Ring vortex solitons in nonlocal nonlinear media.

We study the formation and propagation of two-dimensional vortex solitons, i.e. solitons with a phase singularity, in optical materials with a nonlocal focusing nonlinearity. We show that nonlocality stabilizes the dynamics of an otherwise unstable vortex beam. This occurs for either single or higher charge fundamental vortices as well as higher order (multiple ring) vortex solitons. Our results pave the way for experimental observation of stable vortex rings in other nonlocal nonlinear systems including Bose-Einstein condensates with pronounced long-range interparticle interaction.

An outbreak of Serratia marcescens infections related to contaminated chlorhexidine.

An outbreak of Serratia marcescens infections occurred in a university tertiary-care hospital. Alcohol-free chlorhexidine solutions were contaminated with S marcescens. The majority of patient and chlorhexidine strains had similar pulsed field-gel electrophoresis banding patterns. Chlorhexidine was recalled, and the rate of S marcescens isolation returned to baseline. Chlorhexidine without alcohol should not be used as an antiseptic.

Protein interaction domains of the measles virus nucleocapsid protein (NP).

The currently accepted model for measles virus (MV) transcription and replication assumes the nucleocapsid (NP) protein to possess the ability to bind to RNA, to other NP molecules, and to the phosphoprotein (P) during ribonucleocapsid (RNP) assembly, as well as to the matrix protein (M) during virion assembly. We have cloned the MV NP open reading frame and have expressed the protein in bacteria as a fusion with glutathione-S-transferase (GST). Affinity purified GST-NP fusion protein has been used as a probe to examine the interaction of NP with [35S] methionine labeled proteins from MV-infected cells. We have demonstrated definite and specific interactions between NP and itself and between NP and P, but have been unable to demonstrate any interaction between NP and M. We have been able to provide independent confirmation of this pattern of interaction using the yeast two-hybrid assay. We have, in addition, been able to map the domains of NP involved in these interactions by assays using sets of amino- and carboxy-terminal deletion mutants of GST-NP. The NP-NP interaction domain was found to reside in the highly conserved middle and amino-terminal domains of the protein. The hyper-variable carboxy-terminus and the conserved middle domain appear to constitute separate and independent sites for the binding of P to NP. The significance of these findings in regard to MV transcription and replication is discussed.

Ribosomal frameshifting during translation of measles virus P protein mRNA is capable of directing synthesis of a unique protein.

Members of the Paramyxoviridae family utilize a variety of different strategies to increase coding capacity within their P cistrons. Translation initiation at alternative 5'-proximal AUG codons is used by measles virus (MV) to express the virus-specific P and C proteins from overlapping reading frames on their mRNAs. Additional species of mRNAs are transcribed from the MV P cistron by the insertion of extra nontemplated G residues at a specific site within the P transcript. Addition of only a single nontemplated G residue results in the expression of the V protein, which contains a unique carboxyl terminus. We have used an Escherichia coli system to express MV P cistron-related mRNAs and proteins. We have found that ribosomal frameshifting on the MV P protein mRNA is capable of generating a previously unrecognized P cistron-encoded protein that we have designated R. Some ribosomes which have initiated translation of the P protein mRNA use the sequence TCC CCG AG (24 nucleotides upstream of the V protein stop codon) to slip into the -1 reading frame, thus translating the sequence as TC CCC GAG. The resulting R protein terminates five codons downstream of the frameshift site at the V protein stop codon. We have gone on to use a chloramphenicol acetyltransferase reporter system to demonstrate that this MV-specific sequence is capable of directing frameshifting during in vivo translation in eukaryotic cells. Analysis of immunoprecipitated proteins from MV-infected cells by two-dimensional gel electrophoresis allowed detection of a protein species consistent with R protein in MV-infected cells. Quantitation of this protein species allowed a rough estimation of frameshift frequency of approximately 1.8%. Significant stimulation of ribosomal frameshift frequency at this locus of the MV P mRNA was mediated by a downstream stimulator element which, although not yet fully defined, appeared to be neither a conventional stem-loop nor an RNA pseudoknot structure.

Protein interactions entered into by the measles virus P, V, and C proteins.

Measles virus (MV) expresses at least 3 proteins from the phosphoprotein (P) cistron. Alternative translation initiation directs synthesis of the C protein from the +1 reading frame, while so-called RNA editing generates a second population of mRNAs which express the V protein from the -1 reading frame which lies within and overlaps the larger P reading frame. While the P protein has been demonstrated to be an essential cofactor for the L protein in the formation of active transcriptase complexes, the functions of the V and C proteins remain unknown. In order to investigate these functions, we have expressed the MV P, V and C proteins as GST fusions in E. coli for affinity purification and use in an in vitro binding assay with other viral and cellular proteins. The P protein was found to interact with L, NP, and with itself. These interactions were mapped to the carboxy-terminal half of the protein which is absent in the V protein. In contrast, both the V and C proteins failed to interact with any other viral proteins, but were each found to interact specifically with one or more cellular proteins. Appropriate aspects of these results were confirmed in vivo using the yeast two-hybrid system. These observations suggest that the V and C proteins may be involved in modulation of the host cellular environment within MV-infected cells. Such activity would be distinct from their previously proposed role in the possible down-regulation of virus-specific RNA transcription and replication.

The carboxy-terminal 18 amino acids of the measles virus hemagglutinin are essential for its biological function.

The hemagglutinin (HA) glycoprotein encoded by measles virus (MV) is a type II integral membrane protein that is expressed at the infected cell surface. Genes encoding wild-type MV HA as well as two mutant HA proteins shortened at their carboxy-termini by either 18 (HA delta 18O) or 223 (HA delta 223) amino acids were constructed and studied in a transient expression system in COS cells. Under nonreducing conditions, assembly of HA delta 18 into homodimers was diminished while HA delta 223 remained in a monomeric form. Hemadsorption assays revealed that neither mutant was functional at the cell surface. These studies show that the carboxy-terminal ectodomain of the HA protein is essential to its proper folding and assembly into homodimers while its carboxy-terminal 18 amino acids are essential for the hemadsorption (receptor-binding) function of the protein.

Characterization of a cleavage mutant of the measles virus fusion protein defective in syncytium formation.

Membrane fusion caused by measles virus (MV) is a function of the fusion (F) protein. This process is essential for penetration into the host cell and subsequent initiation of the virus replicative cycle. The biological activity of the MV F protein is generated by endoproteolytic cleavage of a precursor protein (F0) into a large F1 subunit and a smaller F2 subunit held together by disulfide bonds. The cleavage site consists of a cluster of five basic amino acids (amino acids 108 to 112) within the predicted primary structure of the F protein. To investigate the role of the arginine residue at the carboxy terminus of the F2 subunit (arginine 112), site-directed mutagenesis was used to construct a cleavage mutant of the MV F protein in which this arginine residue was changed to a leucine residue. The mutated F gene, encoding four out of the five basic amino acids at the cleavage site, was inserted into the genome of vaccinia virus. The resulting recombinant virus was used to study expression of the mutant F protein in infected cells. Analysis of the Leu-112 mutant protein made in infected cells demonstrated that this single-amino-acid substitution resulted in a reduced rate of transport of the mutant protein to the cell surface, despite its efficient cleavage to yield F1 and F2 subunits. However, the electrophoretic mobilities of the Leu-112 polypeptides suggested that the protein was cleaved incorrectly. This aberrant cleavage appears to have abolished the ability of the F protein to cause syncytium formation. The data indicate that the arginine 112 residue is critical for the correct proteolytic cleavage that is required for the membrane fusion activity of the MV F protein.

Functional analysis of N-linked glycosylation mutants of the measles virus fusion protein synthesized by recombinant vaccinia virus vectors.

The role of N-linked glycosylation in the biological activity of the measles virus (MV) fusion (F) protein was analyzed by expressing glycosylation mutants with recombinant vaccinia virus vectors. There are three potential N-linked glycosylation sites located on the F2 subunit polypeptide of MV F, at asparagine residues 29, 61, and 67. Each of the three potential glycosylation sites was mutated separately as well as in combination with the other sites. Expression of mutant proteins in mammalian cells showed that all three sites are used for the addition of N-linked oligosaccharides. Cell surface expression of mutant proteins was reduced by 50% relative to the wild-type level when glycosylation at either Asn-29 or Asn-61 was abolished. Despite the similar levels of cell surface expression, the Asn-29 and Asn-61 mutant proteins had different biological activities. While the Asn-61 mutant was capable of inducing syncytium formation, the Asn-29 mutant protein did not exhibit any significant cell fusion activity. Inactivation of the Asn-67 glycosylation site also reduced cell surface transport of mutant protein but had little effect on its ability to cause cell fusion. However, when the Asn-67 mutation was combined with mutations at either of the other two sites, cleavage-dependent activation, cell surface expression, and cell fusion activity were completely abolished. Our data show that the loss of N-linked oligosaccharides markedly impaired the proteolytic cleavage, stability, and biological activity of the MV F protein. The oligosaccharide side chains in MV F are thus essential for optimum conformation of the extracellular F2 subunit that is presumed to bind cellular membranes.

Measles virus V protein binds zinc.

Measles virus transcription generates multiple P/C gene-specific mRNAs by a process which has been termed editing. In one of these mRNAs, the cotranscriptional addition of a single nontemplated G residue allows translational access to the V protein reading frame. The protein translated from this mRNA has been called V and consists of 231 amino-terminal amino acid residues identical to those at the amino terminus of the P protein followed by a unique carboxy-terminal domain consisting of 68 amino acids from the V reading frame. The most striking feature of this unique domain is the presence within it of seven cysteine residues whose presence and position are highly conserved among different paramyxoviruses. The number and arrangement of these cysteine residues is suggestive of a zinc finger protein. We have used a zinc binding protocol to determine that V protein does indeed bind zinc, have further demonstrated that this metal binding activity is highly specific to zinc, and have shown that it is the unique carboxy-terminal domain of the V protein that is responsible for zinc binding.

Disseminated infection after intravesical BCG immunotherapy. Detection of organisms in pulmonary tissue.

A 57-year-old man undergoing intravesical immunotherapy with BCG for transitional cell bladder carcinoma presented with dyspnea, fever, hypoxemia, and a diffuse micronodular pattern on chest radiograph. Transbronchial biopsy specimen revealed widespread noncaseating granulomas, and acid-fast bacilli were identified in sputum as well as in the biopsy tissue. The patient's condition responded promptly to antituberculous antibiotics given in conjunction with corticosteroids. Although no growth was evident on TB culture of the specimens, the presence of organisms indicates a probable infectious cause of the pulmonary disease process.

The use of an enzyme single fiber reactor in the study of leukemic cell proliferation: in vitro experiments and computer simulation.

This paper describes the use of an immobilized enzyme reactor in the study of the in vitro effects of lysine deprivation on leukemic blood. L-lysine alpha-oxidase is immobilized in a single hollow fiber reactor to remove lysine from the blood of sheep infected by BLV. The treatment relies on the higher sensitivity of leukemic cells to nutrient depletion than that of normal cells. A population balance model is used to describe the changes in the leukocyte proliferative capacity after treatment. Additionally, preliminary data from in vitro tests with human blood demonstrate the potential of L-lysine alpha-oxidase and the enzymatic reactor in treating leukemia.

Nonreplicating viral vectors as potential vaccines: recombinant canarypox virus expressing measles virus fusion (F) and hemagglutinin (HA) glycoproteins.

The development of canarypox virus (CPV) recombinants expressing the hemagglutinin (HA) and fusion (F) glycoproteins of measles virus (MV) is described. Inoculation of the CPV-MV recombinants into avian or nonavian tissue culture substrates led to the expression of authentic MVF and MVHA as determined by radioimmunoprecipitation and surface immunofluorescence. In contrast to avian-derived tissue culture, no productive replication of the CPV recombinant was evident in tissue culture cells derived from nonavian origin. On inoculation of dogs, a species restricted for avipoxvirus replication, the recombinants elicited a protective immune response against a lethal canine distemper virus (CDV) challenge. The level of MV neutralizing antibodies and the level of protection induced against CDV challenge achieved by the host-restricted CPV vector were equivalent to that obtained by vaccinia virus vectors expressing the same MV antigens.

Group C streptococcal endocarditis presenting as clinical meningitis: Report of a case and review of the literature.

Lancefield group C streptococci are known to be pathogenic in a number of animal species, but cause human disease much less commonly than do streptococci of scrogroups A or B. Reported cases of bacteremic infection, pneumonia or meningitis in humans have been very severe with a grave prognosis. The authors describe a patient who presented with classic clinical and laboratory evidence of bacterial meningitis which proved to be a complication of endocarditis caused by a group C streptococcus. This is the first reported case in which meningitis was the presenting manifestation of group C streptococcal endocarditis and is only the second case in which group C streptococcal meningitis and endocarditis have been associated in the same patient. A total of 13 cases of group C streptococcal meningitis have now been reported in the medical literature. Five of these patients died, and four others recovered only to be left with neurological sequelae. The current case confirms the seriousness of group C streptococcal infections in humans. Such infections are associated with a poor prognosis despite apparently adequate antimicrobial therapy.

The effect of lysine deprivation on leukemic blood.

Studies have shown that specific amino acids are required for optimal growth of leukemic versus normal cells, and it is believed that the depletion of selected amino acids can abrogate tumor growth. We have developed a technique for studying the effect of amino acid deprivation on leukemic cell proliferation. The technique is based on the controlled enzymatic removal of the amino acid from leukemic blood and the subsequent measurement of cell proliferative capacity. The specific system being studied is the removal of lysine from blood using immobilized L-lysineα-oxidase.A reactor has been designed that consists of L-lysineα-oxidase and catalase co-immobilized within the void space of the porous region of asymmetric hollow fiber (ultrafiltration) membranes. Blood from leukemic sheep is currently being treatedin vitro with this reactor. By varying treatment time, the amount of enzyme immobilized, and the blood flow rate, the amount of lysine removed from the blood can be varied and controlled. Preliminary data indicate that 80% depletion of lysine from leukemic blood is enough to cause a significant (25%) decrease in total white cell count as well as a decrease in the proliferative capacity of the leukemic cells.

Vaccinia virus recombinants expressing either the measles virus fusion or hemagglutinin glycoprotein protect dogs against canine distemper virus challenge.

cDNA clones of the genes encoding either the hemagglutinin (HA) or fusion (F) proteins of the Edmonston strain of measles virus (MV) were expressed in vaccinia virus recombinants. Immunofluorescence analysis detected both proteins on the plasma membranes of unfixed cells as well as internally in fixed cells. Immunoprecipitation of metabolically radiolabeled infected-cell extracts by using specific sera demonstrated a 76-kDa HA polypeptide and gene products of 60, 44, and 23 kDa which correspond to a MV F precursor and cleavage products F0, F1, and F2, respectively. Neither recombinant induced cell fusion of Vero cells when inoculated individually, but efficient cell fusion was readily observed upon coinfection of cells with both recombinants. Inoculation of dogs with the vaccinia virus-MV F recombinant (VV-MVF) did not give rise to detectable MV-neutralizing antibody. Inoculation of dogs with the vaccinia virus-MV HA recombinant (VV-MVHA) or coinoculation with both recombinants (VV-MVF and VV-MVHA) induced significant MV-neutralizing titers that were increased following a booster inoculation. Inoculation of dogs with the vaccinia virus recombinants or with MV failed to induce canine distemper virus (CDV)-neutralizing antibodies. Upon challenge with a lethal dose of virulent CDV, signs of infection were observed in dogs inoculated with (VV-MVF). No symptoms of disease were observed in dogs that had been vaccinated with VV-MVHA or with VV-MVHA and VV-MVF and then challenged with CDV. All dogs vaccinated with the recombinant viruses as well as those inoculated with MV or a vaccine strain of CDV survived CDV challenge.

Characterization of V protein in measles virus-infected cells.

An edited mRNA transcribed from the phosphoprotein (P) gene of measles virus (MV) has been predicted to encode a cysteine-rich protein designated V. This mRNA contains a single additional nontemplated G residue which permits access to an additional protein-coding reading frame. Such an edited P gene-specific mRNA has been detected in MV-infected cells, but no corresponding protein has yet been identified in vivo. We report the use of antisera directed against synthetic peptides corresponding to five different regions of the predicted MV V protein amino acid sequence to analyse MV-specific proteins synthesized in vivo and in vitro. The MV V protein (40 kDa) was detected in MV-infected cells in a diffuse cytoplasmic distribution, a predominant subcellular localization distinct from that of virus nucleocapsids. The protein was found to be phosphorylated and to be maximally synthesized at 16 h postinfection, when MV-specific structural protein synthesis was also maximal. Antiserum directed against a peptide (PV2) corresponding to amino acids 65 to 87 of the V protein amino acid recognized the P protein but not the V protein, indicating that the P and V proteins may be folded differently at or near this region so that the PV2 sequence is in an exposed position at the surface of the P protein but not at the surface of the V protein.

Evaluation of intrinsic immobilized kinetics in hollow fiber reactor systems.

Immobilized cell and enzyme hollow fiber reactors have been developed for a variety of biochemical and biomedical applications. Reported mathematical models for predicting substrate conversion in these reactors have been limited in accuracy because of the use of free-solution kinetic parameters. This paper describes a method for determining the intrinsic kinetics of enzymes immobilized in hollow fiber reactor systems using a mathematical model for diffusion and reaction in porous media and an optimization procedure to fit intrinsic kinetic parameters to experimental data. Two enzymes, a thermophilic beta-galactosidase that exhibits product inhibition and L-lysine alpha-oxidase, were used in the analysis. The intrinsic kinetic parameters show that immobilization enhanced the activity of the beta-galactosidase while decreasing the activity of L-lysine alpha-oxidase. Both immobilized enzymes had higher Km values than did the soluble enzyme, indicating less affinity for the substrate. These results are used to illustrate the significant improvement in the ability to predict substrate conversion in hollow fiber reactors.

The use of a single-fiber reactor for the enzymatic removal of amino acids from solutions.

In this article we describe the use of bench-scale single-fiber dialyzers for the development and testing of an immobilized enzyme reactor for the treatment of leukemia. The treatment is based on the enzymatic removal of specific amino acids from the blood of leukemia patients. L-Lysine alpha-oxidase and catalase were coimmobilized within the void space of the porous region of asymmetric hollow-fiber membranes for the removal of L-lysine from simulated human plasma solutions. Hollow-fiber reactor performance was evaluated using a small single-fiber dialyzer (SFD) consisting of a single fiber encased in a protective glass shell. This small reactor affords ease of use, requires small amounts of chemicals and biochemicals, and gives useful reactor performance data. Single-fiber dialyzers were constructed using polyamide fibers with a molecular weight cutoff of 10,000 (PA10 fibers); these fibers demonstrated the best compatibility with and retention of the enzymes. The SFD performance in removing L-lysine from solution was evaluated under both steady and pulsatile flow operation. Pulsatile flow was tested for two reasons: (1) to enhance the radial mass transfer of lysine within the SFD and (2) to simulate the pulsatile flow of blood in dialysis treatment. The use of pulsatile flow increased lysine conversion by 15% over the steady-flow case. Approximately 40% of the lysine was removed from simulated plasma by the SFD in a 4-h experiment using pulsatile flow in the recycle mode.

Synthesis of the membrane fusion and hemagglutinin proteins of measles virus, using a novel baculovirus vector containing the beta-galactosidase gene.

An improved baculovirus expression vector was developed to expedite screening and facilitate oligonucleotide-directed mutagenesis. This vector contained twin promoters derived from the P10 and polyhedrin genes of Autographica californica nuclear polyhedrosis virus. The P10 promoter directed the synthesis of beta-galactosidase, whereas the polyhedrin promoter controlled the synthesis of foreign gene products. These two genes recombined with wild-type virus genome to yield recombinants which were polyhedrin negative, produced the foreign gene product, and formed blue plaques when beta-galactosidase indicator was present in the agarose overlay. An origin of replication derived from M13 or f1 bacteriophage was also included in the plasmid to permit the synthesis of single-stranded DNA. This template DNA was used to introduce or delete sequences through the process of site-specific mutagenesis. The measles virus virion possesses a membrane envelope which contains two glycoproteins: the hemagglutinin (H) and membrane fusion (F) proteins. The H polypeptide has receptor-binding and hemagglutinating activity, whereas the F protein mediates virus penetration of the host cell, formation of syncytia, and hemolysis of erythrocytes. Genes for these two glycoproteins were inserted into the NheI cloning site of the modified expression vector described above. The vector and purified wild-type viral DNA were introduced into Sf9 insect cells by calcium phosphate precipitation. A mixture of wild-type and recombinant virus was generated and used to infect Sf9 cells, which were subsequently overlaid with agarose. After 3 days, 0.1 to 1% of the plaques became blue in the presence of beta-galactosidase indicator. At least 70% of these blue viral colonies contained the foreign gene of interest as determined by dot blot analysis. Recombinant virus was separated from contaminating wild-type virus through several rounds of plaque purification. Insect cells were then infected with the purified recombinants, and synthesis of H and F proteins were verified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by immunoblot detection and Coomassie blue staining. Glycosylation of the proteins appeared to be impaired somewhat, and the precursor to the F protein was not completely cleaved by the proteases present in insect host cells. On the other hand, both proteins appeared to be active in hemagglutination, hemolysis, and cell fusion assays. Levels of synthesis were in the order of 50 to 150 mg of protein per 10(8) cells.

Expression of bicistronic measles virus P/C mRNA by using hybrid adenoviruses: levels of C protein synthesized in vivo are unaffected by the presence or absence of the upstream P initiator codon.

The measles virus (MV) P/C mRNA is functionally bicistronic. Translation is presumed to initiate at both the first and second 5'-proximal AUG codons, leading, respectively, to synthesis of the P and C polypeptides from different overlapping reading frames. To study the function and differential expression of these polypeptides, we have constructed hybrid human adenoviruses capable of expressing high levels of P and C together or of C alone. Cloned cDNA corresponding to the MV P/C gene was coupled to the adenovirus type 2 (Ad2) major late promoter, most of the Ad2 tripartite leader sequence, and the simian virus 40 3'-end processing signal and then used to replace most of the E1a-E1b region of the Ad5 genome in two hybrid adenoviruses: one (Ad5MV/PC13) which contained both 5'-proximal AUG codons of the P/C mRNA and another (Ad5MV/C3) which retained only the second. The sequence context for the P protein initiator AUG codon in Ad5MV/PC13 was made more favorable (GAGAUGG) than the relatively unfavorable context (CCGAUGG) seen in the native MV P/C mRNA. After infection of 293 cells (which provide complementary E1a-E1b functions), both viruses directed equal amounts of P/C-specific mRNA transcription. Ad5MV/PC13 directed the synthesis of both P and C proteins, while Ad5MV/C3 directed the synthesis of C protein alone. Ad5-expressed P protein was phosphorylated, while C was not. C protein had a similar diffuse cytoplasmic localization in both MV and Ad5-infected cells. Ad5MV/C3 and Ad5MV/PC13 directed equal amounts of C protein expression in 293 cells at a level approximately 15 times greater than that seen in MV-infected cells. Thus the level of C protein expression was unaffected by the presence or absence of an out-of-frame upstream AUG codon in a favorable sequence context. This observation cannot be explained by the scanning model for ribosomal initiation and suggests that ribosomes may be binding directly at an internal mRNA site at or near the initiator AUG codon for the C protein.