Capsid size determination in the P2-P4 bacteriophage system: suppression of sir mutations in P2's capsid gene N by supersid mutations in P4's external scaffold gene sid.

The sid gene of the P2-dependent phage P4 provides an external scaffold so P2 N gene encoded protomers assemble as T = 4 capsids rather than as P2's T = 7 capsids. Mutations (sir) in the middle of N interfere with Sid's function. We describe a new P4 mutant class, nms ("supersid") mutations, which direct also P2 sir to provide small capsids. Three different nms mutations were located near the sid end, commingled with sid(-) mutations. Suppression of sir by nms is not allele-specific. Our results favor this interpretation of capsid size control: (i) sir mutations reduce pN protomer flexibility and thereby interfere with the generation of T = 4 compatible hexons; (ii) the C-termini of Sid molecules link up when forming the scaffold; nms mutations strengthen these Sid-Sid contacts and thus allow the scaffold to force even sir-type protomers to form T = 4 compatible hexons. Some related findings concern suppression of N ts mutations by P4.

In vitro assembly of bacteriophage P4 procapsids from purified capsid and scaffolding proteins.

Bacteriophage P4 is a satellite virus of bacteriophage P2, which has acquired the ability to utilize the structural gene products of P2 to assemble its own capsid. The normal P2 capsid has a T = 7 icosahedral structure comprised of the gpN-derived capsid protein, whereas the capsid produced under the control of P4 has a smaller, T = 4 structure. The protein responsible for this size determination is the P4-coded gene product Sid, which forms an external scaffold on the P4 procapsid. Using an in vitro assembly system, we show that gpN and Sid can coassemble into procapsid-like particles, indistinguishable from those produced in vivo, in the absence of any other gene products. The fidelity of the assembly reaction is enhanced by the inclusion of PEG and has a pH optimum between 8.0 and 8.5. Analysis of the assembly properties of truncated versions of Sid and gpN suggests that the amino-terminal part of Sid is involved in gpN binding, while the carboxyl-terminal part forms trimeric Sid-Sid interactions, and that the first 31 amino acids of gpN are required for binding to Sid as well as for size determination.

RNA aptamers to S-adenosylhomocysteine: kinetic properties, divalent cation dependency, and comparison with anti-S-adenosylhomocysteine antibody.

To explore the potential of RNA aptamers as small-molecule discriminating devices, we have characterized the properties of aptamers selected from a library of approximately 10(14) variants through their interaction with S-adenosylhomocysteine (SAH, AdoHcy). Competition studies with SAH and azaSAM analogues revealed that the Hoogsteen face of adenine is the main contributor to binding, whereas specificity for SAH is conferred by a secondary contact point at or near the sulfur/thioether of homocysteine (Hcy). Binding specificities were determined by both affinity chromatography and a novel method designed for the biosensor. The kinetic properties of individual aptamers, including the "classic" ATP aptamer that also emerged in our selection, were studied by biosensor analysis. Association rates were slow, but the complexes were stable, suggesting micro- to submicromolar affinities. A solution affinity of approximately 0.1 microM was found for the strongest binding variant under the conditions used for selection (5 mM Mg(2+)). Systematic studies of the effect of Mg(2+) and Mn(2+) on binding, however, revealed that the affinity of the aptamers could be substantially improved, and at optimized conditions of Mn(2+) the affinity of one of the aptamers approached that of an anti-SAH antibody with similar/identical binding specificity. Comparisons with the MAb suggest that the on rate is the limiting factor for high-affinity binding by these aptamers, and comparison with a truncated aptamer shows that shortening of RNA constructs may alter binding kinetics as well as sensitivity to ions.

Modeling the occurrence of cardiac arrest as a poisson process.

STUDY OBJECTIVE: A statistical model for the occurrence of cardiac arrest has not been described in the literature. Independent events occurring along the time axis may constitute a Poisson process, described by the Poisson and exponential probability distributions. This statistical model defines the probability distribution of events occurring within time intervals and enables construction of confidence intervals for the mean rate. Moreover, the probability that 2 or more events will occur close in time can be estimated from knowledge of the mean rate. We investigated whether the occurrence of cardiac arrests constitutes a Poisson process. METHODS: Time and date for cardiac arrests requiring CPR out of hospital (county population, 155,000) or in hospital (850 beds) during 5 years were analyzed. Goodness of fit was assessed by comparing the observed weekly counts of cardiac arrests and the observed time intervals between such events with the values predicted from the model. RESULTS: The Poisson parameter estimates (mean weekly rates) for out-of-hospital and in-hospital cardiac arrest were 2.02 and 1.09 events per week, respectively. There was close agreement between observed and predicted values, indicating an adequate model fit. CONCLUSION: Occurrence of cardiac arrest along the time axis constitutes a Poisson process and may be adequately modeled by the Poisson and exponential distributions. The model provides information about the nature of these events and allows for probability calculations based on the mean rate of events. Examples of such calculations are given.

Bacteriophage P2 and P4 morphogenesis: structure and function of the connector.

The connector, the structure located between the bacteriophage capsid and tail, is interesting from several points of view. The connector is in many cases involved in the initiation of the capsid assembly process, functions as a gate for DNA transport in and out of the capsid, and is, as implied by the name, the structure connecting a tail to the capsid. Occupying a position on a 5-fold axis in the capsid and connected to a coaxial 6-fold tail, it mediates a symmetry mismatch between the two. To understand how the connector is capable of all these interactions its structure needs to be worked out. We have focused on the bacteriophage P2/P4 connector, and here we report an image reconstruction based on 2D crystalline layers of connector protein expressed from a plasmid in the absence of other phage proteins. The overall design of the connector complies well with that of other phage connectors, being a toroid structure having a conspicuous central channel. Our data suggests a 12-fold symmetry, i.e., 12 protrusions emerge from the more compact central part of the structure. However, rotational analysis of single particles suggests that there are both 12- and 13-mers present in the crude sample. The connectors used in this image reconstruction work differ from connectors in virions by having retained the amino-terminal 26 amino acids normally cleaved off during the morphogenetic process. We have used different late gene mutants to demonstrate that this processing occurs during DNA packaging, since only mutants in gene P, coding for the large terminase subunit, accumulate uncleaved connector protein. The suggestion that the cleavage might be intimately involved in the DNA packaging process is substantiated by the fact that the fragment cleaved off is highly basic and is homologous to known DNA binding sequences.

Photoimmunodetection: a nonradioactive labeling and detection method for DNA.

We describe a simple detection system for DNA based on antibody detection of UV-induced photoproducts. It includes a convenient and inexpensive labeling procedure, which is completed in 5-10 min. The only equipment required is a UV source such as an ordinary transilluminator or a DNA crosslinker. Using a monoclonal antibody specific for thymine dimers, coupled to horseradish peroxidase, we are able to detect subpicogram amounts of UV-irradiated DNA directly, and approximately 10 pg homologues DNA indirectly by hybridization with an irradiated probe.

Identification and characterisation of C1q-binding phage displayed peptides.

Five phage displayed peptide libraries were screened for binders to C1q, the recognition subunit of the classical complement pathway. Two rounds of panning resulted in the isolation and characterisation of several different phage displayed C1q-binding peptides from all five libraries. Two groups of the characterised peptides show sequence similarity with part of the metal ion dependent adhesion site (MIDAS) of integrin A-domains, and the site 187LRNPCPNKEKECQPPF of CD18 (integrin beta2), respectively. These results support binding of complement receptor 3 (CR3, CD11b/CD18, Mac1) to C1q and further suggest C1q binding sites in CR3. We also discuss sequence matches between the characterised peptides and proteins known to interact with C1q, as well as other proteins listed in the SwissProt databank. These findings are of interest for the study of the complement system and may lead to the development of peptides, fusion products or peptido-mimetics with C1q modulating potential.

Adhesive peptides selected by phage display: characterization, applications and similarities with fibrinogen.

Phase clones with affinity for polystyrene/polyurethane magnetic particles were isolated from a 10-men peptide display library. Sequence analysis revealed that 40 out of 80 clones contained the consensus WXXWXXXW. Some of the selected phages showed high surface activity and adsorbed to plastic surfaces even in the presence of blocking agents or surfactants. Covalent attachment of a synthetic peptide (KG), carrying one of the selected sequences to alkaline phosphatase (AP) or bovine serum albumin (BSA) enhanced binding of AP to a wide range of materials and improved the ability of BSA to prevent binding of antibodies and phages to polystyrene. Interestingly, the WXXW/XXXW motif occurs in the beta- and gamma-chains of the natural "adhesive" protein fibrinogen, and a synthetic peptide carrying the gamma-chain 369-376 sequence turned out to have essentially the same binding properties as the KG peptide. Furthermore, adsorption in different types of polystyrene was similar for AP carrying either the KG or gamma-chain peptide intact fibrinogen and plasmin-generated fragment D1. The latter fragment contains two copies of the WXXWXXXW motif but lacks the alpha-chain: protuberances previously implicated in fibrinogen adsorption. Thus, our study may have revealed a hitherto unknown structural determinant for fibrinogen's adsorptivity, located in the 13-kDa C terminal region of the gamma-chain.

The N-terminal part of bacteriophage P2 capsid protein is essential for postassembly maturation of P2 and P4 capsids.

During capsid assembly of bacteriophage P2 and its satellite phage P4, gpN undergoes proteolytic cleavage with the removal of the first 31 amino acids. The truncated protein gpN* is unable to support formation of viable phages in complementation tests. A c-myc antigenic epitope (EQKLISEEDL) exchanged for eleven amino acids in the amino terminal part of gpN results in both proteolytic processing of gpN::c-myc as well as assembly of P2 and P4 procapsid-like structures, but gpN::c-myc failed, like N*, to support the production of infectious P2 and P4 particles.

Mutational analysis of the bacteriophage P4 capsid-size-determining gene.

Satellite phage P4 (11,624 bp) depends on the morphopoietic genes (capsid, tail) and lysis genes of its helper phage P2 (33.5 kb) for its lytic development. In the morphopoietic process, P4 redirects the assembly pathway of large, P2 size, capsids (diameter = 60 nm) to yield smaller, P4 size, capsids (diameter = 45 nm), 1/3 in volume of that of its helper. The P4-specified capsid size determination is dependent on the function of the 27-kDa gpSid. To study the capsid size-determining function, we carried out a mutational analysis of the P4 sid gene. Use of a P4-derived genome of 29.1 kb (P461), which can be packaged only into large, P2 size, capsids allowed us to select P4 Sid- mutants. By DNA sequencing we characterized 25 P4 Sid- mutants, of which 10 contain base pair substitutions and 15 contain deletions. Both types of mutations are clustered in separate locations within the sid gene. Our results suggest that the Sid polypeptide contains three distinct functional domains.

Bacteriophage P4 capsid-size determination and its relationship to P2 helper interference.

The sid (size determination) gene product of phage P4 is known to be involved in capsid-size determination. Moreover, the capsid-size determination function interferes with the lytic development of its helper P2, presumably because the helper genome is too large to be packaged into P4-size capsids. In order to study P4-specified helper interference, we cloned the sid gene for expression during phage infection. Even though gpSid restores the capsid-size determination function of a sid defective P4 mutant, we find that gpSid alone is not sufficient to establish full interference of helper P2 phage production. Complete helper interference requires some P4 function in addition to gpSid. Complementation tests show that none of the known P4 genes display this property. We propose that P4 encodes a yet-unidentified function that in concert with gpSid establishes full P2 helper interference at the level of capsid-size determination.

Bacteriophage P2: genes involved in baseplate assembly.

The sequences of two previously defined tail genes, V and J, of the temperate bacteriophage P2, and those of two new essential tail genes, W and I, were determined. Their order is the late gene promoter, VWJI, followed by the tail fiber genes H and G, and a transcription terminator. The V gene product is the small spike at the tip of the tail, and the J gene product lies at the edge of the baseplate. The W gene product may be homologous to the product of gene 25 of T4 phage, which is part of the T4 baseplate. A temperature-sensitive mutation in gene V affects satellite phage P4 production more than it affects the production of P2 helper phage. P4 mutations that partially compensate for this defect of gene V lie in the P4 capsid size determination gene, sid.

The capsid size-determining protein Sid forms an external scaffold on phage P4 procapsids.

Although the phages P2 and P4 build their capsids from the same precursor, the product of the P2 N gene, the two capsids differ in size: P2 builds a 60 nm, T = 7 capsid from 420 subunits, whereas P4 makes a 45 nm, T = 4 capsid from 240 subunits. This difference leads to substantial changes in shell geometry and subunit interactions. Previous results have demonstrated that the P4 sid gene is responsible for the assembly of P4-sized shells. We have used cryo-electron microscopy and image reconstruction to determine the structure of a putative assembly intermediate of P4 capsids, produced in vivo from cloned genes. We demonstrate that Sid forms a P4-specific scaffold with icosahedral symmetry on the outside of the procapsid-like particles. The Sid molecules (60 or 120 copies) form lofty arches that interact with the gpN hexamers on the icosahedral 2-fold axes, and connect as trimers over the 3-fold axes, forming a continuous dodecahedrally shaped outer cage. The gpN shell inside the Sid cage is approximately 40 nm wide, consistent with the previously suggested maturational expansion. The main difference with respect to the mature P4 capsids is found in the hexamers, which appear strongly elongated and more protruding than in the mature shell. These and previous results are discussed in the light of a model for regulation of capsid size.

Peptide presentation by bacteriophage P4.

This article focuses on bacteriophage P4 as a potential peptide display phage by exploring the possibility of using the P4 capsid decoration component, Psu, as a peptide carrier protein. Psu is non-essential for P4 growth but it enhances the stability of the P4 capsid by binding to its exterior. We have constructed a unique SacI cloning site in the beginning of the psu gene. This site changes the third amino acid of Psu from Ser to Leu. This substitution does not destroy the binding of Psu to the P4 capsid. A synthetic oligonucleotide encoding a 10-amino acid peptide whose sequence is part of the human p62c-myc protein, has been inserted into the SacI site. The Psuc-myc shows full capsid binding activity and reacts with monoclonal antibodies directed against the c-myc peptide. These results pave the way for the further development of a peptide display system based on bacteriophage P4.

Bacteriophage P2 and P4 morphogenesis: assembly precedes proteolytic processing of the capsid proteins.

Several of the structural proteins of phage P2 and its satellite P4 undergo proteolytic processing during development of mature phage particles. Here, we report that uncleaved shell protein, gpN, is present in immature capsids of both P2 and P4, showing that assembly precedes processing. This excludes the possibility that processing of gpN is involved in capsid size determination. We also find that N*, the fully processed version of gpN, produced from a plasmid, can assemble into both P2- and P4-sized particles, implying that the amino-terminal end of gpN is not required for assembly initiation nor for the formation of a T = 4 shell. As may be expected for a scaffolding protein, we find that gpO coexists with gpN in immature P2, as well as P4, capsids. This result supports the conclusion that gpO is required for both phages and strongly suggests that the O derivative, h7 (found in mature capsids), results from proteolytic cleavage after gpN/gpO coassembly.

Bacteriophage P2 and P4 assembly: alternative scaffolding proteins regulate capsid size.

The capsid protein of bacteriophage P2, encoded by the N gene, can assemble into icosahedral capsids of two possible sizes, with diameters of 60 and 45 nm, respectively. Only the larger capsid is used by P2 itself, but the smaller one is exploited by the satellite phage P4. We have analyzed the assembly products of gpN expressed in vivo from a plasmid, i.e., in the absence of any other phage proteins, and find that gpN alone forms closed shells of both sizes, although with poor efficiency. Coexpressing gpN with gpO, the putative P2 scaffolding protein, increases the efficiency of large particle formation. In contrast, introducing the sid gene by P4 infection stimulates the assembly of small particles. Our results suggest that gpO and gpSid act competitively with respect to capsid size determination. Furthermore, we demonstrate that gpN alone undergoes the normal proteolytic maturation steps, implying that gpN processing is either autocatalytic or mediated by a host enzyme.