Metal- and DNA-binding properties and mutational analysis of the transcription activating factor, B, of coliphage 186: a prokaryotic C4 zinc-finger protein

Thermoresponsive Metallo-protein-based Hybrid Hydro-gels for Reversible and Highly Selective Removal of Lead(II) from Water

It is interesting to develop biomaterials for easily removing ultra-trace toxic metal ions from the environment. Herein, we have synthesized a thermoresponsive hybrid hydrogel PNIPAM-co-PbrRP by incorporating a reconstituted lead-binding...

Evolution of non-genomic nuclear receptor function

Nuclear receptors (NRs) are responsible for the regulation of diverse developmental and physiological systems in metazoans. NR actions can be the result of genomic and non-genomic mechanisms depending on whether they act inside or outside of the nucleus respectively. While the actions of both mechanisms have been shown to be crucial to NR functions, non-genomic actions are considered less frequently than genomic actions. Furthermore, hypotheses on the origin and evolution of non-genomic NR signaling pathways are rarely discussed in the literature. Here we summarize non-genomic NR signaling mechanisms in the context of NR protein family evolution and animal phyla. We find that NRs across groups and phyla act via calcium flux as well as protein phosphorylation cascades (MAPK/PI3K/PKC). We hypothesize and discuss a possible synapomorphy of NRs in the NR1 and NR3 families, including the thyroid hormone receptor, vitamin D receptor, ecdysone receptor, retinoic acid receptor, steroid receptors, and others. In conclusion, we propose that the advent of non-genomic NR signaling may have been a driving force behind the expansion of NR diversity in Cnidarians, Placozoans, and Bilaterians.

Temperature-Driven Metalloprotein-Based Hybrid Hydrogels for Selective and Reversible Removal of Cadmium(II) from Water

To develop biomaterials that easily and reversibly remove trace amounts of metal ions, we synthesized PNIPAM-co-CadRP, a thermally sensitive hybrid hydrogel by immobilizing a reconstituted cadmium binding peptide (CadRP) derived from the metalloregulatory protein CadR in a poly(N-isopropylacrylamide) (PNIPAM) gel network. The hybrid hydrogel retains the properties of the immobilized peptide and highly sensitively and selectively binds Cd(II) ions. The thermally sensitive properties of the hybrid hydrogel, which swells at low temperatures (<34 °C) and shrinks at high temperatures, provides a driving force sufficient to alternate the conformation of the immobilized CadRP such that the peptide captures and releases metal ions at high and low temperatures, respectively. Using this novel hybrid gel, we captured nanomolar Cd(II) from samples of environmental water in a highly efficient manner, leading to a practical and repeatedly reusable material to remediate our environment.

A single C4 Zinc finger-containing protein from Litopenaeus vannamei involved in antibacterial responses

The Zinc finger domains (ZnFs), which contain finger-like protrusions stabilized by zinc ions and function to bind DNA, RNA, protein and lipid substrates, are ubiquitously present in a large number of proteins. In this study, a novel protein containing a single C4 type Znf domain (SZnf) was identified from Pacific white shrimp, Litopenaeus vannamei and its role in immunity was further investigated. The ZnF domain of SZnF but not other regions shared high homology with those of fushi tarazu-factor 1 (FTZ-F1) proteins. The SZnF protein was mainly localized in the cytoplasm and was also present in the nucleus at a small level. SZnF was high expressed in the scape and muscle tissues of healthy shrimp and its expression in gill and heptopancreas was strongly up-regulated during bacterial infection. Silencing of SZnf in vivo could strongly increase the susceptibility of shrimp to infection with Vibrio parahaemolyticus but not white spot syndrome virus (WSSV), suggesting that SZnf could be mainly involved in antibacterial responses. Both dual luciferase reporter assays and real-time PCR analysis demonstrated that SZnf could positively regulate the expression of various antimicrobial peptides in vitro and in vivo, which could be part of the mechanism underlying its antibacterial effects. In summary, the current study could help learn more about the function of ZnF-containing proteins and the regulatory mechanisms of immune responses against pathogen infection in crustaceans.

Variable primary coordination environments of Cd(II) binding to three helix bundles provide a pathway for rapid metal exchange

Members of the ArsR/SmtB family of transcriptional repressors, such as CadC, regulate the intracellular levels of heavy metals like Cd(II), Hg(II), and Pb(II). These metal sensing proteins bind their target metals with high specificity and affinity, however, a lack of structural information about these proteins makes defining the coordination sphere of the target metal difficult. Lingering questions as to the identity of Cd(II) coordination in CadC are addressed via protein design techniques. Two designed peptides with tetrathiolate metal binding sites were prepared and characterized, revealing fast exchange between CdS3O and CdS4 coordination spheres. Correlation of (111m)Cd PAC spectroscopy and (113)Cd NMR spectroscopy suggests that Cd(II) coordinated to CadC is in fast exchange between CdS3O and CdS4 forms, which may provide a mechanism for rapid sensing of heavy metal contaminants by this regulatory protein.

Positive allostery in metal ion binding by a cooperatively folded β-peptide bundle

Metal ion binding is exploited by proteins in nature to catalyze reactions, bind molecules, and favor discrete structures, but it has not been demonstrated in β-peptides or their assemblies. Here we report the design, synthesis, and characterization of a β-peptide bundle that uniquely binds two Cd(II) ions in a distinct bicoordinate array. The two Cd(II) ions bind with positive allosteric cooperativity and increase the thermodynamic stability of the bundle by more than 50 °C. This system provides a unique, synthetic context to explore allosteric regulation and should pave the way to sophisticated molecular assemblies with catalytic and substrate-sensing functions that have historically not been available to de novo designed synthetic proteomimetics in water.

Genomic sequence of temperate phage Smp131 of Stenotrophomonas maltophilia that has similar prophages in xanthomonads

BACKGROUND

Stenotrophomonas maltophilia is a ubiquitous Gram-negative bacterium previously named as Xanthomonas maltophilia. This organism is an important nosocomial pathogen associated with infections in immunocompromised patients. Clinical isolates of S. maltophilia are mostly resistant to multiple antibiotics and treatment of its infections is becoming problematic. Several virulent bacteriophages, but not temperate phage, of S. maltophilia have been characterized.

RESULTS

In this study, a temperate myophage of S. maltophilia (Smp131) was isolated and characterized. Sequence analysis showed that its genome is 33,525-bp long with 47 open reading frames (ORFs). Its similarity to P2-like phages and prophages in S. maltophilia and several Xanthomonas pathovars includes genomic organization, arrangement of several operons, and possession of a slippery sequence T₇G for translational frameshifting in tail assembly genes. Smp131 encodes a tyrosine family integrase that shares low degrees of similarity with those of other phages and a lysin belonging to family 19 chitinase that is observed in plants and some bacteria, although not in phages. tRNA are the preferred sites for host integration of Smp131 and the related phages: tRNA-Thr for Smp131 and prophage of S. maltophilia K279a; tRNA-Lys for prophages of X. campestris pv. campestris ATCC33913, X. oryzae pv. oryzae strains MAFF311018, and KACC10331; and tRNA-Asn for prophage of X. oryzae pv. oryzae PXO99A and remnant of X. axonopodis pv. citri 306. Regions flanking the prophages are varied highly in nucleotide sequence and rich in transposase genes, suggesting that frequent insertion/excision had occurred.

CONCLUSIONS

Prevalence of closely related prophages in Stenotrophomonas and Xanthomonads may have contributed to the diversity of these closely related species owing to possible horizontal gene transfer mediated by the phages.

Pirates of the Caudovirales

Molecular piracy is a biological phenomenon in which one replicon (the pirate) uses the structural proteins encoded by another replicon (the helper) to package its own genome and thus allow its propagation and spread. Such piracy is dependent on a complex web of interactions between the helper and the pirate that occur at several levels, from transcriptional control to macromolecular assembly. The best characterized examples of molecular piracy are from the E. coli P2/P4 system and the S. aureus SaPI pathogenicity island/helper system. In both of these cases, the pirate element is mobilized and packaged into phage-like transducing particles assembled from proteins supplied by a helper phage that belongs to the Caudovirales order of viruses (tailed, dsDNA bacteriophages). In this review we will summarize and compare the processes that are involved in molecular piracy in these two systems.

Elucidation of the functional metal binding profile of a Cd(II)/Pb(II) sensor CmtR(Sc) from Streptomyces coelicolor

Metal homeostasis and resistance in bacteria is maintained by a panel of metal-sensing transcriptional regulators that collectively control transition metal availability and mediate resistance to heavy metal xenobiotics, including As(III), Cd(II), Pb(II), and Hg(II). The ArsR family constitutes a superfamily of metal sensors that appear to conform to the same winged helical, homodimeric fold, that collectively "sense" a wide array of beneficial metal ions and heavy metal pollutants. The genomes of many actinomycetes, including the soil dwelling bacterium Streptomyces coelicolor and the human pathogen Mycobacterium tuberculosis, encode over ten ArsR family regulators, most of unknown function. Here, we present the characterization of a homologue of M. tuberculosis CmtR (CmtR(Mtb)) from S. coelicolor, denoted CmtR(Sc). We show that CmtR(Sc), in contrast to CmtR(Mtb), binds two monomer mol equivalents of Pb(II) or Cd(II) to form two pairs of sulfur-rich coordination complexes per dimer. Metal site 1 conforms exactly to the alpha4C site previously characterized in CmtR(Mtb) while metal site 2 is coordinated by a C-terminal vicinal thiolate pair, Cys110 and Cys111. Biological assays reveal that only Cd(II) and, to a lesser extent, Pb(II) mediate transcriptional derepression in the heterologous host Mycobacterium smegmatis in a way that requires metal site 1. In contrast, mutagenesis of metal site 2 ligands Cys110 or Cys111 significantly reduces Cd(II) responsiveness, with no detectable effect on Pb(II) sensing. The implications of these findings on the ability to predict metal specificity and function from metal-site signatures in the primary structure of ArsR family proteins are discussed.

Analysis of DNA binding by a eubacterial zinc finger transcription factor

The Serratia marcescens NucC protein is structurally and functionally homologous to the P2 Ogr family of eubacterial zinc finger transcription factors required for late gene expression in P2- and P4-related bacteriophages. These activators exhibit site-specific binding to a conserved DNA sequence, TGT-N(3)-R-N(4)-Y-N(3)-aCA, that is located upstream of NucC-dependent S. marcescens promoters and the late promoters of P2-related phages. In this report we describe the interactions of NucC with the P2 FETUD late operon promoter P(F). NucC is shown to bind P(F) as a tetramer and to make 12 symmetrical contacts to the DNA phosphodiester backbone. The backbone contacts are centered on the TGT-N(3)-R-N(4)-Y-N(3)-aCA motif. Major groove base contacts can be seen at most positions within the approximately 24-bp binding site. Minor groove contacts map to adjacent positions in the downstream half of the binding site, which corresponds to the area in which the DNA also appears to be bent by NucC binding. NucC binding provides a new example of protein-DNA interaction that is strikingly different from the DNA binding demonstrated for eukaryotic zinc-finger transcription factors.

Multiple metal binding domains enhance the Zn(II) selectivity of the divalent metal ion transporter AztA

Transition metal-transporting P1B-type CPx ATPases play crucial roles in mediating metal homeostasis and resistance in all cells. The degree to which N-terminal metal binding domains (MBDs) confer metal specificity to the transporter is unclear. We show that the two MBDs of the Zn/Cd/Pb effluxing pump Anabaena AztA are functionally nonequivalent, but only with respect to zinc resistance. Inactivation of the a-MBD largely abrogates resistance to high intracellular Zn(II) levels, whereas inactivation of the b-MBD is not as deleterious. In contrast, inactivation of either the a- or b-MBD has little measurable impact on Cd(II) and Pb(II) resistance. The membrane proximal b-MBD binds Zn(II) with a higher affinity than the distal N-terminal a-MBD. Facile Zn(II)-specific intermolecular transfer from the a-MBD to the higher-affinity b-MBD is readily observed by 1H-15N HSQC spectroscopy. Unlike Zn(II), Cd(II) and Pb(II) form saturated 1:1 S4 or S3(O/N) complexes with AztAaHbH, where a single metal ion bridges the two MBDs. We propose that the tandem MBDs enhance Zn(II)-specific transport, while stabilizing a non-native inter-MBD Cd/Pb cross-linked structure that is a poor substrate and/or regulator for the transporter.

Evolution of P2-like phages and their impact on bacterial evolution

The structural genes of P2-like phages are almost identical between different isolates of Escherichia coli, whereas the regulatory genes and host integration sites are more variable. The variation in P2-like phages infecting other gamma-proteobacteria is broader, but their structural genes seem to follow the evolution of their host bacteria. Taken together, this suggests that P2-like phages and their hosts are coevolving.

Mutational analysis of the activator of late transcription, Alt, in the lactococcal bacteriophage TP901-1

An activator protein, Alt, synthesized during the early state of lytic infection is required for transcription of the late operon in the lactococcal phage TP901-1. In order to identify amino acid residues in the Alt protein required for activation of the TP901-1 late promoter, P(late), hydroxylamine mutagenesis was performed, resulting in almost saturating mutagenesis of alt. Twenty-three different non-functional alt alleles containing one, and in one case two amino acid exchanges were isolated and analyzed. Eight of the twenty-three mutant proteins were still able to activate the P(late) promoter to some extent. Our results show that alt encodes a protein of 16.7 kDa and that the last fourteen amino acids in the C-terminal part of the protein are required for activation of the P(late) promoter. By combining sequence analysis with experimental data we suggest that the C-terminal half of the Alt protein contains a helix-turn-helix-like motif involved in DNA binding. We also propose that the C-terminal half of the Alt protein may be involved in interactions with the bacterial RNA polymerase, whereas the N-terminal half of the protein is proposed to be important for the overall protein structure.

Peptidic models for the binding of Pb(II), Bi(III) and Cd(II) to mononuclear thiolate binding sites

Herein, we evaluate the binding of Pb(II) and Bi(III) to cysteine-substituted versions of the TRI peptides [AcG-(LKALEEK)4G-NH2] which have previously been shown to bind Hg(II) and Cd(II) in unusual geometries as compared with small-molecule thiol ligands in aqueous solutions. Studies of Pb(II) and Bi(III) with the peptides give rise to complexes consistent with the metal ions bound to three sulfur atoms with M-S distances of 2.63 and 2.54 A, respectively. Competition experiments between the metal ions Pb(II), Cd(II), Hg(II) and Bi(III) for the peptides show that Hg(II) has the highest affinity, owing to the initial formation of the extremely strong HgS2 bond. Cd(II) and Pb(II) have comparable binding affinities at pH > 8, while Bi(III) displays the weakest affinity, following the model, M(II) + (TRI LXC)3(3-) --> M(II)(TRI LXC)3(-). While the relevant equilibria for Hg(II) binding to the TRI peptides corresponds to a strong first step forming Hg(TRI LXC)2(HTRI LXC), followed by a single deprotonation to give Hg(TRI LXC)3(-), the binding of Cd(II) and Pb(II) is consistent with initial formation of M(II)(TRI LXC)(HTRI LXC)2 (+) at pH < 5 followed by a two-proton dissociation step (pK(a2)) yielding M(II)(TRI LXC)3(-). Pb(II)(TRI LXC)(HTRI LXC)2(+) converts to Pb(II)(TRI LXC)3(-) at slightly lower pH values than the corresponding Cd(II)-peptide complexes. In addition, Pb(II) displays a lower pK (a) of binding to the "d"-substituted peptide, (TRI L12C, pK(a2) = 12.0) compared with the "a"-substituted peptide, (TRI L16C, pK (a2) = 12.6), the reverse of the order seen for Hg(II) and Cd(II). Pb(II) also showed a stronger binding affinity for TRI L12C (K(bind) = 3.2 x 10(7) M(-1)) compared with that with TRI L16C (K(bind) = 1.2 x 10(7) M(-1)) at pH > 8.

Identification of upstream sequences essential for activation of a bacteriophage P2 late promoter

We have carried out a mutational scan of the upstream region of the bacteriophage P2 FETUD late operon promoter, P(F), which spans an element of hyphenated dyad symmetry that is conserved among all six of the P2 and P4 late promoters. All mutants were assayed for activation by P4 delta in vivo, by using a lacZ reporter plasmid, and a subset of mutants was assayed in vitro for delta binding. The results confirm the critical role of the three complementary nucleotides in each half site of the upstream element for transcription factor binding and for activation of transcription. A trinucleotide DNA recognition site is consistent with a model in which these transcription factors bind via a zinc finger motif. The mutational scan also led to identification of the -35 region of the promoter. Introduction of a sigma(70) -35 consensus sequence resulted in increased constitutive expression, which could be further stimulated by delta. These results indicate that activator binding to the upstream region of P2 late promoters compensates in part for poor sigma(70) contacts and helps to recruit RNA polymerase holoenzyme.

Purification and in vitro characterization of the Serratia marcescens NucC protein, a zinc-binding transcription factor homologous to P2 Ogr

NucC is structurally and functionally homologous to a family of prokaryotic zinc finger transcription factors required for late gene expression in P2- and P4-related bacteriophages. Characterization of these proteins in vitro has been hampered by their relative insolubility and tendency to aggregate. We report here the successful purification of soluble, active, wild-type NucC protein. Purified NucC exhibits site-specific binding to a conserved DNA sequence that is located upstream of NucC-dependent Serratia marcescens promoters and the late promoters of P2-related phages. This sequence is sufficient for binding of NucC in vitro. NucC binding to the S. marcescens nuclease promoter P(nucA) and to the sequence upstream of the P2 late promoter P(F) is accompanied by DNA bending. NucC protects about 25 nucleotides of the P(F) upstream region from DNase I digestion, and RNA polymerase protects the promoter region only in the presence of NucC. Template DNA, RNA polymerase holoenzyme, and purified NucC are the only macromolecular components required for transcription from P(F) in vitro.

Multiple bacteria encode metallothioneins and SmtA-like zinc fingers

Zinc is essential but toxic in excess. Bacterial metallothionein, SmtA from Synechococcus PCC 7942, sequesters and detoxifies four zinc ions per molecule and contains a zinc finger structurally similar to eukaryotic GATA. The dearth of other reported bacterial metallothioneins has been surprising. Here we describe related bacterial metallothioneins (BmtA) from Anabaena PCC 7120, Pseudomonas aeruginosa and Pseudomonas putida that bind multiple zinc ions with high stability towards protons. Thiol modification demonstrates that cysteine coordinates zinc in all of these proteins. Additionally, (111)Cd-NMR, and (111)Cd-edited (1)H-NMR, identified histidine ligands in Anabaena PCC 7120 BmtA, analogous to SmtA. A related Escherichia coli protein bound only a single zinc ion, via four cysteine residues, with low stability towards protons; (111)Cd-NMR and (111)Cd-edited (1)H-NMR confirmed exclusive cysteine-coordination, and these cysteine residues reacted rapidly with 5,5'-dithiobis-(2-nitrobenzoic acid). (1)H-NMR of proteins from P. aeruginosa, Anabaena PCC 7120 and E. coli generated fingerprints diagnostic for the GATA-like zinc finger fold of SmtA. These studies reveal first the existence of multiple bacterial metallothioneins, and second proteins with SmtA-like lone zinc fingers, devoid of a cluster,and designated GatA. We have identified 12 smtA-like genes in sequence databases including four of the gatA type.

Elucidation of primary (alpha(3)N) and vestigial (alpha(5)) heavy metal-binding sites in Staphylococcus aureus pI258 CadC: evolutionary implications for metal ion selectivity of ArsR/SmtB metal sensor proteins

Despite a common evolutionary origin, individual members of the ArsR/SmtB family of bacterial metal-responsive transcriptional repressors sense a wide range of heavy-metal ions. The molecular basis for this metal ion selectivity is unclear. Here, we establish that Staphylococcus aureus plasmid pI258 CadC, a Cd(II)/Pb(II)/Bi(III)/Zn(II) sensor, contains two distinct metal-binding sites: a thiolate-rich alpha(3)N site comprised exclusively of cysteine ligands that preferentially binds larger, softer metal ions such as Cd(II), Pb(II) and Bi(III); and a second C-terminal alpha(5) site, found at the dimer interface, that is devoid of cysteine ligands and preferentially binds smaller, harder metal ions [Co(II) and Zn(II)] concurrently with metal binding to the alpha(3)N site. Optical absorption and X-ray spectroscopies reveal that the alpha(3)N site can adopt distinct coordination geometries in order to accommodate different metal ions, i.e. Cd(II), Bi(III), Co(II) and Zn(II) form distorted tetrahedral S(4) complexes, while Pb(II) adopts a trigonal S(3) complex. Characterization of mutant CadCs reveals that the alpha(3)N site is composed of Cys58 and Cys60 from the alpha(3) helix of the helix-turn-helix DNA-binding domain and Cys7 and/or Cys11 from the N-terminal "arm" of CadC; Cys11 is excluded from the Pb(II) coordination sphere. Only the thiolate-rich alpha(3)N site is metalloregulatory for repressor binding to a fluorescein-labeled cad O/P oligonucleotide upon coordination to Cd(II), Pb(II), Bi(III), Zn(II), and weakly for Co(II). Substitution of Cys60 and Cys7 with non-ligating residues specifically abrogates metal-dependent negative regulation of cad O/P binding, despite the fact that C60G and C7G CadCs maintain high affinity for metals in altered coordination complexes. These findings reveal that formation of metal coordination bonds to Cys7 and Cys60 play primary roles in transducing the allosteric response in CadC. The evolutionary implications for metal ion selectivity of ArsR/SmtB metal sensor proteins are discussed.

Effect of static magnetic field on E. coli cells and individual rotations of ion-protein complexes

The effect of week static magnetic fields on Escherichia coli K12 AB1157 cells was studied by the method of anomalous viscosity time dependencies (AVTD). The AVTD changes were found when E. coli cells were exposed to static fields within the range from 0 to 110 microT. The dependence of the effect on the magnetic flux density had several extrema. These results were compared with theoretical predictions of the ion interference mechanism. This mechanism links the dissociation probability of ion--protein complexes to parameters of magnetic fields. The mechanism was extended to the case of rotating complexes. Calculations were made for several ions of biological relevance. The results of simulations for Ca(2+), Mg(2+), and Zn(2+) showed a remarkable consistency with experimental data. An important condition for this consistency was that all complexes rotate with the same speed approximately 18 revolutions per second (rps). This suggests that the rotation of the same carrier for all ion--protein complexes may be involved in the mechanism of response to the magnetic field. We believe that this carrier is DNA.

Cloning, expression, and purification of a thermostable nonhomodimeric restriction enzyme, BslI

BslI is a thermostable type II restriction endonuclease with interrupted recognition sequence CCNNNNN/NNGG (/, cleavage position). The BslI restriction-modification system from Bacillus species was cloned and expressed in Escherichia coli. The system is encoded by three genes: the 2,739-bp BslI methylase gene (bslIM), the bslIRalpha gene, and the bslIRbeta gene. The alpha and beta subunits of BslI can be expressed independently in E. coli in the absence of BslI methylase (M.BslI) protection. BslI endonuclease activity can be reconstituted in vitro by mixing the two subunits together. Gel filtration chromatography and native polyacrylamide gel electrophoresis indicated that BslI forms heterodimers (alphabeta), heterotetramers (alpha(2)beta(2)), and possibly oligomers in solution. Two beta subunits can be cross-linked by a chemical cross-linking agent, indicating formation of heterotetramer BslI complex (alpha(2)beta(2)). In DNA mobility shift assays, neither subunit alone can bind DNA. DNA mobility shift activity was detected after mixing the two subunits together. Because of the symmetric recognition sequence of the BslI endonuclease, we propose that its active form is alpha(2)beta(2). M.BslI contains nine conserved motifs of N-4 cytosine DNA methylases within the beta group of aminomethyltransferase. Synthetic duplex deoxyoligonucleotides containing cytosine hemimethylated or fully methylated at N-4 in BslI sites in the first or second cytosine are resistant to BslI digestion. C-5 methylation of the second cytosine on both strands within the recognition sequence also renders the site refractory to BslI digestion. Two putative zinc fingers are found in the alpha subunit of BslI endonuclease.

The complete nucleotide sequence of phi CTX, a cytotoxin-converting phage of Pseudomonas aeruginosa: implications for phage evolution and horizontal gene transfer via bacteriophages

phi CTX is a cytotoxin-converting phage isolated from Pseudomonas aeruginosa. In this study, we determined the complete nucleotide sequence of the phi CTX phage genome. The precise genome size was 35,538 bp with 21 base 5'-extruding cohesive ends. Forty-seven open reading frames (ORFs) were identified on the phi CTX genome, including two previously identified genes, ctx and int. Among them, 15 gene products were identified in the phage particle by protein microsequencing. The most striking feature of the phi CTX genome was an extensive homology with the coliphage P2 and P2-related phages; more than half of the ORFs (25 ORFs) had marked homology to P2 genes with 28.9-65.8% identity. The gene arrangement on the genome was also highly conserved for the two phages, although the G + C content and codon usage of most phi CTX genes were similar to those of the host P. aeruginosa chromosome. In addition, phi CTX was found to share several common features with P2, including the morphology, non-inducibility, use of lipopolysaccharide core oligosaccharide as receptor and Ca(2+)-dependent receptor binding. These findings indicate that phi CTX is a P2-like phage well adapted to P. aeruginosa, and provide clear evidence of the intergeneric spread and evolution of bacteriophages. Furthermore, comparative analysis of genome structures of phi CTX, P2 and other P2 relatives revealed the presence of several hot-spots where foreign DNAs, including the cytotoxin gene, were inserted. They appear to be deeply concerned in the acquisition of various genes that are horizontally transferred by bacteriophage infection.

Mutational analysis of a satellite phage activator

The late gene activator, Delta, of satellite phage P4 is more efficient than the Delta of satellite phage phiR73 in utilizing a P2 helper prophage that lacks an activator (ogr) gene. Analysis of P4 Delta is complicated by the fact that this protein contains two tandem phiR73 Delta-like domains. We performed a mutational analysis of phiR73 Delta, in order to select mutations that might not be found using P4 Delta. The host RNA polymerase alpha subunit mutation rpoA155 (L289F) blocks the growth of P2, P4, and P4 carrying the delta gene of phiR73. A mutant of this latter phage that can grow in the presence of rpoA155 carries a V19M mutation in phiR73 Delta. This suggests that aa 19 contacts RNA polymerase, in addition to the aa residues 13, 42 and 44, that have been implicated in interactions with RNA polymerase by previous mutational analyses of P2 ogr and P4 delta. In corroboration of the proposed role of the regions at aa residues 19, 42, and 44, we found phiR73 Delta mutations in these regions that showed a reduced activation of late gene expression, but a normal ability to bind to late gene promoters. All activators in the Delta class contain four Cys residues that bind Zn2+. Mutation of these aa residues in phiR73 Delta eliminated late gene activation. Spectroscopic analysis of these mutant proteins revealed that they were unable to bind Zn2+. Histidine residues were substituted for two of the Cys residues (C30 and C35), changing a C2C2 type Zn-binding motif to a C2H2 motif. Although His residues are used in coordinating Zn2+ in other proteins, these His substitutions resulted in complete loss of activity and the inability to bind Zn2+.

A complex control system for transcriptional activation from the sid promoter of bacteriophage P4

The sid gene promoter (Psid), which controls expression of the late genes from satellite phage P4, is activated by a unique class of small DNA-binding proteins. The activators from both satellite and helper phages stimulate transcription from Psid. These activators bind to sites centered at position -55 in all the helper and satellite phage late promoters. P4 Psid is unique in that it has an additional activator binding site centered at position -18 (site II). We have constructed a mutant of site II that no longer binds activators. Transcription under the control of satellite phage activators is increased by the site II mutation. In contrast, helper phage activators do not show this increase in transcription from Psid mutated at site II. Competition gel shift analysis reveals that the P4 satellite phage activator, Delta, binds eightfold better to site II than to site I. The products of the sid transcription unit are needed only when a helper phage is present; thus, the satellite phage activators repress transcription until the helper is present to supply a nonrepressing activator.

The late-expressed region of the temperate coliphage 186 genome

The late-lytic region of the genome of bacteriophage 186 encodes the phage proteins that synthesize the complex viral particle and lyse the bacterial host. We report the completion of the DNA sequence of the late region and the assignment of 18 previously identified genes to open reading frames in the sequence. The 186 late region is similar to the late region of phage P2, sharing 26 genes of known function: the single gene for activation of late gene transcription, 6 genes for construction of DNA-containing heads, 16 for tail morphogenesis, and 3 for cell lysis. We identified two 186 late genes with unknown function; one is homologous to previously unrecognised genes in P2, HP1, and phiCTX, and the other may modulate DNA packaging. The 186 late region, like the rest of the genome, lacks the lysogenic conversion genes that are carried by P2, allowing the 186 late region to be transcribed from only three late promoters rather than four. The relative absence of lysogenic conversion genes in 186 suggests that the two phages have evolved to use the lytic and lysogenic reproductive modes to different extents.

A carboxyl-terminal Cys2/His2-type zinc-finger motif in DNA primase influences DNA content in Synechococcus PCC 7942

The DNA primase gene, dnaG, has been isolated from the cyanobacterium Synechococcus PCC 7942. It is not part of a macromolecular synthesis operon but is co-transcribed with pheT and located adjacent to the metallothionein divergon, smt. At the carboxyl terminus of this DnaG is a Cys2/His2 zinc-finger motif. The carboxyl-terminal 91 residues bound 65Zn and 0.95 g atom of Zn2+ mol-1 were detected with 4-(2-pyridylazo)resorcinol. Following exposure to Cd2+, 0.95 g atom of Cd2+ was displaced by 2 equivalents of p-(hydroxymercuri) phenylsulfonate mol-1, while only 0.03 g atom of Cd2+ was displaced mol-1 polypeptide missing the carboxyl-terminal (residue 592 onward) zinc-finger motif. Zn2+ caused an increase in intensity, and a reduction in wavelength, of Trp fluorescence at the tip of the predicted zinc-finger, while EDTA caused the converse. Cells containing a single chromosomal codon substitution (C597S), altering the zinc-finger, were generated by exploiting Zn2+-sensitive smt mutants and the proximity of dnaG to smt. Cells in which smt and dnaG(C597S) had integrated into the chromosome were selected via restored Zn2+ tolerance. Synechococcus PCC 7942 and its dnaG(C597S) mutant grew at equivalent rates, but the latter had a reduced number of chromosomes.