Model peptides mimic the structure and function of the N-terminus of the pore-forming toxin sticholysin II

To investigate the role of the N-terminal region in the lytic mechanism of the pore-forming toxin sticholysin II (St II), we studied the conformational and functional properties of peptides encompassing the first 30 residues of the protein. Peptides containing residues 1-30 (P1-30) and 11-30 (P11-30) were synthesized and their conformational properties were examined in aqueous solution as a function of peptide concentration, pH, ionic strength, and addition of the secondary structure-inducing solvent trifluoroethanol (TFE). CD spectra showed that increasing concentration, pH, and ionic strength led to aggregation of P1-30; as a consequence, the peptide acquired beta-sheet conformation. In contrast, P11-30 exhibited practically no conformational changes under the same conditions, remaining essentially structureless. Moreover, this peptide did not undergo aggregation. These differences clearly point to the modulating effect of the first 10 hydrophobic residues on the peptides aggregation and conformational properties. In TFE both the first ten hydrophobic peptides acquired alpha-helical conformation, albeit to a different extent, P11-30 displayed lower alpha-helical content. P1-30 presented a larger fraction of residues in alpha-helical conformation in TFE than that found in St II's crystal structure for that portion of the protein. Since TFE mimics the membrane environment, such increase in helical content could also occur upon toxin binding to membranes and represent a step in the mechanism of pore formation. The peptides conformational properties correlated well with their functional behavior. Thus, P1-30 exhibited much higher hemolytic activity than P11-30. In addition, P11-30 was able to block the toxin's hemolytic activity. The size of pores formed in red blood cells by P1-30 was estimated by measuring the permeability to PEGs of different molecular mass. The pore radius (0.95 +/- 0.01 nm) was very similar to that of the pore formed by the toxin. The results demonstrate that the synthetic peptide P1-30 is a good model of St II conformation and function and emphasize the contribution of the toxin's N-terminal region, and, in particular, the hydrophobic residues 1-10 to pore formation.     

Low resolution structure of the human alpha4 protein (IgBP1) and studies on the stability of alpha4 and of its yeast ortholog Tap42

The yeast Tap42 and mammalian alpha4 proteins belong to a highly conserved family of regulators of the type 2A phosphatases, which participate in the rapamycin-sensitive signaling pathway, connecting nutrient availability to cell growth. The mechanism of regulation involves binding of Tap42 to Sit4 and PPH21/22 in yeast and binding of alpha4 to the catalytic subunits of type 2A-related phosphatases PP2A, PP4 and PP6 in mammals. Both recombinant proteins undergo partial proteolysis, generating stable N-terminal fragments. The full-length proteins and alpha4 C-terminal deletion mutants at amino acids 222 (alpha4Delta222), 236 (alpha4Delta236) and 254 (alpha4Delta254) were expressed in E. coli. alpha4Delta254 undergoes proteolysis, producing a fragment similar to the one generated by full-length alpha4, whereas alpha4Delta222 and alpha4Delta236 are highly stable proteins. alpha4 and Tap42 show alpha-helical circular dichroism spectra, as do their respective N-terminal proteolysis resistant products. The cloned truncated proteins alpha4Delta222 and alpha4Delta236, however, possess a higher content of alpha-helix, indicating that the C-terminal region is less structured, which is consistent with its higher sensitivity to proteolysis. In spite of their higher secondary structure content, alpha4Delta222 and alpha4Delta236 showed thermal unfolding kinetics similar to the full-length alpha4. Based on small angle X-ray scattering (SAXS), the calculated radius of gyration for alpha4 and Tap42 were 41.2 +/- 0.8 A and 42.8 +/- 0.7 A and their maximum dimension approximately 142 A and approximately 147 A, respectively. The radii of gyration for alpha4Delta222 and alpha4Delta236 were 21.6 +/- 0.3 A and 25.7 +/- 0.2 A, respectively. Kratky plots show that all studied proteins show variable degree of compactness. Calculation of model structures based on SAXS data showed that alpha4Delta222 and alpha4Delta236 proteins have globular conformation, whereas alpha4 and Tap42 exhibit elongated shapes.     

Structure-guided identification of novel VEGFR-2 kinase inhibitors via solution phase parallel synthesis

Structural analysis of the essential binding elements of the oxindole-based kinase inhibitor (1) led to the identification of a novel class of heterocyclic-substituted pyrazolones. Knoevenagel condensation of a variety of activated methylene nucleophiles with indole or pyrrole carboxaldehydes provided a focused library of molecules, each containing elements of kinase pharmacophore probe. Initial screening for VEGFR-2 kinase inhibition eliminated several of the probes. Identification of an active pyrazolone motif and further optimization resulted in several highly potent VEGFR-2 inhibitors with cellular efficacy, anti-angiogenic activity ex vivo in rat aortic ring explant cultures, and oral anti-tumor efficacy in nude mice.     

The Multiplicity of Infection of a Plant Virus Varies during Colonization of Its Eukaryotic Host

The multiplicity of infection (MOI), i.e., the number of virus genomes that infect a cell, is a key parameter in virus evolution, as it determines processes such as genetic exchange among genomes, selection intensity on viral genes, epistatic interactions, and the evolution of multipartite viruses. In fact, the MOI level is equivalent to the virus ploidy during genome expression. Nevertheless, there are few experimental estimates of MOI, particularly for viruses with eukaryotic hosts. Here we estimate the MOI of Tobacco mosaic virus (TMV) in its systemic host, Nicotiana benthamiana. The progress of infection of two TMV genotypes, differently tagged with the green or red fluorescent proteins GFP and RFP, was monitored by determining the number of leaf cell protoplasts that showed GFP, RFP, or GFP and RFP fluorescence at different times postinoculation. This approach allowed the quantitative analysis of the kinetics of infection and estimation of the generation time and the number of infection cycles required for leaf colonization. MOI levels were estimated from the frequency of cells infected by only TMV-GFP or TMV-RFP. The MOI was high, but it changed during the infection process, decreasing from an initial level of about 6 to a final one of 1 to 2, with most infection cycles occurring at the higher MOI levels. The decreasing MOI can be explained by mechanisms limiting superinfection and/or by genotype competition within double-infected cells, which was shown to occur in coinfected tobacco protoplasts. To our knowledge, this is the first estimate of MOI during virus colonization of a eukaryotic host.Virus evolution has been a very active area of research in the last few decades, as viruses are both important pathogens of humans, animals, and plants and good models to experimentally test hypotheses on parasite evolution or, more generally, central questions on evolutionary biology (11, 12, 21, 36). Considerable efforts have been devoted to modeling the evolution of viral populations. However, contrasting the theoretical models with reality may be hindered by limited experimental information on important parameters of the virus life cycle. The multiplicity of infection (MOI), i.e., the number of virus particles or genomes that may infect a cell, is a key parameter in many models of virus evolution (5, 6, 14, 15, 37, 38, 39, 52, 53, 57, 61) for which experimental estimates are scant.When a cell is coinfected by different viral genomes, competition may lead to decreased fitness of individual genotypes in comparison with their fitness in single infections (15, 31, 40). Thus, limiting coinfection may result in a selective advantage for viruses (58), which have developed mechanisms to prevent superinfection of previously infected cells (51, 60). On the other hand, infection of a cell by more than one virus genome is a prerequisite for two central phenomena in virus genetics to take place: recombination and complementation of defective mutants. Recombination between viral strains during replication in the same cell and complementation of defective mutants have been extensively documented for viruses infecting prokaryotes, animals, and plants (2, 25, 56), indicating that there must be some degree of coinfection and, hence, that the MOI must be higher than one in at least some infected cells. However, estimates of MOI in the natural hosts of viruses are surprisingly scarce in spite of this parameter''s relevance: values of about 2 to 3 have been reported for different DNA or RNA bacteriophages (26, 41, 51, 58), and a value of 4 to 5 was reported for Autographa californica nuclear polyhedrosis virus infecting larvae of the moth Tricoplusia ni (3), to our knowledge, the only estimate for a virus in its eukaryotic host. We are not aware of estimates reported for viruses infecting mammals or plants, although a MOI of about 3 can be inferred from the number of proviral copies of HIV in spleen cells of infected patients (29). This paucity of data may be due to the technical difficulty of directly measuring MOI, particularly within a eukaryotic host. Genetic approaches may provide valid alternatives for estimating MOI levels (3, 58), and here, the MOI of a plant virus is estimated through the analysis of the relative frequencies of two genotypes during the process of host colonization.Host colonization by plant-infecting viruses has been known for a long time to be a two-step phenomenon. First, colonization proceeds slowly from the initially infected cells to their neighbors by way of the cytoplasmic connections called plasmodesmata, a process known as cell-to-cell movement. After infection thus reaches the cells in the vasculature, the second step, known as long-distance or systemic movement, occurs as viruses move faster to distant organs through the vascular tissue, the phloem in most cases (59). As a result of these processes, the virus population within the infected plant may be strongly structured. Analyses of different viruses in different host plant species have shown that systemic movement causes population bottlenecks that may be severe (16, 28, 32, 34, 46), resulting in differences in the genetic composition of the virus subpopulations in different systemically infected organs. No analysis of population bottlenecks during cell-to-cell movement has been reported, but data indicate that the virus population within a leaf has a strong spatial structure with a separate distribution of different genotypes in different leaf areas. These reports derive from analyses of viruses that differ in genomic organization and gene expression strategies in different host plant species (9, 10, 23, 55); they indicate that a separate distribution of viral genotypes within the infected leaf is a general phenomenon and suggest limitation of coinfection. Data on the spatial exclusion of virus genotypes within the infected leaf are in apparent contradiction with the abundant evidence of recombination and complementation of defective mutants, which has been widely documented for plant viruses (19, 44, 50, 62). It should be pointed out that all reports on the spatial exclusion of virus genotypes in an infected leaf derive from microscopy observations, mostly at late times after infection of the tissue. No information is available on the kinetics of leaf colonization by viruses, and current data do not allow the estimation of MOI.In this report, we estimate the MOI of a plant RNA virus, Tobacco mosaic virus (TMV), in its systemic host, Nicotiana benthamiana. For this, we have reexamined the process of virus colonization by monitoring the progress of infection of two TMV genotypes in inoculated and in systemically infected leaves. The two TMV genotypes differed in the expression of fluorescent tags, either the green fluorescent protein (GFP) from Aequorea victoria (42, 43) or a red fluorescent protein (RFP) from Discosoma sp. (49). The expression of GFP and RFP allowed the precise quantification of the number of cells infected by either one or both TMV genotypes, and these data allowed the estimation of genotype frequencies and of MOI. The results show evidence of strong spatial structure of the virus population, with most cells being infected by either TMV-GFP or TMV-RFP alone and only a small fraction of cells being double infected. The kinetics of the single and double infections show that the MOI changes with time, decreasing as colonization progresses and therefore suggesting that exclusion mechanisms operate at later times after infection.     

Balamuthia mandrillaris: The multiple nuclei of Balamuthia amebas; their location, activity, and site of development

Multiple nuclei were first noted in the pseudopodia of Balamuthia mandrillaris amebas feeding on mammalian cells. Phase microscope observations of live amebas in vitro reveal that while many amebas have a single nucleus, others have multiple nuclear-like structures, now confirmed as nuclei with hematoxylin and Feulgen stains. In the live cultures, two nuclei located near the tip of an extended pseudopodium were seen to fuse resulting in one larger morphologic unit. Such merging of nuclei has not been previously reported. Other nuclei were located at positions that subsequently became the site for the outgrowth of an additional pseudopod branch. A newly discovered large structure, a polyploid nucleus, was located in the mid-part of the ameba. Nucleoli of uniform size were seen to develop from the central mass of chromatin and each became surrounded by a vesicular component as they moved into the protoplasm as morphologically complete nuclei.     

Modeling the Trypanosoma cruzi Tc85-11 protein and mapping the laminin-binding site

Trypanosoma cruzi expresses a set of glycoproteins encoded by the gp85/trans-sialidase gene superfamily. In this report a structure model is proposed for a cloned member of the superfamily, the Tc85-11 protein. The structure consists of an N-terminus beta-propeller and a C-terminus beta-sandwich interconnected by an alpha-helix. The recombinant protein, corresponding to the N-domain (Tc85-N), binds to laminin in a selective manner. Six synthetic 20-mer peptides from the N-domain adhere onto the surface of LLC-MK(2) cells and two of these peptides specifically inhibit the Tc85-N/laminin interaction, indicating that they are the laminin-binding sites of the molecule. Thus, Tc85-11 and other related members of the family appear to be good candidates to play an important role in T. cruzi infection via a laminin mediated host-parasite interaction.     

Scorpidotrema longistipes n. g., n. sp. (Digenea: Opecoelidae) from Scorpis georgiana (Teleostei: Scorpididae) from southern Western Australia

Scorpidotrema longistipes n. g., n. sp. is described from the intestine of Scorpis georgiana Valenciennes (Scorpididae) from off Point Peron, Western Australia. The new genus is distinguished by the combination of a remarkably long and retractable ventral sucker peduncle, a possible uroproct, well-developed cirrus-sac and a uterine seminal receptacle. The subfamilial relationships of the new genus are troublesome. It incorporates features of the Opecoelinae, Stenakrinae and Plagioporinae. The absence of a canalicular seminal receptacle suggests a relationship with the Opecoelinae and Stenakrinae, whereas the well-developed cirrus-sac suggests a relationship with the Plagioporinae and Stenakrinae. The overall arrangement of the gonads is not similar to that of existing genera of Stenakrinae. It is concluded that the genus is best placed in the Stenakrinae although that subfamily may now be an artificial assemblage. This new genus forms part of a distinctive fauna of trematodes restricted to Australian southern temperate fishes.     

Allopodocotyle skoliorchis n. sp. (Opecoelidae: Plagioporinae) from Parequula melbournensis (Castelnau) (Gerreidae), a temperate marine fish in Australian waters

A new species of Allopodocotyle Pritchard, 1966 is described from the intestine and pyloric caeca of Parequula melbournensis (Gerreidae) caught from the waters off South and Western Australia. The new species is distinguished from other species by its larger eggs, broader form, pre-bifurcal genital pore and a number of other measurable features that are discussed. Of the species that share morphological similarities with Allopodocotyle skoliorchis n. sp., it is the only species known from a gerreid; all the other species are from serranids.     

A new species of Podocotyloides Yamaguti, 1934 (Digenea: Opecoelidae) from a Western Australian temperate marine fish

A new species of Podocotyloides is described from Sillago bassensis caught off the coast of Western Australia. This is the second report of a species of this genus from Australian waters but the first of a new species. P. victori n. sp. is one of four species whose vitelline follicles extend into the forebody. It is distinguished from the other three species with vitelline follicles in the forebody by its relatively shorter forebody, smaller eggs and bipartite seminal vesicle. Pedunculotrema Fischthal & Thomas, 1970 is reduced to synonymy with Podocotyloides Yamaguti, 1934.     

Gene structure and M20T polymorphism of the Schistosoma mansoni Sm14 fatty acid-binding protein. Molecular,functioanl, and immunoprotection analysis

The Schistosoma mansoni Sm14 antigen belongs to the fatty acid-binding protein family and is considered a vaccine candidate against at least two parasite worms, Fasciola hepatica and S. mansoni. Here the genomic sequence and the polymorphism of Sm14 have been characterized for the first time. We found that the conserved methionine at position 20 is polymorphic, being exchangeable with threonine (M20T). To evaluate the function of the amino acid residue at this position, we have also constructed the mutant Sm14-A20 besides the two native isoforms (Sm14-M20 and Sm14-T20). The three purified recombinant His(6)-tagged Sm14 proteins (rSm14-M20, rSm14-T20, and rSm14-A20) present a predominant beta-barrel structure as shown by CD spectroscopy. Thermal and urea unfolding studies evidenced a higher structural stability of rSm14-M20 over the other forms (rSm14-M20>rSm14-T20>rSm14-A20). All of the Sm14 proteins were able to bind 11-(dansylamino)undecanoic acid (DAUDA) without substantial difference in the binding affinity. However, rSm14-M20 exhibited a higher affinity for natural fatty acids than the rSm14-T20 and rSm14-A20 proteins as judged by competitive experiments against DAUDA (rSm14-M20>rSm14-T20>rSm14-A20). The rSm14-M20 or rSm14-T20 isoforms but not the rSm14-A20 mutant was able to induce significant protection against S. mansoni cercariae challenge in immunized mice. The level of protection efficacy correlates with the extent of structure stability of the recombinant Sm14 isoforms and mutant.