Domain-swapped structure of a mutant of cyanovirin-N

Cyanovirin-N (CV-N) is a potent 11 kDa HIV-inactivating protein that binds with high affinity to the HIV surface envelope protein gp120. A double mutant P51S/S52P of CV-N was engineered by swapping two critical hinge-region residues Pro51 and Ser52. This mutant has biochemical and biophysical characteristics equivalent to the wild-type CV-N and its structure resembles that of wild-type CV-N. However, the mutant shows a different orientation in the hinge region that connects two domains of the protein. The observation that this double mutant crystallizes under a wide variety of conditions challenges some of the current hypotheses on domain swapping and on the role of hinge-region proline residues in domain orientation. The current structure contributes to the understanding of domain swapping in cyanovirins, permitting rational design of domain-swapped CV-N mutants.     

Flipping the switch from monomeric to dimeric CV-N has little effect on antiviral activity

Cyanovirin-N can exist in solution in monomeric and domain-swapped dimeric forms, with HIV-antiviral activity being reported for both. Here we present results for CV-N variants that form stable solution dimers: the obligate dimer [DeltaQ50]CV-N and the preferential dimer [S52P]CV-N. These variants exhibit comparable DeltaG values (10.6 +/- 0.5 and 9.4 +/- 0.5 kcal.mol(-1), respectively), similar to that of stabilized, monomeric [P51G]CV-N (9.8 +/- 0.5 kcal.mol(-1)), but significantly higher than wild-type CV-N (4.1 +/- 0.2 kcal.mol(-1)). During folding/unfolding, no stably folded monomer was observed under any condition for the obligate dimer [DeltaQ50]CV-N, whereas two monomeric, metastable species were detected for [S52P]CV-N at low concentrations. This is in contrast to our previous results for [P51G]CV-N and wild-type CV-N, for which the dimeric forms were found to be the metastable species. The dimeric mutants exhibit comparable antiviral activity against HIV and Ebola, similar to that of wild-type CV-N and the stabilized [P51G]CV-N variant.     

Stability of wild-type and mutant RTEM-1 beta-lactamases: effect of the disulfide bond

Uniquely among class A beta-lactamases, the RTEM-1 and RTEM-2 enzymes contain a single disulfide bond between Cys 77 and Cys 123. To study the possible role of this naturally occurring disulfide in stabilizing RTEM-1 beta-lactamase and its mutants at residue 71, this bond was removed by introducing a Cys 77----Ser mutation. Both the wild-type enzyme and the single mutant Cys 77----Ser confer the same high levels of resistance to ampicillin in vivo to Escherichia coli; at 30 degrees C the specific activity of purified Cys 77----Ser mutant is also the same as that of the wild-type enzyme. Also, neither wild-type enzyme nor the Cys 77----Ser mutant is inactivated by brief exposure to p-hydroxymercuribenzoate. However, above 40 degrees C the mutant enzyme is less stable than wild-type enzyme. After introduction of the Cys 77----Ser mutation, none of the double mutants (containing the second mutations at residue 71) confer resistance to ampicillin in vivo at 37 degrees C; proteins with Ala, Val, Leu, Ile, Met, Pro, His, Cys, and Ser at residue 71 confer low levels of resistance to ampicillin in vivo at 30 degrees C. The use of electrophoretic blots stained with antibodies against beta-lactamase to analyze the relative quantities of mutant proteins in whole-cell extracts of E. coli suggests that all 19 of the doubly mutant enzymes are proteolyzed much more readily than their singly mutant analogues (at Thr 71) that contain a disulfide bond.(ABSTRACT TRUNCATED AT 250 WORDS)     

Solution and crystal structures of a sugar binding site mutant of cyanovirin-N: no evidence of domain swapping

The cyanobacterial lectin Cyanovirin-N (CV-N) exhibits antiviral activity against HIV at a low nanomolar concentration by interacting with high-mannose oligosaccharides on the virus surface envelope glycoprotein gp120. Atomic structures of wild-type CV-N revealed a monomer in solution and a domain-swapped dimer in the crystal, with the monomer comprising two independent carbohydrate binding sites that individually bind with micromolar affinity to di- and trimannoses. In the mutant CVN(mutDB), the binding site on domain B was abolished and the protein was found to be completely inactive against HIV. We determined the solution NMR and crystal structures of this variant and characterized its sugar binding properties. In solution and the crystal, CVN(mutDB) is a monomer and no domain-swapping was observed. The protein binds to Man-3 and Man-9 with similar dissociation constants ( approximately 4 muM). This confirms that the nanomolar activity of wild-type CV-N is related to the multisite nature of the protein carbohydrate interaction.     

Site-directed mutants of the cAMP receptor protein--DNA binding of five mutant proteins

Oligonucleotide-directed mutagenesis was employed to generate mutants of the cAMP receptor protein (CRP) of Escherichia coli. The mutant proteins were purified to homogeneity and tested for stability and DNA binding. It is shown that mutations at the position of Arg180 abolish specific DNA binding, whereas those at the position Arg185 have very little effect. Both positions have previously been implicated as crucial for the specific interaction between CRP and DNA. The Ser128----Ala mutant shows a slight reduction in DNA binding affinity relative to wild-type. All mutants investigated show similar stability profiles to wild-type CRP with respect to thermolysin proteolysis as a function of temperature.     

Crystal structure of the double azurin mutant Cys3Ser/Ser100Pro from Pseudomonas aeruginosa at 1.8 A resolution: its folding-unfolding energy and unfolding kinetics

Azurin is a cupredoxin, which functions as an electron carrier. Its fold is dominated by a beta-sheet structure. In the present study, azurin serves as a model system to investigate the importance of a conserved disulphide bond for protein stability and folding/unfolding. For this purpose, we have examined two azurin mutants, the single mutant Cys3Ser, which disrupts azurin's conserved disulphide bond, and the double mutant Cys3Ser/Ser100Pro, which contains an additional mutation at a site distant from the conserved disulphide. The crystal structure of the azurin double mutant has been determined to 1.8 A resolution(2), with a crystallographic R-factor of 17.5% (R(free)=20.8%). A comparison with the wild-type structure reveals that structural differences are limited to the sites of the mutations. Also, the rates of folding and unfolding as determined by CD and fluorescence spectroscopy are almost unchanged. The main difference to wild-type azurin is a destabilisation by approximately 20 kJ x mol(-1), constituting half the total folding energy of the wild-type protein. Thus, the disulphide bond constitutes a vital component in giving azurin its stable fold.     

The role of thioredoxin in filamentous phage assembly. Construction, isolation, and characterization of mutant thioredoxins

Filamentous phage assembly in vivo shows an absolute requirement for thioredoxin and a partial requirement for thioredoxin reductase. Mutants in which one or both of the active site cysteine residues of thioredoxin were changed to alanine or serine were constructed and shown to support filamentous phage assembly. Some of the mutants were almost as effective as wild-type thioredoxin, while others supported phage assembly only when high levels of the mutant protein were present in the infected cell. The mutant proteins were all inactive in an assay which couples oxidation of NADPH to reduction of 5,5'-dithiobis-2-nitrobenzoic acid) via thioredoxin reductase and thioredoxin. These active site mutants make phage assembly completely independent of thioredoxin reductase, which suggests that the phage needs, and the active site mutants provide, the proteins in the reduced conformation. Other mutants were isolated on the basis of their failure to support filamentous phage growth. These specified mutant thioredoxin proteins with varying levels of redox activity in vivo and in vitro. The locations of these mutations suggest that the surface of thioredoxin thought to interact with thioredoxin reductase also interacts with the filamentous phage assembly machinery. An in vivo assay for thioredoxin redox function, based on the ability of cells to utilize methionine sulfoxide, was developed. Met- cells containing mutant thioredoxins that are inactive in vitro do not form colonies on plates containing methionine sulfoxide as the sole methionine source.     

DNA elongation rates and growing point distributions of wild-type phage T4 and a DNA-delay amber mutant

The rates of DNA elongation by wild-type phage T4 and a gene 52 DNA-delay am mutant were estimated by pulse-labeling infected cells with tritiated thymidine and visualizing the gently extracted DNA by autoradiography. The estimated rate of chain elongation of wild-type DNA was 749 nucleotides/second early in synthesis and 516 to 581 nucleotides/second at a later time. The rate of DNA elongation by the am mutant was measured to be 693, 758 and 829 nucleotides/second during successive stages of synthesis, indicating that elongation was not slower than in wild-type. The kinetics of DNA increase after infection of host cells by wild-type phage T4 or by the gene 52 DNA-delay am mutant was followed using [methyl-³H]thymidine uptake into acid-insoluble material. It was found that DNA increase in both wild-type and am infections could be represented as exponential during early times and linear during late times of DNA synthesis. From the rates of DNA increase and the rates of DNA elongation we were able to estimate the number of growing points per chromosome equivalent of template DNA during the exponential and linear phases. Our estimates for wild-type phage were 0.55 and 0.71 to 0.80 growing points per chromosome equivalent of template DNA in the exponential and linear phases, respectively. For the am mutant we found 0.14 and 0.12 to 0.13 growing points per chromosome equivalent of template DNA during the exponential and linear phases, respectively. The apparent lower incidence of growing points in the am mutant infections suggests that the mutant may be defective in the initiation of growing points.     

Characterization of catalytic centre mutants of macrophage migration inhibitory factor (MIF) and comparison to Cys81Ser MIF.

Macrophage migration inhibitory factor (MIF) displays both cytokine and enzyme activities, but its molecular mode of action is still unclear. MIF contains three cysteine residues and we showed recently that the conserved Cys57-Ala-Leu-Cys60 (CALC) motif is critical for the oxidoreductase and macrophage-activating activities of MIF. Here we probed further the role of this catalytic centre by expression, purification, and characterization of the cysteine-->serine mutants Cys60Ser, Cys57Ser/Cys60Ser, and Cys81Ser of human MIF and of mutants Ala58Gly/Leu59Pro and Ala58Gly/Leu59His, containing a thioredoxin (Trx)-like and protein disulphide isomerase (PDI)-like dipeptide, respectively. The catalytic centre mutants formed inclusion bodies and the resultant mutant proteins Cys57Ser/Cys60Ser, Ala58Gly/Leu59Pro, and Als58Gly/Leu59His were only soluble in organic solvent or 6 m GdmHCl when reconstituted at concentrations above 1 microgram.mL-1. This made it necessary to devise new purification methods. By contrast, mutant Cys81Ser was soluble. Effects of pH, solvent, and ionic strength conditions on the conformation of the mutants were analysed by far-UV CD spectropolarimetry and mutant stability was examined by denaturant-induced unfolding. The mutants, except for mutant Cys81Ser, showed a close conformational similarity to wild-type (wt) MIF, and stabilization of the mutants was due mainly to acid pH conditions. Intramolecular disulphide bond formation at the CALC region was confirmed by near-UV CD of mutant Cys60Ser. Mutant Cys81Ser was not involved in disulphide bond formation, yet had decreased stability. Analysis in the oxidoreductase and a MIF-specific cytokine assay revealed that only substitution of the active site residues led to inactivation of MIF. Mutant Cys60Ser had no enzyme and markedly reduced cytokine activity, whereas mutant Cys81Ser was active in both tests. The Trx-like variant showed significant enzyme activity but was less active than wtMIF; PDI-like MIF was enzymatically inactive. However, both variants had full cytokine activity. Together with the low but nonzero cytokine activity of mutant Cys60Ser, this indicated that the cytokine activity of MIF may not be tightly regulated by redox effects or that a distinguishable receptor mechanism exists. This study provides evidence for a role of the CALC motif in the oxidoreductase and cytokine activities of MIF, and suggests that Cys81 could mediate conformational effects. Availability and characterization of the mutants should greatly aid in the further elucidation of the mechanism of action of the unusual cytokine MIF.     

Effect of point mutations in the N terminus of the lentivirus lytic peptide-1 sequence of human immunodeficiency virus type 1 transmembrane protein gp41 on Env stability

To understand the role of the lentivirus lytic peptide-1 region of the human immunodeficiency virus type 1 transmembrane glycoprotein (gp) 41 in viral infection, we examined the effects on virus replication of single amino acid deletions spanning this region in an infectious provirus of the HXB2 strain. Among the mutants analyzed, only the deletion of one of the two adjacent valine residues located at positions 832 and 833 (termed the Delta 833 mutant for simplicity) greatly reduced the steady-state, cell-associated levels of the Env precursor and gp120, as opposed to the wild-type virus. The altered Env phenotype resulted in severely impaired virus infectivity and gp120 incorporation into this mutant virion. Analyses of additional mutants with deletions at Ile-830, Ala-836, and Ile-840 demonstrated that the Delta 830 mutant exhibited the most significant inhibitory effect on Env steady-state expression. These results indicate that the N terminus of the lentivirus lytic peptide-1 region is critical for Env steady-state expression. Among the mutant viruses encoding Env proteins in which residues Val-832 and Val-833 were individually substituted by nonconserved amino acids Ala, Ser, or Pro, which were expected to disrupt the alpha-helical structure in the increasingly severe manner of Pro > Ser > Ala, only the 833P mutant exhibited significantly reduced steady-state Env expression. Pulse labeling and pulse-chase studies demonstrated that the Delta 830, Delta 833, and 833P mutants of Env proteins degraded more rapidly in a time-dependent manner after biosynthesis than did the wild-type Env. The results indicate that residue 830 and 833 mutations are likely to induce a conformational change in Env that targets the mutant protein for cellular degradation. Our study has implications about the structural determinants located at the N terminus of the lentivirus lytic peptide-1 sequence of gp41 that affect the fate of Env in virus-infected cells.     

Functional homologs of cyanovirin-N amenable to mass production in prokaryotic and eukaryotic hosts

Cyanovirin-N (CV-N) is under development as a topical (vaginal or rectal) microbicide to prevent sexual transmission of human immunodeficiency virus (HIV), and an economically feasible means for very large-scale production of the protein is an urgent priority. We observed that N-glycosylation of CV-N in yeast eliminated the anti-HIV activity, and that dimeric forms and aggregates of CV-N occurred under certain conditions, potentially complicating the efficient, large-scale manufacture of pure monomeric CV-N. We therefore expressed and tested CV-N homologs in which the glycosylation-susceptible Asn residue at position 30 was replaced with Ala, Gln, or Val, and/or the Pro at position 51 was replaced by Gly to eliminate potential conformational heterogeneity. All homologs exhibited anti-HIV activity comparable to wild-type CV-N, and the Pro51Gly homologs were significantly more stable proteins. These glycosylation-resistant, functional cyanovirins should be amenable to large-scale production either in bacteria or in eukaryotic hosts.     

Isolation of a Bacillus stearothermophilus mutant exhibiting increased thermostability in its restriction endonuclease.

A procedure was developed for the selection of spontaneous mutants of Bacillus stearothermophilus NUB31 that are more efficient than the wild type in the restriction of phage at elevated temperatures. Inactivation studies revealed that two mutants contained a more thermostable restriction enzyme and one mutant contained three times more enzyme than the wild type. The restriction endonucleases from the wild type and one of the mutants were purified to apparent homogeneity. The mutant enzyme was more thermostable than the wild-type enzyme. The subunit molecular weight, amino acid composition, N-terminal and C-terminal amino acid residues, tryptic peptide map, and catalytic properties of the two enzymes were determined. The two enzymes have similar catalytic properties, but the molecular size of the mutant enzyme is approximately 6 to 7 kilodaltons larger than that of the wild-type enzyme. The mutant enzyme contains 54 additional amino acid residues, of which 26 to 28 are aspartate/asparagine, 8 to 15 are glutamate/glutamine, and 8 to 9 are tyrosine residues. The two enzymes contained similar amounts of the other amino acids, identical N-terminal residues, and different C-terminal residues. Tryptic peptide analyses revealed a high degree of homology between the two enzymes. The increased thermostability observed in the mutant enzyme appears to have been achieved by a mutation that resulted in the addition of amino acid residues to the wild-type enzyme. A number of mechanisms are discussed that could account for the observed difference between the mutant and wild-type enzymes.     

In vitro evolution of a polyhydroxybutyrate synthase by intragenic suppression-type mutagenesis

In vitro evolution was applied to obtain highly active mutants of Ralstonia eutropha polyester synthase (PhbC(Re)), which is a key enzyme catalyzing the formation of polyhydroxybutyrate (PHB) from (R)-3-hydroxybutyryl-CoA (3HB-CoA). To search for beneficial mutations for activity improvement of this enzyme, we have conducted multi-step mutations, including activity loss and intragenic suppression-type activity reversion. Among 259 revertants, triple mutant E11S12 was obtained as the most active one via PCR-mediated secondary mutagenesis from mutant E11 with a single mutation (Ser to Pro at position 80), which exhibited reduced activity (as low as 27% of the wild-type level) but higher thermostability compared to the wild-type enzyme. Mutant E11S12 exhibited up to 79% of the wild-type enzyme activity. Mutation separation of E11S12 revealed that the replacement of Phe by Ser at position 420 (F420S), located in a highly conserved alpha/beta hydrolase fold region, of the E11S12 mutant contributes to the improvement of the enzyme activity. A purified sample of the genetically engineered mutant, termed E11S12-1, with the F420S mutation alone was found to exhibit a 2.4-fold increase in specific activity toward 3HB-CoA, compared to the wild-type.     

p53 mutants without a functional tetramerisation domain are not oncogenic

p53 is altered in about 50 % of cancers. Most of the p53 mutants have lost the wild-type tumour suppressor activity but show oncogenic properties. The majority of the p53 alterations are missense mutations of residues located in its DNA binding domain (DBD). Only a few mutations concern residues in its tetramerisation domain (TD). However, the study of mutant proteins identified in tumors that do not form tetramers has shown that they have lost the wild-type activity like most of the p53 DBD mutants. Here, we show that two of such mutant proteins, Arg342Pro and Leu344Pro are not dominant negative and do not stimulate the expression of a reporter gene under the control of the multi-drug resistance gene-1 (MDR-1). This suggests that to be oncogenic, p53 mutants need to form tetramers. Accordingly, the dominant negative effect and the ability of a tetrameric mutant protein, Asp281Gly, to stimulate the MDR-1 promoter are abolished when its TD is rendered non-functional by the mutation of leucine 344 to a proline residue. These results suggest that mutations in the TD, are less selected in tumors than mutations in the DBD because they do not lead to oncogenic proteins.     

The rate and structural consequences of proline cis-trans isomerization in calbindin D9k: NMR studies of the minor (cis-Pro43) isoform and the Pro43Gly mutant

The EF-hand calcium-binding protein, calbindin D9k, exists in solution in the calcium-loaded state, as a 1:3 equilibrium mixture of two isoforms, the result of cis-trans isomerism at the Gly42-Pro43 peptide bond [Chazin et al. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 2195-2198]. Nuclear magnetic resonance (NMR) studies of the minor (cis-Pro43) isoform and the Pro43----Gly mutant are reported here. The rate of cis----trans isomerization at the Pro43 peptide bond in the wild-type protein was determined by line-shape analysis at elevated temperatures, using a sample in which all amino acids, except Ser and Val, were deuterated. The cis----trans rate is calculated to be 0.2 s-1 at 25 degrees C, corresponding to a free energy of activation, delta G, of 77 kJ/mol. The complete sequence-specific 1H NMR assignments of the cis-Pro43 isoform and the Pro43----Gly mutant in the calcium-loaded state have been obtained by using standard methods combined with comparisons to the previously assigned major (trans-Pro43) isoform. This has permitted detailed comparative analysis of 1H NMR chemical shifts, backbone scalar coupling constants, and nuclear Overhauser effects. The minor isoform has a global fold that is identical with that of the major isoform. Structural changes imposed by cis-trans isomerization at Pro43 are highly localized to the linker loop (containing Pro43) that joins the two EF hands. The Pro43----Gly mutant has a global fold that is identical with the wild-type protein, but does not exhibit conformational heterogeneity. Only very limited structural differences are observed between mutant and wild-type protein, and these are also highly localized to the linker loop. The ion-binding properties of the mutant, as determined by 43Ca and 113Cd NMR, are found to be very similar to the wild-type protein. These results provide crucial evidence that justifies the calculation of high-resolution three-dimensional structures of the Pro43Gly mutant, rather than of the conformationally heterogeneous wild-type protein.     

Comparison of CD spectra in the aromatic region on a series of variant proteins substituted at a unique position of tryptophan synthase alpha-subunit

CD spectra in the aromatic region of a series of the mutant alpha-subunits of tryptophan synthase from Escherichia coli, substituted at position 49 buried in the interior of the molecule, were measured at pH 7.0 and 25 degrees C. These measurements were taken to gain information on conformational change produced by single amino acid substitutions. The CD spectra of the mutant proteins, substituted by Tyr or Trp residue in place of Glu residue at position 49, showed more intense positive bands due to one additional Tyr or Trp residue at position 49. The CD spectra of other mutant proteins also differed from that of the wild-type protein, despite the fact that the substituted residues at position 49 were not aromatic. Using the spectrum of the wild-type protein (Glu49) as a standard, the spectra of the other mutants were classified into three major groups. For 10 mutant proteins substituted by Ile, Ala, Leu, Met, Val, Cys, Pro, Ser, His, or Gly, their CD values of bands (due to Tyr residues) decreased in comparison with those of the wild-type protein. The mutant protein substituted by Phe also belonged to this group. These substituted amino acid residues are more hydrophobic than the original residue, Glu. In the second group, three mutant proteins were substituted by Lys, Gln, or Asn, and the CD values of tyrosyl bands increased compared to those of the wild-type proteins. These residues are polar. In the third group, the CD values of tyrosyl bands of two mutant proteins substituted by Asp or Thr were similar to those of the wild-type protein, except for one band at 276.5 nm. These results suggested that the changes in the CD spectra for the mutant proteins were affected by the hydrophobicity of the residues at position 49.     

Isolation and characterization of unusual gin mutants.

Site-specific inversion of the G segment in phage Mu DNA is promoted by two proteins, the DNA invertase Gin and the host factor FIS. Recombination occurs if the recombination sites (IR) are arranged as inverted repeats and a recombinational enhancer sequence is present in cis. Intermolecular reactions as well as deletions between direct repeats of the IRs rarely occur. Making use of a fis- mutant of Escherichia coli we have devised a scheme to isolate gin mutants that have a FIS independent phenotype. This mutant phenotype is caused by single amino acid changes at five different positions of gin. The mutant proteins display a whole set of new properties in vivo: they promote inversions, deletions and intermolecular recombination in an enhancer- and FIS-independent manner. The mutants differ in recombination activity. The most active mutant protein was analysed in vitro. The loss of site orientation specificity was accompanied with the ability to recombine even linear substrates. We discuss these results in connection with the role of the enhancer and FIS protein in the wild-type situation.     

Characterization of two mutant lactose repressor proteins containing single tryptophans

Two mutant lactose repressors, each containing a single tryptophan, were generated by site-specific mutagenesis. Tyrosine was substituted for tryptophan to be analogous to amber suppression mutants reported previously (Sommer, H., Lu, P., and Miller, J. H. (1976) J. Biol. Chem. 251, 3774-3779). Unlike the amber suppression mutants, plasmids containing the mutant sequences produce large quantities of stable, easily isolable protein. The binding properties of the site-specific mutant repressors (W201Y, W220Y) differ from those reported for the corresponding suppression mutants (A201, A220). Whereas minimal effects on operator dissociation rate from lambda plac DNA were noted for the suppression mutants, purified W201Y and W220Y proteins exhibit 10- and 5-fold reduced affinity for a 40-base pair operator, respectively, compared with wild-type. Inducer binding of the A201 and W201Y mutants was similar to that for wild-type repressor, but the inducer affinity of W220Y was approximately 2-fold lower than A220 (approximately 30-fold lower than wild-type). Fluorescence spectra and iodide quenching of the mutant proteins were similar to the suppression mutants, but the absorption coefficient differed significantly from the values reported previously. Acrylamide and iodide quenching results indicate that Trp201 is relatively buried whereas Trp220 is exposed to solvent; inducer binding reduces quenching of Trp220 significantly. CD spectra indicate that the mutant proteins have secondary structural features similar to those of wild-type. Inducer UV difference spectra showed that the major features reported for the wild-type isopropyl beta-D-thiogalactopyranoside difference spectrum were attributable to both tryptophans. In the presence of melibiose, a new minimum appeared in the difference spectra of wild-type and W201Y which was not evident when these proteins bound isopropyl beta-D-thiogalactopyranoside. It is possible that this new feature results from Trp220 involvement in a direct contact with the second sugar in disaccharide inducer molecules such as melibiose and 1,6-allolactose.     

Isolation and characterization of a bacteriophage specific for the lipopolysaccharide of rough derivatives of Pseudomonas aeruginosa strain PAO

A lipopolysaccharide (LPS)-defective (rough) mutant of Pseudomonas aeruginosa PAO was isolated by selection for resistance to the LPS-specific phage E79. The LPS of this mutant, AK-1012, lacked the O-antigenic side chain-specific amino sugar fucosamine as well as the core-specific sugars glucose and rhamnose. Using this strain, we isolated and characterized a phage, phi PLS27, which is specifically inactivated upon incubation with LPS extracted from rough mutants of P. aeruginosa PAO. phi PLS27 was found to be a Bradley type C phage and was very similar to coliphage T7 in a number of properties, including size, buoyant density, mass, and the number of structural proteins.     

Structure of a monomeric mutant of the HIV-1 capsid protein

The capsid protein (CA) of HIV-1 plays a significant role in the assembly of the immature virion and is the critical building block of its mature capsid. Thus, there has been significant interest in the CA protein as a target in the design of inhibitors of early and late stage events in the HIV-1 replication cycle. However, because of its inherent flexibility from the interdomain linker and the monomer-dimer equilibrium in solution, the HIV-1 wild-type CA monomer has defied structural determinations by X-ray crystallography and nuclear magnetic resonance spectroscopy. Here we report the detailed solution structure of full-length HIV-1 CA using a monomeric mutant that, though noninfective, preserves many of the critical properties of the wild-type protein. The structure shows independently folded N-terminal (NTD) and C-terminal domains (CTD) joined by a flexible linker. The CTD shows some differences from that of the dimeric wild-type CTD structures. This study provides insights into the molecular mechanism of the wild-type CA dimerization critical for capsid assembly. The monomeric mutant allows investigation of interactions of CA with human cellular proteins exploited by HIV-1, directly in solution without the complications associated with the monomer-dimer equilibrium of the wild-type protein. This structure also permits the design of inhibitors directed at a novel target, viz., interdomain flexibility, as well as inhibitors that target multiple interdomain interactions critical for assembly and interactions of CA with host cellular proteins that play significant roles within the replication cycle of HIV-1.