immunocytochemical localization of urokinase-type plasminogen activator in lewis lung carcinoma

The invasively growing and metasizing Lewis lung carcinoma consistently contained urokinase-type plasminogen activator (u-PA) enzyme activity. When investigated immunocytochemically with antibodies against u-PA, different parts of individual tumors showed a pronounced heterogeneity in staining intensity. Strong staining was found in areas with invasive growth and degradation of surrounding normal tissue, while other areas were completely devoid of staining. Immunoreactivity occurred both with a perinuclear cytoplasmic localization in tumor cells and associated with apparently extracellular material. SDS PAGE of tumor extracts, under both reducing and nonreducing conditions, followed by immunoblotting, showed only one immunocytochemically stainable band with an electrophoretic mobility corresponding to that of purified proenzyme to u-PA, while no two-chain u-PA was detected. This indicates that the major part of the activator in Lewis lung carcinoma is present as one-chain pro-u-PA.     

Evolutionary history of the SARS-CoV-2 Gamma variant of concern (P.1): a perfect storm

Our goal was to describe in more detail the evolutionary history of Gamma and two derived lineages (P.1.1 and P.1.2), which are part of the arms race that SARS-CoV-2 wages with its host. A total of 4,977 sequences of the Gamma strain of SARS-CoV-2 from Brazil were analyzed. We detected 194 sites under positive selection in 12 genes/ORFs: Spike, N, M, E, ORF1a, ORF1b, ORF3, ORF6, ORF7a, ORF7b, ORF8, and ORF10. Some diagnostic sites for Gamma lacked a signature of positive selection in our study, but these were not fixed, apparently escaping the action of purifying selection. Our network analyses revealed branches leading to expanding haplotypes with sites under selection only detected when P.1.1 and P.1.2 were considered. The P.1.2 exclusive haplotype H_5 originated from a non-synonymous mutational step (H3509Y) in H_1 of ORF1a. The selected allele, 3509Y, represents an adaptive novelty involving ORF1a of P.1. Finally, we discuss how phenomena such as epistasis and antagonistic pleiotropy could limit the emergence of new alleles (and combinations thereof) in SARS-COV-2 lineages, maintaining infectivity in humans, while providing rapid response capabilities to face the arms race triggered by host immuneresponses.     

An association between the acute phase response and patterns of antigen induced T cell proliferation in juvenile idiopathic arthritis

The aim of this research was to determine whether all memory T cells have the same propensity to migrate to the joint in patients with juvenile idiopathic arthritis. Paired synovial fluid and peripheral blood mononuclear cell proliferative responses to a panel of antigens were measured and the results correlated with a detailed set of laboratory and clinical data from 39 patients with juvenile idiopathic arthritis. Two distinct patterns of proliferative response were found in the majority of patients: a diverse pattern, in which synovial fluid responses were greater than peripheral blood responses for all antigens tested; and a restricted pattern, in which peripheral blood responses to some antigens were more vigorous than those in the synovial fluid compartment. The diverse pattern was generally found in patients with a high acute phase response, whereas patients without elevated acute phase proteins were more likely to demonstrate a restricted pattern. We propose that an association between the synovial fluid T cell repertoire and the acute phase response suggests that proinflammatory cytokines may influence recruitment of memory T cells to an inflammatory site, independent of their antigen specificity. Additionally, increased responses to enteric bacteria and the presence of αEβ7 T cells in synovial fluid may reflect accumulation of gut associated T cells in the synovial compartment, even in the absence of an elevated acute phase response. This is the first report of an association between the acute phase response and the T cell population recruited to an inflammatory site.     

Leptin activation of mTOR pathway in intestinal epithelial cell triggers lipid droplet formation,cytokine production and increased cell proliferation

Accumulating evidence suggests that obesity and enhanced inflammatory reactions are predisposing conditions for developing colon cancer. Obesity is associated with high levels of circulating leptin. Leptin is an adipocytokine that is secreted by adipose tissue and modulates immune response and inflammation. Lipid droplets (LD) are organelles involved in lipid metabolism and production of inflammatory mediators, and increased numbers of LD were observed in human colon cancer. Leptin induces the formation of LD in macrophages in a PI3K/mTOR pathway-dependent manner. Moreover, the mTOR is a serine/threonine kinase that plays a key role in cellular growth and is frequently altered in tumors. We therefore investigated the role of leptin in the modulation of mTOR pathway and regulation of lipid metabolism and inflammatory phenotype in intestinal epithelial cells (IEC-6 cells). We show that leptin promotes a dose- and time-dependent enhancement of LD formation. The biogenesis of LD was accompanied by enhanced CXCL1/CINC-1, CCL2/MCP-1 and TGF-β production and increased COX-2 expression in these cells. We demonstrated that leptin-induced increased phosphorylation of STAT3 and AKT and a dose and time-dependent mTORC activation with enhanced phosphorilation of the downstream protein P70S6K protein. Pre-treatment with rapamycin significantly inhibited leptin effects in LD formation, COX-2 and TGF-β production in IEC-6 cells. Moreover, leptin was able to stimulate the proliferation of epithelial cells on a mTOR-dependent manner. We conclude that leptin regulates lipid metabolism, cytokine production and proliferation of intestinal cells through a mechanism largely dependent on activation of the mTOR pathway, thus suggesting that leptin-induced mTOR activation may contribute to the obesity-related enhanced susceptibility to colon carcinoma.     

The Plant Cell Surface

Multicellular organization and tissue construction has evolved along essentially different lines in plants and animals. Since plants do not run away, but are anchored in the soil, their tissues are more or less firm and stiff. This strength stems     

beta-Catenin has sequential roles in the survival and specification of ventral dermis

The dermis promotes the development and maintains the functional components of skin, such as hair follicles, sweat glands, nerves and blood vessels. The dermis is also crucial for wound healing and homeostasis of the skin. The dermis originates from the somites, the lateral plate mesoderm and the cranial neural crest. Despite the importance of the dermis in the structural and functional integrity of the skin, genetic analysis of dermal development in different parts of the embryo is incomplete. The signaling requirements for ventral dermal cell development have not been established in either the chick or the mammalian embryo. We have shown previously that Wnt signaling specifies the dorsal dermis from the somites. In this study, we demonstrate that Wnt/beta-catenin signaling is necessary for the survival of early ventral dermal progenitors. In addition, we show that, at later stages, Wnt/beta-catenin signaling is sufficient for ventral dermal cell specification. Consistent with the different origins of dorsal and ventral dermal cells, our results demonstrate both conserved and divergent roles of beta-catenin/Wnt signaling in dermal development.     

Locomotory behavior, contact inhibition, and pattern formation of 3T3 and polyoma virus-transformed 3T3 cells in culture

The social behavior of 3T3 cells and their polynoma virus-transformed derivative (Py3T3 cells) was examined by time-lapse cinemicrography in order to determine what factors are responsible for the marked differences in the patterns formed by the two cell lines in culture. Contrary to expectations, both cell types have been found to exhibit contact inhibition of cell locomotion. Therefore, the tendency of 3T3 cells to form monolayers and of Py3T3 cells to form crisscrossed multilayers cannot be explained on the basis of the presence versus the absence of contact inhibition. Morevover, with the exception of cell division control, the social behavior of the two cell types is qualitively similar. Both exhibit cell underlapping and, after contact between lamelliopodia, both show inhibition of locomotory activity and adhesion formation. Neither cell type was observed to migrate over the surface of another cell. The two cell types do show quantitative differences in the frequency of underlapping, the frequency with which contact results in inhibition of locomotion, and the proportion of the cell margin that adheres to the substratum. The increased frequency pf Py3T3 underlapping is correlated with the reduced frequency of substratum adhesions, which in turn favors underlapping. On the basis of these observations, it is concluded that the differences in culture patterns are the result of differences in the shapes of the individual cells, such that underlapping, and hence crisscrossing, is favored in Py3T3 cell interactions and discouraged in 3T3 cells.     

A Forward Genetic Strategy Reveals Destabilizing Mutations in the Ebolavirus Glycoprotein That Alter Its Protease Dependence during Cell Entry

Ebolavirus (EBOV) entry into cells requires proteolytic disassembly of the viral glycoprotein, GP. This proteolytic processing, unusually extensive for an enveloped virus entry protein, is mediated by cysteine cathepsins, a family of endosomal/lysosomal proteases. Previous work has shown that cleavage of GP by cathepsin B (CatB) is specifically required to generate a critical entry intermediate. The functions of this intermediate are not well understood. We used a forward genetic strategy to investigate this CatB-dependent step. Specifically, we generated a replication-competent recombinant vesicular stomatitis virus bearing EBOV GP as its sole entry glycoprotein and used it to select viral mutants resistant to a CatB inhibitor. We obtained mutations at six amino acid positions in GP that independently confer complete resistance. All of the mutations reside at or near the GP1-GP2 intersubunit interface in the membrane-proximal base of the prefusion GP trimer. This region forms a part of the “clamp” that holds the fusion subunit GP2 in its metastable prefusion conformation. Biochemical studies suggest that most of the mutations confer CatB independence not by altering specific cleavage sites in GP but rather by inducing conformational rearrangements in the prefusion GP trimer that dramatically enhance its susceptibility to proteolysis. The remaining mutants did not show the preceding behavior, indicating the existence of multiple mechanisms for acquiring CatB independence during entry. Altogether, our findings suggest that CatB cleavage is required to facilitate the triggering of viral membrane fusion by destabilizing the prefusion conformation of EBOV GP.Filoviruses are enveloped, filamentous, nonsegmented negative-sense RNA viruses that can cause a deadly hemorrhagic fever with case fatality rates in excess of 90% (see references 4, 20, and 37 for recent reviews). All known filoviruses belong to one of two genera: Ebolavirus (EBOV), consisting of the five species Zaire (ZEBOV), Côte d''Ivoire, Sudan, Reston, and Bundibugyo (tentative); and Marburgvirus, consisting of the single Lake Victoria species (21, 62).Cell entry by filoviruses is mediated by their envelope glycoprotein, GP (60, 68). Mature GP is a trimer of three disulfide-linked GP1-GP2 heterodimers. GP1 and GP2 are generated by endoproteolytic cleavage of the GP0 precursor polypeptide by a furin-like protease during transport to the cell surface (31, 39, 63, 69). The membrane-distal subunit, GP1, mediates viral adhesion to host cells (10, 18, 38, 42, 56, 59) and regulates the activity of the transmembrane subunit, GP2, which catalyzes fusion of viral and cellular membrane bilayers (30, 39, 41, 64, 65). The consequence of membrane fusion is cytoplasmic delivery of the viral nucleocapsid cargo.Lee et al. (39) recently solved the crystal structure of a ZEBOV GP prefusion trimer lacking the heavily glycosylated GP1 mucin domain (Muc) and the GP2 transmembrane domain (see Fig. ​Fig.5).5). The three GP1 subunits together form a bowl-like structure encircled by sequences from the three GP2 subunits. The trimer is held together by GP1-GP2 and GP2-GP2 contacts; the hydrophobic GP2 fusion loop packs against the external surface of adjacent GP1 subunits, and each GP2 subunit contributes a strand to a trimeric α-helical coiled-coil stem. GP1 is organized into three subdomains. The base is intimately associated with GP2 and clamps it in its prefusion conformation. The head is proposed to mediate virus receptor binding during entry (10, 18, 38, 42). The glycan cap resides at the top of the trimer and is critical for GP assembly but must be removed during entry (see below) (31, 42). The base and glycan cap are connected by the β13-β14 loop, which was not visualized in the structure. The location and structure of the Muc domain are also unknown, but it is proposed to sheathe the top and/or sides of the prefusion GP trimer (39). Muc is dispensable for ZEBOV GP-dependent entry in tissue culture but may play roles in virus-cell adhesion and immune evasion in vivo (31, 42, 44, 56, 59).Open in a separate windowFIG. 5.CA074^R mutations localize at or near the GP1-GP2 interface in the GP prefusion crystal structure. In all diagrams, GP1 is depicted in blue, GP2 in red, GP1 CA074^R mutations in green, and GP2 CA074^R mutations in yellow. (A) Linear representation of the amino acid sequence of GPΔMuc. S-S indicates the intersubunit disulfide bond between C53 and C609. sp, signal peptide; fl, fusion loop; hr1 and hr2, heptad repeats; tm, transmembrane domain; N, N terminus; C, C terminus. (B) Structure of GP in a prefusion conformation (39). Cartoon representation of a GP1-GP2 monomer is shown. Remaining subunits are shown as a surface-shaded watermark. The boxed inset contains the membrane-proximal base of the trimer, in which the CA074^R mutations are located. The β13-β14 loop is modeled as a chain of blue circles. (C) Magnified view of the inset shown in panel B rotated by 90°. The side chains of D47, I584, K588, and their contacting residues are shown. Dashed pink lines connect atoms from different side chains separated by ≤3.9 Å. Other CA074^R residues are not shown for clarity. (D) View shown in panel C rotated by 90°. (E) Schematic diagram of the potential interactions made by residues mutated in the CA074^R viruses. Residues approaching ≤3.9 Å to each CA074^R residue are shown. Beige arcs, hydrophobic interactions; dashed lines, potential ionic interactions. Visualizations of the GP structures shown in panels B to D (Protein Data Bank accession no. 3CSY) were rendered in Pymol (Delano Scientific).Crystal structures of ZEBOV GP2 in its postfusion conformation indicate that filovirus GP is a “class I” viral membrane fusion protein (41, 65). Like the prototypic class I fusion proteins of human immunodeficiency virus and influenza virus, GP2 contains a hydrophobic fusion peptide near its N terminus and N- and C-terminal α-helical heptad repeat sequences (HR1 and HR2, respectively) (22, 28, 30, 39, 41, 64, 65, 67) (see Fig. ​Fig.5).5). GP2 drives membrane fusion by undergoing large-scale conformational changes; the prefusion HR1 helix-loop-helix rearranges to an unbroken α-helix, projecting the fusion loop into the endosomal membrane, and GP2 jackknifes on itself to form a hairpin-like structure in which the HR2s pack against grooves in the trimeric HR1 coiled coil (41, 65).The available GP structures make clear that the transition of GP2 from prefusion to postfusion conformation requires its release from its binding groove in the GP1 base subdomain. For all known class I fusion proteins, this transition is controlled by priming and triggering events. Priming typically involves a single endoproteolytic cleavage of the glycoprotein mediated by a cellular protease within the secretory pathway of the virus-producer cells (e.g., human immunodeficiency virus ENV → SU + TM by furin [27]). This cleavage is essential because it liberates an N-terminal fusion peptide and allows the glycoprotein to rearrange during fusion. Unusually for a class I fusion glycoprotein, however, ZEBOV GP does not require cleavage to GP1 and GP2 by a furin-like protease, even though this cleavage occurs efficiently (46, 69). Instead, the GP trimer is primed by extensive proteolytic remodeling during entry. This process is mediated by cysteine cathepsins, a class of papain superfamily cysteine proteases active within the cellular endosomal/lysosomal pathway (14, 54).The cysteine cathepsins B (CatB) and L (CatL) play essential and accessory roles, respectively, in ZEBOV entry into Vero cells (14). The functions of these enzymes in viral entry can be recapitulated in vitro. Incubation of vesicular stomatitis virus (VSV) pseudotypes bearing ZEBOV GP (VSV-GP) with a mixture of purified human CatL and CatB, or with the bacterial protease thermolysin (THL), results in the cleavage and removal of GP1 Muc and glycan cap sequences, leaving a stable ∼17-kDa N-terminal GP1 fragment and intact GP2 (see Fig. ​Fig.5)5) (18, 54). VSV particles containing this GP_17K intermediate no longer require CatB activity within cells, strongly suggesting that this protease plays a critical role in generating a related primed species during viral entry (54). Strikingly, incubation of VSV-GP with CatL alone (14, 54) or with bovine chymotrypsin (CHT) (this study) (Fig. ​(Fig.1;1; see also Fig. ​Fig.7)7) generates a similar but distinct GP_18K intermediate (containing a slightly larger ∼18-kDa GP1 fragment) that cannot bypass the requirement for CatB during entry. Therefore, the removal of a few residues from GP_18K by CatB is crucial for viral entry. The reason for this requirement is unknown. Finally, VSV-GP_17K particles cannot infect cells completely devoid of cysteine cathepsin activity, indicating the existence of at least one additional cysteine protease-dependent step during entry (34, 54; present study). The signal that acts on a fully primed GP intermediate to trigger membrane fusion remains unknown.Open in a separate windowFIG. 1.CatB activity is required for entry of ZEBOV GP-dependent entry, whereas CatL activity is dispensable. Vero cells were pretreated for 4 h with 1% (vol/vol) DMSO (vehicle), 0.5 μM FYdmk (CatL-selective inhibitor), 80 μM CA074 (CatB-selective inhibitor), 0.5 μM FYdmk plus 80 μM CA074, or 300 μM E64 (pan-cysteine cathepsin inhibitor). (A) The cells were then challenged with VSV-GPΔMuc, CHT-derived VSV-GP_18K (CHT-GP_18K), THL-derived VSV-GP_17K (THL-GP_17K), or VSV-G pseudotypes at a low MOI (0.02 to 0.1 eGFP-positive infectious units [iu] per cell) in the presence of drug, and viral titers (iu/ml) were determined at 18 h postinfection. CatB and CatL activities in extracts prepared from a parallel set of pretreated cells were measured by fluorogenic peptide turnover and are shown (bottom). Averages ± standard deviations (SD) for six trials from three independent experiments are shown. CatL activity below the detection threshold is indicated as zero without an accompanying SD. (B) Vero cells pretreated with protease inhibitors were challenged with VSV-GPΔMuc, cathepsin L-derived VSV-GP_18K (CatL-GP_18K), or cathepsin B-derived VSV-GP_17K (CatB-GP_17K), and viral infectivity was measured as described above. Averages ± SD for three trials from a representative experiment are shown.Open in a separate windowFIG. 7.rVSV-GPΔMuc mutants resemble the WT in cleavage to GP_18K and GP_17K intermediates. WT or mutant rVSV-GPΔMuc was incubated with the indicated protease(s) as described in Materials and Methods and then deglycosylated with PNGaseF (except for N40K and T42A, which lack the N40 glycan and do not require deglycosylation at this position). The resulting GP1 proteolytic fragments were resolved by SDS-PAGE and detected by Western blotting. Shorter protease incubation times were necessary to obtain cleavage intermediates for some mutants (see text for details). Positions of uncleaved GP1 and the ∼18-kDa and ∼17-kDa cleavage fragments are indicated on the left. *, partially cleaved GP fragment of unknown composition. Experimental samples shown on each gel (bold labels) were flanked by WT samples cleaved with CHT (WT 18K) or THL (WT 17K) to provide markers of band mobility.In this study, we used a forward genetic strategy to investigate the CatB-dependent step in ZEBOV entry. Specifically, we engineered and rescued a recombinant VSV (rVSV) encoding a mucin domain-deleted ZEBOV GP in place of the VSV glycoprotein G and used it to select viral mutants resistant to the CatB inhibitor CA074. Analysis of these viruses identified mutations in both GP1 and GP2 that allow CatB-independent cell entry. We found that GP_18K and/or GP_17K intermediates derived from some but not all of the mutant GPs are conformationally distinct from the wild type (WT), suggesting the existence of multiple mechanisms for CA074 resistance. Taken together, our results indicate that ZEBOV GP→GP_17K cleavage by CatB promotes fusion triggering and viral entry by destabilizing the prefusion conformation of GP.