Cell-associated ovalbumin is cross-presented much more efficiently than soluble ovalbumin in vivo

To better understand the antigenic requirements for cross-presentation, we compared the in vivo efficiency of presentation of cell-associated vs soluble OVA with the OT-I (CD8) and OT-II (CD4) TCR transgenic lines. Cross-presentation of cell-associated OVA was very efficient, requiring as little as 21 ng of OVA to activate OT-II cells and 100-fold less to activate OT-I cells. In contrast, soluble OVA was presented inefficiently, requiring at least 10,000 ng OVA for activation of either T cell subset. Thus, cell-associated OVA was presented 500-fold more efficiently than soluble OVA to CD4 T cells and 50,000-fold more efficiently to CD8 T cells. These data, which represent the first quantitative in vivo analysis of cross-presentation, show that cell-associated OVA is very efficiently presented via the class I pathway.     

Spatial constraints on polyadenylation signal function

Efficient cleavage and polyadenylation of eukaryotic messenger RNAs require at least two signal elements: an AAUAAA or closely related sequence located 7-30 base pairs (bp) upstream of the site of processing, and a G/U- or U-rich sequence located 3' to the cleavage site. The herpes simplex virus type 1 thymidine kinase (tk) gene contains two copies of the AATAAA hexanucleotide and a GT-rich region. We have shown that the first AATAAA and the GT-rich region are essential for efficient processing, both in vivo and in vitro, whereas the second AATAAA does not appear to play any role in the formation of tk mRNA 3' ends. The failure of a signal containing only the second AATAAA and the GT-rich element to signal cleavage and polyadenylation suggested that these two elements might be too close together to constitute a functional polyadenylation signal. The experiments described in this report were directed at determining the effects on mRNA 3' end formation of alterations in spacing between signal elements. Wild-type tk contains 19 bp between these two elements. Constructs were made in which an AATAAA and the GT-rich region were separated by various distances ranging from 7 to 43 bp. The quantity and location of 3' ends of the tk mRNA produced by these constructs in Cos-1 cells were measured by S1 nuclease protection analysis. Signal efficiency was gradually reduced as the separation between the two signal elements was increased; with a separation of 43 bp, the signal functioned at approximately one-eighth the efficiency of the parental construction. Bringing the two signals closer together resulted in decreased signal efficiency; with a separation of 7 or 9 bp, no tk mRNA polyadenylated within the normal region was produced. Altering the sequences between these two elements without changing the distance had small effects on processing efficiency.     

The T cell receptor V alpha 11 gene family. Analysis of allelic sequence polymorphism and demonstration of J alpha region-dependent recognition by allele-specific antibodies.

Allelic polymorphism in TCR loci may play an important role in shaping the T cell repertoire and in disease susceptibility. We have used a combination of antibody and sequence analysis to investigate polymorphism in the murine V alpha 11 family. Two different antibodies have been analyzed that recognize particular V alpha 11 family members of the V alpha b and V alpha d haplotypes. One antibody shows J alpha dependency, suggesting a conformational element to the epitope. Investigation of the anti-V alpha 11 staining pattern on different mouse strains indicates that there is a marked influence of MHC haplotype on V alpha 11 selection and that V alpha 11 is preferentially expressed on CD4+ cells. Sequence analysis of V alpha 11 genes from the V alpha a, V alpha b, and V alpha d haplotypes shows two potential regions for the haplotype-specific epitopes. The relatedness of the different V alpha 11 family members from different haplotypes suggests that the V alpha 11.1/11.2 gene duplication is relatively recent, but that V alpha 11.3 separated much earlier. Differences between V alpha 11.3 and V alpha 11.1/11.2 are concentrated in the putative complementarity determining regions (CDR), whereas differences between alleles are not clearly clustered. However, the V alpha 11.1a and V alpha 11.1d alleles differ from V alpha 11.1b and V alpha 11.2b in CDR1. A V alpha 11.2-expressing anti-cytochrome c T cell has the same V-J junction as a V alpha 11.1-bearing cell with a similar fine specificity, indicating that V alpha 11.1b and V alpha 11.2b do not contribute different Ag specificities.     

Multiple effects of temperature,photoperiod and food quality on the performance of a pine sawfly

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Mutations in the Parainfluenza Virus 5 Fusion Protein Reveal Domains Important for Fusion Triggering and Metastability

Paramyxovirus membrane glycoproteins F (fusion protein) and HN, H, or G (attachment protein) are critical for virus entry, which occurs through fusion of viral and cellular envelopes. The F protein folds into a homotrimeric, metastable prefusion form that can be triggered by the attachment protein to undergo a series of structural rearrangements, ultimately folding into a stable postfusion form. In paramyxovirus-infected cells, the F protein is activated in the Golgi apparatus by cleavage adjacent to a hydrophobic fusion peptide that inserts into the target membrane, eventually bringing the membranes together by F refolding. However, it is not clear how the attachment protein, known as HN in parainfluenza virus 5 (PIV5), interacts with F and triggers F to initiate fusion. To understand the roles of various F protein domains in fusion triggering and metastability, single point mutations were introduced into the PIV5 F protein. By extensive study of F protein cleavage activation, surface expression, and energetics of fusion triggering, we found a role for an immunoglobulin-like (Ig-like) domain, where multiple hydrophobic residues on the PIV5 F protein may mediate F-HN interactions. Additionally, destabilizing mutations of PIV5 F that resulted in HN trigger-independent mutant F proteins were identified in a region along the border of F trimer subunits. The positions of the potential HN-interacting region and the region important for F stability in the lower part of the PIV5 F prefusion structure provide clues to the receptor-binding initiated, HN-mediated F trigger.     

Decoupled genomic elements and the evolution of partner quality in nitrogen‐fixing rhizobia

Understanding how mutualisms evolve in response to a changing environment will be critical for predicting the long‐term impacts of global changes, such as increased N (nitrogen) deposition. Bacterial mutualists in particular might evolve quickly, thanks to short generation times and the potential for independent evolution of plasmids through recombination and/or HGT (horizontal gene transfer). In a previous work using the legume/rhizobia mutualism, we demonstrated that long‐term nitrogen fertilization caused the evolution of less‐mutualistic rhizobia. Here, we use our 63 previously isolated rhizobium strains in comparative phylogenetic and quantitative genetic analyses to determine the degree to which variation in partner quality is attributable to phylogenetic relationships among strains versus recent genetic changes in response to N fertilization. We find evidence of distinct evolutionary relationships between chromosomal and pSym genes, and broad similarity between pSym genes. We also find that nifD has a unique evolutionary history that explains much of the variation in partner quality, and suggest MoFe subunit interaction sites in the evolution of less‐mutualistic rhizobia. These results provide insight into the mechanisms behind the evolutionary response of rhizobia to long‐term N fertilization, and we discuss the implications of our results for the evolution of the mutualism.     

Association of ganglioside-protein conjugates into cell and Sendai virus. Requirement for the HN subunit in viral fusion

We have prepared several electron and light microscopic labels of epidermal growth factor (EGF) to analyse the morphologic features of its binding and internalization by cultured cells. These include a ferritin conjugate of EGF, a covalent conjugate of EGF and horseradish peroxidase (EGF-HRP), a colloidal gold marker system using EGF-HRP as a primary antigen, and a covalent complex of EGF with rhodamine-labelled lactalbumin. All of the light and electron microscopic labels showed similar patterns of binding. EGF initially bound to diffusely distributed cell surface receptors at 4 degrees C. The EGF-receptor complexes clustered into clathrin-coated pits on the cell surface only when the temperature was raised to 37 degrees C. In KB and Swiss 3T3 cells, this was followed by rapid internationalization into receptosomes, compartmentalization into the Golgi system, clustering in the clathrin-coated regions of the Golgi, and finally delivery into lysosomes from the Golgi. This general pathway was seen in Swiss 3T3 cells which have a low number of EGF receptors, KB cells which have a moderate number of receptors and A431 cells that have a high number of receptors. However, the ruffling activity induced in A431 cells by EGF produced some internalization through macropinosomes, making the pathway of entry more difficult to evaluate. Double label experiments showed that EGF is internalized together with alpha 2-macroglobulin and adenovirus particles. These data clarify the route of entry of EGF in different cell types using multiple labels, and shows that it enters cells through the same coated pit entry pathway as most other ligands previously examined.