Resistance to friend virus-induced erythroleukemia in W/W(v) mice is caused by a spleen-specific defect which results in a severe reduction in target cells and a lack of Sf-Stk expression

The characteristic progression and specificity of Friend virus for the erythroid lineage have allowed for the identification of a number of host-encoded loci that are required for disease progression. Several of these loci, including the Friend virus susceptibility gene 2 (Fv2), dominant white spotting gene (W), and Steel gene (Sl), regulate the initial polyclonal expansion of infected erythroid progenitor cells. W and Sl encode the Kit receptor tyrosine kinase and its ligand, stem cell factor, respectively. W mutant mice are severely anemic, and earlier work suggested that this defect in erythroid differentiation is the cause for the resistance to Friend virus-induced erythroleukemia. Here we show that in bone marrow, W/W(v) mice have near normal numbers of target cells and the initial infection of bone marrow occurs normally in vivo. In contrast, spleen cells from W/W(v) mice infected both in vitro and in vivo with Friend virus failed to give rise to erythropoietin-independent colonies at any time following Friend virus infection, suggesting that mutation of the Kit receptor specifically affects target cells in the spleen, rendering the mutant mice resistant to the development of Friend virus-induced erythroleukemia. In addition, we show that the Kit+ pathogenic targets of Friend virus in the spleen are distinct from the pathogenic targets in bone marrow and this population of spleen target cells is markedly decreased in W/W(v) mice and these cells fail to express Sf-Stk. These results also underscore the unique nature of the spleen microenvironment in its role in supporting the progression of acute leukemia in Friend virus-infected mice.     

Differential elicitation of two processing proteases controls the processing pattern of the trypsin proteinase inhibitor precursor in Nicotiana attenuata

Trypsin proteinase inhibitors (TPIs) of Nicotiana attenuata are major antiherbivore defenses that increase dramatically in leaves after attack or methyl jasmonate (MeJA) elicitation. To understand the elicitation process, we characterized the proteolytic fragmentation and release of TPIs from a multidomain precursor by proteases in MeJA-elicited and unelicited plants. A set of approximately 6-kD TPI peptides was purified from leaves, and their posttranslational modifications were characterized. In MeJA-elicited plants, the diversity of TPI structures was greater than the precursor gene predicted. This elicited structural heterogeneity resulted from differential fragmentation of the linker peptide (LP) that separates the seven-domain TPI functional domains. Using an in vitro fluorescence resonance energy transfer assay and synthetic substrates derived from the LP sequence, we characterized proteases involved in both the processing of the TPI precursor and its vacuolar targeting sequence. Although both a vacuolar processing enzyme and a subtilisin-like protease were found to participate in a two-step processing of LP, only the activity of the subtilisin-like protease was significantly increased by MeJA elicitation. We propose that MeJA elicitation increases TPI precursor production and saturates the proteolytic machinery, changing the processing pattern of TPIs. To test this hypothesis, we elicited a TPI-deficient N. attenuata genotype that had been transformed with a functional NaTPI gene under control of a constitutive promoter and characterized the resulting TPIs. We found no alterations in the processing pattern predicted from the sequence: a result consistent with the saturation hypothesis.     

Genetic mapping and comparative analysis of seven mutants related to seed fiber development in cotton

Mapping of genes that play major roles in cotton fiber development is an important step toward their cloning and manipulation, and provides a test of their relationships (if any) to agriculturally-important QTLs. Seven previously identified fiber mutants, four dominant (Li ₁, Li ₂, N ₁ and Fbl) and three recessive (n ₂, sma-4(h _a), and sma-4(fz)), were genetically mapped in six F₂ populations comprising 124 or more plants each. For those mutants previously assigned to chromosomes by using aneuploids or by linkage to other morphological markers, all map locations were concordant except n ₂, which mapped to the homoeolog of the chromosome previously reported. Three mutations with primary effects on fuzz fibers (N ₁, Fbl, n ₂) mapped near the likelihood peaks for QTLs that affected lint fiber productivity in the same populations, perhaps suggesting pleiotropic effects on both fiber types. However, only Li ₁ mapped within the likelihood interval for 191 previously detected lint fiber QTLs discovered in non-mutant crosses, suggesting that these mutations may occur in genes that played early roles in cotton fiber evolution, and for which new allelic variants are quickly eliminated from improved germplasm. A close positional association between sma-4(h _a ), two leaf and stem-borne trichome mutants (t ₁ , t ₂), and a gene previously implicated in fiber development, sucrose synthase, raises questions about the possibility that these genes may be functionally related. Increasing knowledge of the correspondence of the cotton and Arabidopsis genomes provides several avenues by which genetic dissection of cotton fiber development may be accelerated.     

Site-specific immobilization of proteins in a microarray using intein-mediated protein splicing

One of the critical issues in the generation of a protein microarray lies in the choice of immobilization strategies, which ensure proteins are adhered to the glass surface while properly retaining their native biological activities. Herein, we report a bacterium-based, intein-mediated strategy to generate N-terminal cysteine-containing proteins which are then chemoselectively immobilized to a thioester-functionalized glass slide to generate the corresponding protein microarray. We also showed preliminary data of the strategy in a yeast host system.     

Massive number of antigen-specific CD4 T cells during vaccination with live attenuated Salmonella causes interclonal competition

The clonal burst size of CD4 T cells is predicted to be less than that of CD8 T cells. In this study, we demonstrate that massive numbers of Ag-specific CD4 T cells respond during vaccination of mice with live attenuated Salmonella, reaching a peak frequency of approximately 50% of CD4 T cells. Salmonella-specific T cells persisted at high frequency for several weeks and could be detected in the memory population for months after infection. Surprisingly, the expansion of endogenous Salmonella-specific CD4 T cells prevented the persistence of adoptively transferred Salmonella-specific T cells in vivo, demonstrating interclonal competition for access to the memory compartment.     

DNA transfer into human lung cells is improved with Tat-RGD peptide by caveoli-mediated endocytosis

Cell lines and primary cells exhibit varying degrees of resistance to DNA transfection strategies. In this study, we employed the synthetic peptide Tat-RGD (TR), composed of the HIV-1 derived translocation peptide Tat fused to the integrin binding RGD motif, as a tool for improving DNA transfer into pulmonary cells. Binding experiments between DNA and TR and cytotoxicity measurements of TR treated cells were undertaken to optimize DNA and TR concentrations for transfection. Addition of a complex of TR and DNA (TRD) to A549 cells yielded significant transgene expression. When TRD was combined with Lipofectamine (TRDL), the expression was increased by 5-fold over Lipofectamine (DL) and by approximately 30-fold over TRD-mediated transfections. Also, in primary smooth muscle cells (SMC) and fibroblasts (FB) derived from pulmonary arteries, an increase in TRDL-mediated transfection efficiency was observed by a factor of approximately 2 and approximately 3 over that of DL. Laser scanning confocal microscopy for visualizing TR-dependent DNA uptake demonstrated that the internalization of TRDL complexes is linked to caveoli in the plasma membrane. Interfering with caveoli formation by methyl-b-cyclo-dextrin drastically decreased the transfection efficiency by TR. In conclusion, the Tat-RGD peptide mediates efficient gene delivery in human pulmonary cells, in particular when combined with a standard cationic lipid based transfection reagent. The enhancement of DNA uptake by Tat-RGD is suggested to be mediated by caveoli-dependent endocytosis.     

Blending chitosan with polycaprolactone: effects on physicochemical and antibacterial properties

Chitosan is a well sought-after polysaccharide in biomedical applications and has been blended with various macromolecules to mitigate undesirable properties. However, the effects of blending on the unique antibacterial activity of chitosan as well as changes in fatigue and degradation properties are not well understood. The aim of this work was to evaluate the anti-bacterial properties and changes in physicochemical properties of chitosan upon blending with synthetic polyester poly(epsilon-caprolactone) (PCL). Chitosan and PCL were homogeneously dissolved in varying mass ratios in a unique 77% acetic acid in water mixture and processed into uniform membranes. When subjected to uniaxial cyclical loading in wet conditions, these membranes sustained 10 cycles of predetermined loads up to 1 MPa without break. Chitosan was anti-adhesive to Gram-positive Streptococcus mutans and Gram-negative Actinobacillus actinomycetemcomitans bacteria. Presence of PCL compromised the antibacterial property of chitosan. Four-week degradation studies in PBS/lysozyme at 37 degrees C showed initial weight loss due to chitosan after which no significant changes were observed. Molecular interactions between chitosan and PCL were investigated using Fourier transform infrared spectroscopy (FTIR) which showed no chemical bond formations in the prepared blends. Investigation by wide-angle X-ray diffraction (WAXD) indicated that the crystal structure of individual polymers was unchanged in the blends. Dynamic mechanical and thermal analysis (DMTA) indicated that the crystallinity of PCL was suppressed and its storage modulus increased with the addition of chitosan. Analysis of surface topography by atomic force microscopy (AFM) showed a significant increase in roughness of all blends relative to chitosan. Observed differences in biological and anti-bacterial properties of blends could be primarily attributed to surface topographical changes.     

Anergy in CD4 memory T lymphocytes. II. Abrogation of TCR-induced formation of membrane signaling complexes

Memory and naive CD4 T cells have unique regulatory pathways for self/non-self discrimination. A memory cell specific regulatory pathway was revealed using superantigens to trigger the TCR. Upon stimulation by bacterial superantigens, like staphylococcal enterotoxin B (SEB), TCR proximal signaling is impaired leading to clonal tolerance (anergy). In the present report, we show that memory cell anergy results from the sequestration of the protein tyrosine kinase ZAP-70 away from the TCR/CD3ζ chain. During SEB-induced signaling, ZAP-70 is excluded from both detergent-resistant membrane microdomains and the immunological synapse, thus blocking downstream signaling. We also show that the mechanism underlying memory cell anergy must involve Fyn kinase, given that the suppression of Fyn activity restores the movement of ZAP-70 to the immunological synapse, TCR proximal signaling, and cell proliferation. Thus, toleragens, including microbial toxins, may modulate memory responses by targeting the organizational structure of memory cell signaling complexes.     

Molecular characterization of <Emphasis Type="Italic">Vigna radiata</Emphasis> (L.) Wilczek genotypes based on nuclear ribosomal DNA and RAPD polymorphism

Mungbean germplasm characterization, evaluation and improvement are fundamentally based on morpho-agronomic traits. The lack of break-through in mungbean production has been due to non-availability of genetic variability for high yield potential. Forty-four genotypes of mungbean [Vigna radiata (L.)Wilczek] were subjected to random amplified polymorphic DNA (RAPD) analysis to assess the genetic diversity and relationships among the genotypes. Multilocus genotyping by twelve RAPD primers generated 166 markers and detected an average of intraspecific variation amounting to 82% polymorphism in banding patterns. Dendrogram obtained from cluster analysis delineated all the 44 genotypes into six clusters. Higher values of Nei’s gene diversity (h) and Shannon information index (i) and genetic distance analysis validate existence of wide genetic diversity among mungbean genotypes tested. Besides internal transcribed spacer (ITS) length variations, single nucleotide polymorphisms (SNPs) and insertions/deletions (INDELS) were detected at number of sites in nuclear rDNA region and the sequences of representatives of each sub-cluster and all distinct genotypes have been submitted to NCBI database and assigned Gen accession numbers HQ 148136-148147. Multiple sequence alignment revealed further lineages of distinct genotypes with main RAPD clusters. The measures of relative genetic distances among the genotypes of mungbean did not completely correlate the geographical places of their development. The homogeneous phenotypic markers proved insufficient in exhibiting genetic divergence among mungbean genotypes studied. RMG-62, RMG-976, and NDM-56 have been identified as potential source of parents for crop improvement. RAPD primers, OPA-9 and OPA-2 as polymorphic genetic markers and number of pods/plant and number of seeds/plant as dependable phenotypic markers have been identified for improving yield potentials. This genetic diversity will be of significance in developing intraspecific crosses in mungbean crop improvement programme.