Reduced mannose incorporation into GDP-mannose and dolichol-linked intermediates of N-glycosylation in hamster liver during vitamin A deficiency

Summary The molecular mechanism of reduced incorporation of radioactively labeled mannose into hamster liver glycoconjugates during the progression of vitamin A deficiency was investigated. In particular the in vivo incorporation of [2-³H]mannose into GDP-mannose, dolichyl phosphate mannose (Dol-P-Man), lipid-linked oligosaccharides, and glycopeptides of hamster liver was examined. Hamsters maintained on a vitamin A-free diet showed a reduction in the incorporation of mannose into GDP-mannose about 10 days before clinical signs of vitamin A deficiency could be observed. The decrease in [2-³H]mannose incorporated into GDP-mannose was accompanied by a reduction in label incorporated into Dol-P-Man, lipid linked oligosaccharides and glycopeptides, which became more severe with the progression of vitamin A deficiency. By the time they reached a plateau stage of growth, hamsters fed the vitamin A-free diet showed a 50% reduction in the amount of [2-³H]mannose converted to GDP-mannose, and the radioactivity associated with Dol-P-Man and glycopeptides was reduced by approximately 60% as compared to retinoic acid-supplemented controls. These results strongly indicate that the reduced incorporation of mannose into lipidic intermediates and glycoproteins observed during vitamin A deficiency is due to impaired GDP-mannose synthesis.Abbreviations Dol-P-Man Dolichyl Phosphate Mannose - Dol-P Dolichyl Phosphate     

Ultrastructure of the larval firefly light organ as related to control of light emission

The firefly larva has a pair of light organs consisting of a layer of interdigitating, light emitting cells, covered dorsally with a layer of opaque, white cells. Each light organ is ventilated by one large and several smaller tracheal branches and is innervated by a branch of the segmental nerve containing two axons. These axons branch profusely in the photocyte layer so that several nerve profiles are seen around any photocyte. Nerve terminals contain large dense-core vesicles and small light-core vesicles. Clusters of light-core vesicles surrounding irregularly shaped membrane densifications, presumably the synapses between nerve and photocyte, are common in nerve terminals. Light emitting cells in insects characteristically contain photocyte vesicles. In the larva there are both full and empty photocyte vesicles; the full vesicles contain a matrix with tubular membrane invaginations in contrast to the empty vesicles which contain amorphous membrane invaginations.     

Fuzziness and Heterogeneity of Benthic Metacommunities in a Complex Transitional System

We propose an extension to the metacommunity (MC) concept and a novel operational methodology that has the potential to refine the analysis of MC structure at different hierarchical levels. We show that assemblages of species can also be seen as assemblages of abstract subregional habitat-related metacommunities (habMCs). This intrinsically fuzzy concept recognizes the existence of habMCs that are typically associated with given habitats, while allowing for the mixing and superposition of different habMCs in all sites and for boundaries among subregions that are neither spatially sharp nor temporally constant. The combination of fuzzy clustering and direct gradient analysis permits us to 1) objectively identify the number of habMCs that are present in a region as well as their spatial distributions and relative weights at different sites; 2) associate different subregions with different biological communities; and 3) quantitatively assess the affinities between habMCs and physical, morphological, biogeochemical, and environmental properties, thereby enabling an analysis of the roles and relative importance of various environmental parameters in shaping the spatial structure of a metacommunity. This concept and methodology offer the possibility of integrating the continuum and community unit concepts and of developing the concept of a habMC ecological niche. This approach also facilitates the practical application of the MC concept, which are not currently in common use. Applying these methods to macrophytobenthic and macrozoobenthic hard-substrate assemblages in the Venetian Lagoon, we identified a hierarchical organization of macrobenthic communities that associated different habMCs with different habitats. Our results demonstrate that different reference terms should be applied to different subregions to assess the ecological status of a waterbody and show that a combination of several environmental parameters describes the spatial heterogeneity of benthic communities much better than any single property can. Our results also emphasize the importance of considering heterogeneity and fuzziness when working in natural systems.     

Fine characterization of the Iceman's mtDNA haplogroup

Starting from specimens of the intestinal contents of the so-called Tyrolean Iceman or Otzi (5,350-5,100 years before present), it was possible by polymerase chain reaction to amplify fragments of the human mitochondrial DNA (mtDNA) control region that correspond to the sequence found in 1994 at the Munich and Oxford laboratories and which had been attributed to the original DNA of the mummy. The particularly favorable condition of the specimens, showing very low contamination levels, made it easier to extend the analyses to the coding region, which had not previously been considered. The mtDNA of the European population is currently divided into nine (H, T, U, V, W, X, I, J, and K) main groups (haplogroups). The K haplogroup, in particular, is composed of two (K1 and K2) subclusters. The results demonstrate that the Iceman's mtDNA belongs to the K1 subcluster, yet it does not fit any of the three known branches (a, b, and c) into which the K1 subcluster is presently divided. In addition, some other sites, reported to be linked to environmental adaptation or pathologies, were investigated.     

Melan-A/MART-1-specific CD4 T cells in melanoma patients: identification of new epitopes and ex vivo visualization of specific T cells by MHC class II tetramers

Over the past decade, many efforts have been made to identify MHC class II-restricted epitopes from different tumor-associated Ags. Melan-A/MART-1(26-35) parental or Melan-A/MART-1(26-35(A27L)) analog epitopes have been widely used in melanoma immunotherapy to induce and boost CTL responses, but only one Th epitope is currently known (Melan-A51-73, DRB1*0401 restricted). In this study, we describe two novel Melan-A/MART-1-derived sequences recognized by CD4 T cells from melanoma patients. These epitopes can be mimicked by peptides Melan-A27-40 presented by HLA-DRB1*0101 and HLA-DRB1*0102 and Melan-A25-36 presented by HLA-DQB1*0602 and HLA-DRB1*0301. CD4 T cell clones specific for these epitopes recognize Melan-A/MART-1+ tumor cells and Melan-A/MART-1-transduced EBV-B cells and recognition is reduced by inhibitors of the MHC class II presentation pathway. This suggests that the epitopes are naturally processed and presented by EBV-B cells and melanoma cells. Moreover, Melan-A-specific Abs could be detected in the serum of patients with measurable CD4 T cell responses specific for Melan-A/MART-1. Interestingly, even the short Melan-A/MART-1(26-35(A27L)) peptide was recognized by CD4 T cells from HLA-DQ6+ and HLA-DR3+ melanoma patients. Using Melan-A/MART-1(25-36)/DQ6 tetramers, we could detect Ag-specific CD4 T cells directly ex vivo in circulating lymphocytes of a melanoma patient. Together, these results provide the basis for monitoring of naturally occurring and vaccine-induced Melan-A/MART-1-specific CD4 T cell responses, allowing precise and ex vivo characterization of responding T cells.     

Virulence Determinants of Avian H5N1 Influenza A Virus in Mammalian and Avian Hosts: Role of the C-Terminal ESEV Motif in the Viral NS1 Protein

We assessed the prediction that access of the viral NS1 protein to cellular PDZ domain protein networks enhances the virulence of highly pathogenic avian influenza A viruses. The NS1 proteins of most avian influenza viruses bear the C-terminal ligand sequence Glu-Ser-Glu-Val (ESEV) for PDZ domains present in multiple host proteins, whereas no such motif is found in the NS1 homologues of seasonal human virus strains. Previous analysis showed that a C-terminal ESEV motif increases viral virulence when introduced into the NS1 protein of mouse-adapted H1N1 influenza virus. To examine the role of the PDZ domain ligand motif in avian influenza virus virulence, we generated three recombinants, derived from the prototypic H5N1 influenza A/Vietnam/1203/04 virus, expressing NS1 proteins that either have the C-terminal ESEV motif or the human influenza virus RSKV consensus or bear a natural truncation of this motif, respectively. Cell biological analyses showed strong control of NS1 nuclear migration in infected mammalian and avian cells, with only minor differences between the three variants. The ESEV sequence attenuated viral replication on cultured human, murine, and duck cells but not on chicken fibroblasts. However, all three viruses caused highly lethal infections in mice and chickens, with little difference in viral titers in organs, mean lethal dose, or intravenous pathogenicity index. These findings demonstrate that a PDZ domain ligand sequence in NS1 contributes little to the virulence of H5N1 viruses in these hosts, and they indicate that this motif modulates viral replication in a strain- and host-dependent manner.The transmission of highly pathogenic avian influenza A viruses (HPAIV) of the H5N1 subtype to humans since the year 1997 has caused a high mortality rate of almost 60% (62). Patients infected with H5N1 influenza virus developed mainly severe respiratory disease, characterized by fever, cough, shortness of breath, and pneumonia, that frequently progressed to acute respiratory distress syndrome (ARDS) and multiorgan failure (28, 68, 69). In fatal cases, the median time from onset to death was 9 to 10 days (1). Systemic spread (18) and hypercytokinemia (11) have been described as possible disease-aggravating factors of HPAIV-H5N1 viruses, but the reasons for their high virulence in humans are incompletely understood.Due to the potential pandemic threat presented by H5N1 viruses, there is great interest in the identification of viral virulence determinants and their mode of action. This is critical not only for a better understanding of the pathogenic mechanisms induced by these viruses but also for the development of new drugs to treat the infections. The high virulence of HPAIV-H5N1 isolates in the avian host correlates with the presence of a polybasic cleavage site in the hemagglutinin (HA), facilitating its intracellular cleavage by furin-like proteases (27, 50). Further, amino acid substitutions in the PA protein (T515A) (30) and in the NS1 protein (V149A) (40) have been reported to regulate the virulence of corresponding HPAIV-H5N1 isolates in ducks and chickens. The known molecular determinants of virulence in mammalian hosts also include the polybasic cleavage site in the HA (23) and several polymorphisms in the PB2 polymerase subunit and the proapoptotic PB1-F2 protein. Thus, a serine residue at position 66 in the PB1-F2 protein increased viral replication and decreased survival in the mouse model (9). Also, specific amino acid polymorphisms within PB2 (E627K or D701N) can increase virulence in mice (23, 39) and viral replication in mammalian cells (7, 57, 58). Furthermore, the nonstructural NS1 protein, which has a major function in the inhibition of type I interferon (IFN) (17, 19) and in the limitation of the antiviral effects of IFN-induced proteins, including PKR (4, 22), OAS/RNase L (45), and RIG-I (16, 48, 63, 64), contributes to virulence in mammals (34, 55).The domain structure of the NS1 protein is well characterized; it includes an N-terminal RNA binding and dimerization domain and a nuclear localization signal (NLS) at positions 34 to 38 (summarized in reference 19). The NS1 proteins of most human strains circulating between 1950 and 1986 also contain a second NLS at positions 219 to 227 (NLS-2), which includes four conserved basic amino acids (K219, R220, R224, R227) (44). A large-scale sequence analysis showed that the NS1 proteins of avian and human influenza viruses differ in their C-terminal sequences, indicating possible differences in the associated activity (46). Among most high- and low-pathogenicity avian influenza viruses, the last four NS1 amino acids consist of the conserved sequence ESEV (3,007 of 3,692 isolates described in the NCBI database [3]), while for the majority of seasonal human influenza viruses, the motif RSKV is typical (1,911 of 2,713 isolates). Significantly, only the NS1 protein carrying the “avian” ESEV motif interacted in vitro with 24 cellular factors carrying a PDZ (postsynaptic density protein 95, Drosophila disc large tumor suppressor, and zonula occludens 1 protein) domain. The human genome encodes at least 214 proteins containing one or more of these protein interaction modules that recognize short peptide motifs, which are most often present at the C termini of their targets (36, 38). Many PDZ domain proteins have been shown to mediate the formation and localization of higher-order complexes and to participate in various cellular signaling events regulating, for instance, cell polarity and neuronal function (31). Therefore, it was hypothesized that the abundant expression of “avian” NS1 protein capable of interacting with human PDZ domains could possibly disturb their function and aggravate disease severity in H5N1 infections (46). However, there is only limited experimental support for the universal validity of this hypothesis. The grafting of the “avian” ESEV sequence into the C terminus of NS1 protein expressed by mouse-adapted influenza A/WSN/33 virus (H1N1) decreased the mean lethal dose by about 1 order of magnitude (32). Still, it is not clear to what extent this motif contributes to the virulence of HPAIV-H5N1 and other natural influenza A viruses in avian and mammalian hosts.The goal of the present study was to elucidate the role of the C-terminal NS1 motif in viral replication and disease caused by the prototypic influenza A/Vietnam/1203/04 (VN/1203) virus, isolated in a fatal human case (60). This virus expresses an NS1 protein that is very similar or identical at positions 1 to 215 to homologues expressed by other HPAIV-H5N1 strains but naturally lacks the 10 C-terminal amino acids (aa), including the terminal ESEV motif, due to a premature stop codon (Fig. ​(Fig.1).1). We used reverse genetics to produce a recombinant VN/1203 wild-type (WT) virus and two variants with reconstituted NS1 C termini ending either with the “avian” ESEV or with the “human” RSKV sequence. Experimental infections of mice and chickens revealed that all three viruses caused highly lethal infections in both species, with only moderate differences in viral titers in the organs of the mice. Thus, we show that the C-terminal ESEV motif of the NS1 protein contributes little to the virulence of H5N1 viruses in mice and chickens, and we suggest that this motif modulates viral virulence in a strain- and host-dependent manner.Open in a separate windowFIG. 1.Growth kinetics of recombinant VN/1203 viruses expressing WT or elongated NS1 proteins in human, murine, and avian cells. (A) Scheme of the viral VN/1203-NS1 protein with the RNA binding domain and the nuclear localization signals (NLS) at positions 34 to 38 and 214 to 225 indicated. Amino acids involved in NLS2 function are underlined. The C-terminal sequences of the WT and elongated mutant NS1 proteins are given, and the PL motif is shown in boldface. (B to E) Human A549 alveolar cells, murine NIH 3T3 fibroblasts, chicken embryo fibroblasts (CEFs), or EFB-R1 duck embryo fibroblasts (DEFs) were infected with recombinant VN/1203-WT, -ESEV, or -RSKV viruses at an MOI of 0.001. Aliquots of supernatants were harvested at the indicated time points, and samples were titrated by plaque assays in MDCK cells. (F) Human A549 cells were infected at an MOI of 2, and virus titers in supernatants taken at the indicated time points were determined by plaque assays. Results are averages for at least two independent experiments with biological duplicates. Error bars indicate standard deviations.     

Molecular characterization and genetic structure of the Nero Siciliano pig breed

Nero Siciliano is an autochthonous pig breed that is reared mainly in semi-extensive systems in northeastern Sicily. Despite its economic importance and well-appreciated meat products, this breed is currently endangered. Consequently, an analysis of intra-breed variability is a fundamental step in preserving this genetic resource and its breeding system. In this work, we used 25 microsatellite markers to examine the genetic composition of 147 unrelated Nero Siciliano pigs. The total number of alleles detected (249, 9.96 per locus) and the expected heterozygosity (0.708) indicated that this breed had a high level of genetic variability. Bayesian cluster analysis showed that the most likely number of groups into which the sample could be partitioned was nine. Based on the proportion of each individuals genome derived from ancestry, pigs with at least 70% of their genome belonging to one cluster were assigned to that cluster. The cluster size ranged from 7 to 17 (n = 108). Genetic variability in this sub-population was slightly lower than in the whole sample, genetic differentiation among clusters was moderate (F(ST) 0.125) and the F(IS) value was 0.011. NeighborNet and correspondence analysis revealed two clusters as the most divergent. Molecular coancestry analysis confirmed the good within-breed variability and highlighted the clusters that retained the highest genetic diversity.