natl. Acad. Sci. USA 77, 3356-3359] suggested that this factor is made up of only two subunits. In this paper we show that limited proteolysis of rabbit reticulocyte eIF-2 leads to loss of the beta subunit. This modified eIF-2 has the same activity as the native factor in promoting ternary (eIF-2.GTP.Met-tRNAi) and 40S (eIF-2.GTP.Met-tRNAi.40S ribosome) initiation complex formation. Like native eIF-2, the protease-treated factor can restore translation in heme-deficient lysates. On the other hand, the treated factor is less stable than the native protein.     

Isolation of a non-classical mutant of the DNA recognition subunit of the type I restriction endonuclease R.EcoR124I

We have used deletion mutagenesis and PCR-based misincorporation mutagenesis to produce a collection of mutations in the central conserved region of the DNA binding subunit of the type IC restriction endonuclease EcoR124I. It has been proposed that this domain is involved in protein-protein interactions during the assembly of the endonuclease. While a large percentage of these mutations gave a classical Res- Mod- phenotype, one mutant was isolated with a nonclassical Res- Mod+ phenotype. The loss of restriction activity, but retention of the ability to modify indicates that this mutation cannot affect DNA binding and must alter the assembly of the endonuclease in such a way as to prevent DNA cleavage but allow methylation. This mutant resulted from a single amino acid change Trp212-->Arg. The location of the single amino acid change is at the border of the central conserved region and the second target recognition domain (TRD2) and suggests that this region is extremely important for the assembly of the methylase with the HsdR subunit into a functional restriction endonuclease.     

The acidic C-terminal domain of protein disulfide isomerase is not critical for the enzyme subunit function or for the chaperone or disulfide isomerase activities of the polypeptide

Pancreatic neurons receive and integrate synaptic input from a wide variety of extrinsic nerves while providing the predominant innervation of pancreatic acini, ducts, and islets of Langerhans. Here we report the first primary cultures of adult rabbit pancreatic neurons, isolated from extrinsic nerves and secretory cells, and evaluate the neurochemical and electrical properties of these neurons. Pancreatic cultures consisted of single and clustered neurons, extended varicose processes after 3-4 days in culture, and formed interconnecting networks of neurons after 7-10 days. Isolated pancreatic islet cells, added to established neuron cultures, remained attached and viable for several weeks and received innervation by varicose nerve fibers. Histochemical staining revealed populations of neurons positive for acetylcholinesterase (75%), NADPH-diaphorase (62%), nitric oxide synthase (73%), and/or vasoactive intestinal peptide (VIP) (65%). Intracellular recordings revealed active and passive electrical properties comparable to those of neurons from intact ganglia. Several distinct populations of neurons were identified by their firing patterns (phasic vs. tonic) in response to prolonged depolarizing currents or the amplitude and duration of their after-spike hyperpolarizations. Low-amplitude, pacemaker-like potentials were observed in 25% of the neurons and, in older cultures with extensive networks of fibers, spontaneous fast excitatory postsynaptic potentials (EP-SPs) also occurred. Thus these cultures retained the salient neurochemical and electrophysiologic properties observed in pancreatic neurons from intact ganglia and offer a good model for studies of the intrinsic innervation of the pancreas.     

The reduced levels of chi recognition exhibited by the RecBC1004D enzyme reflect its recombination defect in vivo

Homologous recombination in Escherichia coli is initiated by the RecBCD enzyme and is stimulated by an 8-nucleotide element known as Chi (chi). We present a detailed biochemical characterization of a mutant RecBCD enzyme, designated RecBC1004D, that displays a reduced level of chi site recognition. Initially characterized genetically as unable to respond to the chi sequence, we provide evidence to indicate that the ability of this mutant enzyme to respond to chi is reduced rather than lost; the mutant displays about 20-fold lower chi recognition than wild-type RecBCD enzyme. Although this enzyme exhibits wild-type levels of double-stranded DNA exonuclease, helicase, and ATPase activity, its ability to degrade single-stranded DNA is enhanced 2-3-fold. The data presented here suggest that the reduced recombination proficiency of the recBC1004D strain observed in vivo results from a basal level of modification of the RecBC1004D enzyme at both chi-specific, as well as nonspecific, DNA sequences.     

The complete cDNA sequence and structural polymorphism of the polypeptide chain of porcine submaxillary mucin

The complete structure of the DNA encoding the polypeptide chain of porcine submaxillary mucin has been determined. The polypeptide is composed of distinct domains. A large central domain containing tandem repeats of 81 residues each is flanked by much shorter domains with sequences similar to the tandem repeats. Four disulfide-rich domains, three at the amino terminus and one at the carboxyl terminus, complete the chain. The disulfide-rich domains have significant sequence identity to those of other mucins and prepro-von Willebrand factor. The coding region of the mucin gene is highly polymorphic, and three alleles were identified in a single animal that encoded different numbers of the 81-residue tandem repeats. A single large exon devoid of introns encodes the tandem repeat domains. The largest allele with 135 tandem repeats encoded 13,288 amino acids to give a polypeptide with Mr = 1,184,106. The other two alleles contained 99 and 125 tandem repeats, respectively. Each allele also showed different restriction fragment length polymorphisms, which is consistent with the different patterns seen in individual animals. Fragment length polymorphism was also seen within two different families of animals, indicating that the polymorphism observed occurs in a single generation.     

Structural basis of DNA recognition and mechanism of quadruplex formation by the beta subunit of the Oxytricha telomere binding protein

Interactions of the beta subunit of the Oxytricha nova telomere binding protein with the telomeric DNA sequences, d(T4G4)2 and dT6(T4G4)2, have been investigated in vitro using Raman and fluorescence spectroscopies. Raman difference spectra show that the beta subunit binds to both d(T4G4)2 and dT6(T4G4)2 but promotes the formation of a parallel-stranded quadruplex only in dT6(T4G4)2, thus demonstrating the importance of the telomeric 5' tail for in vitro recognition and guanine quadruplex formation. While d(T4G4)2 is not a suitable substrate for quadruplex promotion by the beta subunit, the Raman spectra reveal other structural rearrangements of this DNA strand upon beta subunit binding, including changes in guanine glycosyl torsion angles from syn to anti and disruption of carbonyl hydrogen-bonding interactions. The conformation of d(T4G4)2 in the beta:d(T4G4)2 complex is suggested as a plausible intermediate along the pathway to formation of the parallel-stranded guanine quadruplex. Fluorescence band shifts indicate that at least one of the two tryptophans of the beta subunit is shielded from solvent as a consequence of DNA binding in both the beta:dT6(T4G4)2 and beta:d(T4G4)2 complexes. However, the Raman spectra of these complexes suggest no significant changes in the beta subunit secondary structure attendant with DNA binding. A model for beta subunit binding by Oxytricha telomeric DNA sequences and a mechanism for quadruplex formation are proposed. A key feature of this model is the use of a telomeric hairpin secondary structure as the recognition motif.     

Primase activity of human DNA polymerase alpha-primase. Divalent cations stabilize the enzyme activity of the p48 subunit

DNA polymerase alpha-primase consists of four subunits, p180, p68, p58, and p48, and comprises two essential enzymatic functions. To study the primase activity of the complex, we expressed cDNAs encoding for the human p58 and p48 subunits either as single proteins or together using Escherichia coli expression vectors. Co-expression of both primase subunits allowed the purification of a heterodimer in high yields that revealed stable primase activity. Purified recombinant p48 subunit showed enzyme activity, whereas purified p58 did not. In contrast to the heterodimer, the primase activity of p48 was unstable. The activity of p48 could be stabilized by the addition of the divalent cations Mg2+ and Mn2+ but not Zn2+. On a poly(dC) template the primase activity was hardly influenced by the monovalent cation potassium. However, by using poly(dT) as a template the recombinant p48 activity was sensitive to salt, whereas recombinant p58-p48 and the bovine DNA polymerase alpha-primase purified from thymus were less sensitive to the addition of monovalent cations. A complex of bacterially expressed primase and baculovirus-expressed p180 and p68 was assembled in vitro and shown to support replication of simian virus 40 DNA in a cell-free system.     

The N-domain of the signal recognition particle 54-kDa subunit promotes efficient signal sequence binding

The signal recognition particle 54-kDa subunit (SRP54) binds to the signal sequences of nascent presecretory and transmembrane proteins. Previous studies have shown that signal sequences bind to the C-terminal methionine-rich domain of the protein (M-domain), but have raised the possibility that either the N-terminal domain (N-domain) or the central guanosine triphosphatase module (GTPase-domain) also contribute to signal-sequence-binding activity. We have generated a series of N-domain and GTPase-domain mutants to investigate this issue further. Mutations in a conserved N-domain motif (ALLEADV) produced significant defects in signal sequence binding that correlate with the severity of the mutation. The magnitude of the defect was independent of the preprotein substrate, which suggested that the mutations do not alter the specificity of signal sequence recognition. The N-domain mutants also showed defects in promoting the translocation of presecretory proteins across the membrane of microsomal vesicles, but these defects appeared to be a direct consequence of the reduction in signal-sequence-binding activity and not separate effects of the mutations. By contrast, mutations in the guanosine triphosphatase consensus sequence had no effect on signal sequence binding, but instead severely impaired protein translocation activity. These results indicate that a principal function of the SRP54 N-domain is to promote efficient signal sequence binding. These data also suggest that the SRP54 GTPase regulates the cycle of signal sequence binding and release, perhaps by modulating the relative orientation of the N- and M-domains.     

DNA recognition by the EcoK methyltransferase. The influence of DNA methylation and the cofactor S-adenosyl-L-methionine

The methyltransferase of the EcoK type I restriction/modification system is trimeric, M2S1, where the S subunit determines the sequence specificity of the enzyme. The methyltransferase has a strong preference for hemimethylated substrate DNA and, therefore, we have investigated the effect of the methylation state of DNA on binding by the enzyme, together with the effects on binding of the cofactor S-adenosyl-L-methionine. Our results indicate that the methyltransferase has two non-interacting S-adenosyl-L-methionine binding sites, each with a dissociation constant of 3.60 (+/- 0.42) microM determined by equilibrium dialysis, or 2.21 (+/- 0.29) microM determined by the displacement of a fluorescent probe. Ultraviolet light-induced crosslinking showed that S-adenosyl-L-methionine binds strongly only to the modification (M) subunits. Changes in the sedimentation velocity of the methyltransferase imply a protein conformational change due to S-adenosyl-L-methionine binding. Gel retardation results show that the binding of S-adenosyl-L-methionine to the methyltransferase enhances binding to both specific and non-specific DNAs, but the enhancement is greater for the specific DNA. Differences in binding affinities contribute to the recognition of the specific nucleotide sequence AAC(N)6GTGC by the methyltransferase in preference to a non-specific sequence. In contrast, although the complexes of unmodified and hemimethylated DNAs with the methyltransferase have different mobilities in non-denaturing gels, there appears to be no contribution of binding affinity to the distinction between these two substrates. Therefore, the preference for a hemimethylated substrate must be due to a difference in catalysis.     

A molecular model for the d chain of the giant haemoglobin from Lumbricus terrestris and its implications for subunit assembly

We have previously reported that rhodacyanine dyes, such as 1 and 2, exhibited a potent inhibitory effect on the growth of several tumor cells and that 4-oxothiazolidine (rhodanine) was an essential moiety for antitumor activity. On the basis of our foregoing work, two types of rhodacyanine dyes, which categorized into class I and II depending on the methine length, were synthesized and evaluated as a novel antitumor agent. Attention was particularly focused on the structure-activity study of two heteroaromatic rings. In class I, where the A rings were conjugated to rhodanine via two methine groups, compounds 1, 20, 23, and 24 were found to be efficacious in tumor-bearing nude mice model study, but they did not have the chemical properties (stability, solubility) suitable for clinical use. In contrast, in class II, where the A rings were directly conjugated to rhodanine, compounds 13 and 25, which possessed a benzothiazole moiety for the A ring, exhibited the favorable biological and chemical properties. Therefore, we decided to have a benzothiazole moiety as the A ring and introduce various heterocyclic groups for the B ring. As a result, the pyridinium ring was selected as the optimal moiety for the B ring (compound 13). Further, the variation of counteranion had a profound effect on solubility in water without influence on antitumor activity. Chloride anion was selected as the favorable anion with respect to synthetic method as well as solubility in water. Our study finally led us to the identification of compound 3 (MKT 077, 1-ethyl-2-[[3-ethyl-5-(methylbenzothiazolin-2-ylidene)-4-oxothi azolidin-2 -ylidene]methyl]pyridinium chloride) as the candidate for clinical trials and is currently subjected to further investigation as a potent antitumor agent in phase I clinical trial for the treatment of solid tumors.     

Role of the carbonyl group in thioester chain length recognition by the medium chain acyl-CoA dehydrogenase

Medium chain acyl-CoA dehydrogenase from pig kidney catalyzes the oxidation of acyl-CoA thioesters to trans-2-enoyl-CoA derivatives with an optimal chain length of about C-8. The binding energy for alkyl-SCoA thioethers shows no such optimum but increases linearly from C-2 to C-16 with a slope of about 390 cal/-CH2 group. In contrast, four types of CoA-thioester analogues (2-aza-acyl-, 3-thia-acyl-, 3-keto-acyl-, and trans-2-enoyl-) yield an incremental binding energy of about 800 cal/-CH2 group until a chain length of about C-8 is reached. The observed binding energy then decreases, or remains constant, with increasing chain length. Studies with dithiooctanoyl-CoA and 2-azadithiooctanoyl-CoA show that the C = S moiety is accommodated poorly by the medium chain dehydrogenase. A model for chain length discrimination, based on the crystal structure of the enzyme [Kim, J. J. P., Wang, M., & Paschke, R. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 7523-7527], is proposed in which hydrogen-bonding interactions between enzyme and thioester carbonyl oxygen atom are maximized at optimal chain lengths. Oversized chains decrease the frequency of effective alignment between enzyme and the C-1 to C-3 region of thioester ligands. Thus the extent of polarization of bound 4-thia-trans-2-enoyl-CoA thioesters decreases sharply with chains longer than C-12.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structure of restriction endonuclease BglI bound to its interrupted DNA recognition sequence

The crystal structure of the type II restriction endonuclease BglI bound to DNA containing its specific recognition sequence has been determined at 2.2 A resolution. This is the first structure of a restriction endonuclease that recognizes and cleaves an interrupted DNA sequence, producing 3' overhanging ends. BglI is a homodimer that binds its specific DNA sequence with the minor groove facing the protein. Parts of the enzyme reach into both the major and minor grooves to contact the edges of the bases within the recognition half-sites. The arrangement of active site residues is strikingly similar to other restriction endonucleases, but the co-ordination of two calcium ions at the active site gives new insight into the catalytic mechanism. Surprisingly, the core of a BglI subunit displays a striking similarity to subunits of EcoRV and PvuII, but the dimer structure is dramatically different. The BglI-DNA complex demonstrates, for the first time, that a conserved subunit fold can dimerize in more than one way, resulting in different DNA cleavage patterns.     

The RecD subunit of the RecBCD enzyme from Escherichia coli is a single-stranded DNA-dependent ATPase

We have expressed the RecD subunit of the RecBCD enzyme from Escherichia coli as a fusion protein with a 31-amino acid NH2-terminal extension including 6 consecutive histidine residues (HisRecD). The overexpressed fusion protein can be purified in urea-denatured form by metal chelate affinity chromatography. The mixture of renatured HisRecD protein and the RecB and RecC proteins has a high level of ATP-dependent nuclease activity with either single- or double-stranded DNA, enhanced DNA unwinding activity, enhanced ATP hydrolysis activity in the presence of a small DNA oligomer cosubstrate, and chi-cutting activity. These are all characteristics of the RecBCD holoenzyme. The HisRecD protein by itself hydrolyzes ATP in the presence of high concentrations of single-stranded DNA (polydeoxythymidine). The activity is unstable at 37 degrees C, but is measurable at room temperature (about 23 degrees C). The HisRecD has very little ATPase activity in the presence of a much shorter single-stranded DNA (oligodeoxy(thymidine)12). HisRecD hydrolyzes ATP more efficiently than GTP and UTP, and has very little activity with CTP. We also purified a fusion protein containing a Lys to Gln mutation in the putative ATP-binding site of RecD. This mutant protein has no ATPase activity, indicating that the observed ATP hydrolysis activity is intrinsic to the RecD protein itself.     

The kinetics of sigma subunit directed promoter recognition by E. coli RNA polymerase

Time-resolved laser UV irradiation and controlled proteolysis have been used to study the sequential recognition of the lac UV5 promoter by Escherichia coli RNA polymerase. Local rearrangements in the DNA, the appearance of intimate protein-DNA contacts, and structural changes within the sigma subunit together provide specific signatures that define major species populated during this process. At 22 degreesC, a first closed complex is characterised by a transient conformational change in the sigma subunit and by a distortion in the -35 region. Subsequently, direct contacts at -34 and at positions -8, -5 and -3 on the non-template strand appear prior to DNA strand separation. The contact in the -35 consensus region involves only the sigma subunit. This intermediate possesses different structural parameters from that formed by quenching open complexes from 37 degreesC to 14 degreesC. Sigma thus appears as the principal partner acting during promoter recognition, a strongly coupled process involving two major intermediates only.     

High resolution footprinting of a type I methyltransferase reveals a large structural distortion within the DNA recognition site

The type I DNA methyltransferase M.EcoR124I is a multi-subunit enzyme that binds to the sequence GAAN6RTCG, transferring a methyl group from S-adenosyl methionine to a specific adenine on each DNA strand. We have investigated the protein-DNA interactions in the complex by DNase I and hydroxyl radical footprinting. The DNase I footprint is unusually large: the protein protects the DNA on both strands for at least two complete turns of the helix, indicating that the enzyme completely encloses the DNA in the complex. The higher resolution hydroxyl radical probe shows a smaller, but still extensive, 18 bp footprint encompassing the recognition site. Within this region, however, there is a remarkably hyper-reactive site on each strand. The two sites of enhanced cleavage are co-incident with the two adenines that are the target bases for methylation, showing that the DNA is both accessible and highly distorted at these sites. The hydroxyl radical footprint is unaffected by the presence of the cofactor S-adenosyl methionine, showing that the distorted DNA structure induced by M.EcoR124I is formed during the initial DNA binding reaction and not as a transient intermediate in the reaction pathway.