Tissue-mediated selection of viral variants: correlation between glycoprotein mutation and growth in neuronal cells.

Viral variants with different biological properties predominate in the central nervous system (CNS) and lymphoid tissues of carrier mice infected at birth with the Armstrong strain of lymphocytic choriomeningitis virus. The CNS isolates have the same phenotype as the parental strain and cause acute infections in adult mice, while the spleen-derived isolates cause chronic infections associated with suppressed T-cell responses and susceptibility to opportunistic infections. Our previous studies have identified a single amino acid change in the viral glycoprotein, a phenylalanine-to-leucine (F-->L) mutation at residue 260, that correlates with the tissue-specific selection and the persistent and immunosuppressive phenotype of the spleen isolates (R. Ahmed, C.S. Hahn, T. Somasundaram, L. Villarete, M. Matloubian, and J. H. Strauss, J. Virol. 65:4242-4247, 1991). In this study, we screened viral isolates obtained from the spleen, liver, kidney, and brain of carrier mice for the presence of this mutation and determined the temporal selection of variants as they appear in these organs. We found that this F-->L amino acid change is common to > 90% of the spleen and liver isolates and is selected for rapidly by day 32 postinfection (p.i.). Although the kinetics observed in the kidney are relatively slower than in the spleen and liver, this F-->L mutation predominates in the kidney-derived isolates by 250 days p.i. In contrast, the majority of the CNS isolates retain the parental sequence up to 250 days p.i. In addition, most of the brain isolates replicated efficiently in a neuronal cell line, and this enhanced growth phenotype in neurons correlated with the parental F genotype. This linkage with neurotropism, along with our earlier finding that the F-->L mutation is necessary for enhanced infection of macrophages (M. Matloubian, S. R. Kolhekar, T. Somasundaram, and R. Ahmed, J. Virol. 67:7340-7349, 1993), provides a cellular basis for the molecular changes associated with tissue-specific selection. Taken together, these results suggest that tropism for macrophages is a critical determinant in selection of variants with the F-->L mutation in tissues such as spleen and liver, and tropism for neurons is important in retention of the F genotype in the CNS.     

Molecular determinants of macrophage tropism and viral persistence: importance of single amino acid changes in the polymerase and glycoprotein of lymphocytic choriomeningitis virus.

This study documents that the immunosuppressive lymphocytic choriomeningitis virus (LCMV) variant, clone 13, shows a specific predilection for enhanced infection of macrophages both in vitro and in vivo and that single amino acid changes in the viral polymerase and glycoprotein are responsible for macrophage tropism. The growth difference seen between variant clone 13 and the parental Armstrong strain was specific for macrophages, since both clone 13 and Armstrong grew equally well in fibroblasts and neither isolate infected lymphocytes efficiently. Complete sequencing of the clone 13 genome, along with genetic analysis, showed that a single amino acid change in the polymerase (K-->Q at position 1079) was the major determinant of virus yield in macrophages. This was proven unequivocally by comparing the sequences of parental and reassortant viruses, which were identical at all loci except for the single mutation in the polymerase gene. This finding was further strengthened by showing that reversion at this site back to lysine (Q-->K) resulted in loss of macrophage tropism. In addition, an independently derived macrophage-tropic variant of LCMV, clone 28b, had a K-->N mutation at the same position. Thus, these results show that substitution of the positively charged amino acid K with a neutral amino acid (either Q or N) at residue 1079 of the polymerase resulted in enhanced viral replication in macrophages. In addition to the polymerase change, a mutation in the glycoprotein was also associated with macrophage tropism. This single amino acid change in the glycoprotein (F-->L at position 260) did not affect virus yield per macrophage but was critical in determining the number of macrophages infected. Our previous studies have shown that the same two mutations in the polymerase and glycoprotein are essential for establishing a chronic infection in adult mice. Since the same mutations confer macrophage tropism and ability to persist in vivo, these studies provide compelling evidence that infection of macrophages is a critical determinant of viral persistence and immune suppression.     

Collagens serve as an extracellular store of bioactive interleukin 2

The binding of certain growth factors and cytokines to components of the extracellular matrix can regulate their local availability and modulate their biological activities. We show that interleukin 2 (IL-2), an important stimulator of T cell growth, preferentially binds to collagen types I, III, and VI and to a lesser degree to collagen types II, IV, and V, immobilized on polystyrene or nitrocellulose. These interactions are inhibited by denatured, single collagen chains or a subset of their cyanogen bromide peptides in a dose-dependent manner. Cross-inhibition experiments and ligand blotting of collagen-derived peptides point to a limited set of collagenous consensus sequences mediating the binding of IL-2. This interaction is saturable, with dissociation constants of approximately 10(-)(8) m, and estimated molar ratios of 4-6 molecules of IL-2 bound to one molecule of triple helical collagen. Furthermore, collagen-bound IL-2 stimulates proliferation of mouse lymphocytes. We conclude that its specific binding to the abundant interstitial collagens leads to a spatial pattern of bioavailable IL-2 which is dictated by the local organization of the collagenous extracellular matrix. This interaction may contribute to the particular phenotype of stromal lymphocytes and could be exploited for devising collagenous peptide analogues that modulate IL-2 bioactivity.     

A surface plasmon resonance assay for measurement of neuraminidase inhibition,sensitivity of wild‐type influenza neuraminidase and its H274Y mutant to the antiviral drugs zanamivir and oseltamivir

Antiviral resistance is currently monitored by a labelled enzymatic assay, which can give inconsistent results because of the short half‐life of the labelled product, and variations in assay conditions. In this paper, we describe a competitive surface plasmon resonance (SPR) inhibition assay for measuring the sensitivities of wild‐type neuraminidase (WT NA) and the H274Y (histidine 274 tyrosine) NA mutant to antiviral drugs. The two NA isoforms were expressed in High‐five™ (Trichoplusia ni) insect cells. A spacer molecule (1,6‐hexanediamine (HDA)) was conjugated to the 7‐hydroxyl group of zanamivir, and the construct (HDA‐zanamivir) was immobilized onto a SPR sensor chip to obtain a final immobilization response of 431 response units. The immobilized HDA‐zanamivir comprised a bio‐specific ligand for the WT and mutant proteins. The effects of the natural substrate (sialic acid) and two inhibitors (zanamivir and oseltamivir) on NA binding to the immobilized ligand were studied. The processed SPR data was analysed to determine 50% inhibitory concentrations (IC_50‐spr), using a log dose–response curve fit. Although both NA isoforms had almost identical IC_50‐spr values for sialic acid (WT = 5.5 nM; H274Y mutant = 3.25 nM) and zanamivir (WT = 2.16 nM; H274Y mutant = 2.42 nM), there were significant differences between the IC_50‐spr values obtained for the WT (7.7 nM) and H274Y mutant (256 nM) NA in the presence of oseltamivir, indicating that oseltamivir has a reduced affinity for the H274Y mutant. The SPR inhibition assay strategy presented in this work could be applied for the rapid screening of newly emerging variants of NA for their sensitivity to antiviral drugs. Copyright © 2015 John Wiley & Sons, Ltd.     

A 16-Gene Signature Distinguishes Anaplastic Astrocytoma from Glioblastoma

Anaplastic astrocytoma (AA; Grade III) and glioblastoma (GBM; Grade IV) are diffusely infiltrating tumors and are called malignant astrocytomas. The treatment regimen and prognosis are distinctly different between anaplastic astrocytoma and glioblastoma patients. Although histopathology based current grading system is well accepted and largely reproducible, intratumoral histologic variations often lead to difficulties in classification of malignant astrocytoma samples. In order to obtain a more robust molecular classifier, we analysed RT-qPCR expression data of 175 differentially regulated genes across astrocytoma using Prediction Analysis of Microarrays (PAM) and found the most discriminatory 16-gene expression signature for the classification of anaplastic astrocytoma and glioblastoma. The 16-gene signature obtained in the training set was validated in the test set with diagnostic accuracy of 89%. Additionally, validation of the 16-gene signature in multiple independent cohorts revealed that the signature predicted anaplastic astrocytoma and glioblastoma samples with accuracy rates of 99%, 88%, and 92% in TCGA, {"type":"entrez-geo","attrs":{"text":"GSE1993","term_id":"1993"}}GSE1993 and {"type":"entrez-geo","attrs":{"text":"GSE4422","term_id":"4422"}}GSE4422 datasets, respectively. The protein-protein interaction network and pathway analysis suggested that the 16-genes of the signature identified epithelial-mesenchymal transition (EMT) pathway as the most differentially regulated pathway in glioblastoma compared to anaplastic astrocytoma. In addition to identifying 16 gene classification signature, we also demonstrated that genes involved in epithelial-mesenchymal transition may play an important role in distinguishing glioblastoma from anaplastic astrocytoma.