Vladimir M. Kushnaryov

Transport of γ-interferon into the cell nucleus may be mediated by nuclear membrane receptors

Abstract Purified mouse interferon gamma (MuIFN-γ), a lymphokine having potent antiviral, immunomodulatory, and growth inhibitory activities is internalized ( t 1 2 ) by mouse L929 fibroblasts via receptor-mediated endocytosis. Individual MuIFN-γ molecules, identified by a postembedding immuno-gold technique, are then transported to the cell nucleus, perhaps through nuclear pores, into areas of dense chromatin. Purified, isolated nuclei of L929 cells bind radiolabeled MuIFN-γ specifically and with high affinity (Kd = 2×10−10 M). These nuclear membrane receptors, distinct from those for MuIFN-β, number about 24,000/nucleus. Treatment of nuclei with trypsin prevents binding of MuIFN-γ. The demonstration of rapid cellular uptake and transport of MuIFN-γ into the dense chromatin, perhaps facilitated by nuclear receptors, suggests that IFN-γ molecules, alone or bound to receptor, may directly affect genome regulation.

Lanthanide ion enhancement of interferon binding to cells

Pretreatment of purified [125I]-labeled human and mouse beta interferons (IFN) with lanthanum chloride (LaCl3) enhanced 20-30 fold the binding of the [125I]-IFNs to human A549 and mouse L cells at 0 degree C and also enhanced antiviral activity in homologous cells. Although lanthanides enhanced cross-species binding of both human and mouse [125I]-IFNs, there was no increase in cross-species antiviral activity. Unlabeled IFN not treated with LaCl3 did not compete with [125I]-IFN treated with LaCl3 for cellular receptors. However, unlabeled IFN treated with LaCl3 did compete with LaCl3-treated [125I]-IFN. These results suggest that lanthanide treated IFNs do not bind to the same receptors as native IFNs.

The Use of Dimethylsulfoxide for Fixation of Yeasts for Electron Microscopy

Conventional methods of chemical fixation are often inadequate for preserving yeast ultrastructure. The thick cell wall severely limits penetration of fixatives rendering poor detail of the cell wall, membranes, and overall anatomy. Dimethylsulfoxide (DMSO) enhances penetration of chemicals and has been added to fixatives to improve cell preservation. At high concentrations (5 to 50%), however, it affects ultrastructure unpredictably. We found that adding 0.1% DMSO to fixatives greatly improved retention of yeast ultrastructure. Candida albicans, C. glabrata and Aspergillus fumigatus were fixed for 3 hr in 3% paraformaldehyde, 1% glutaraldehyde, 1 mM MgCl2, 1 mM CaCl2, 0.1% DMSO in 0.1 M sodium cacodylate buffer followed by 1% OsO4, 1% K2Cr2O7, 0.85% NaCl, 0.1% DMSO in the same buffer. Thin epoxy sections were post-stained in uranyl acetate and lead citrate. The multilayered character of the cell wall was distinct and well structured. Addition of ruthenium red or alcian blue to the fixatives further enhanced the outer fibrillar layer. The plasma membrane was contiguous and tightly adjacent to the inner mannoprotein layer of the cell wall. The cytoplasm was well preserved and the overall preservation of the yeast ultrastructure was significantly improved.

Electron Microscopy of Malachite Green— Glutaraldehyde Fixed Bacteria

Malachite green combined with glutaraldehyde has been used recently as a fixative for preserving and revaling lipid complexes in thin sections of eukaryotic cells examined by electron microscopy. When bacteria were prefixed with the above mixture granular electron dense inclusions were revealed in all cultures tested. These inclusions were replaced by electron transparent areas in cells fixed with glutaraldehyde alone. The structures were frequently located near to or within the nucleoid and adjacent to the cell membrane in Gram-negative bacteria and were associated with the nucleoid and mesosomes in Gram-positive species. Polyhydroxybutyrate granules, generally poorly preserved in thin sections of Aquaspirillum serpens, were well preserved by the malachite green-glutaraldehyde fixative. Malachite green complexes were observed outside of the cells in all preparations. Capsules were neither preserved nor stained.

Analysis of fluconazole effect on Candida albicans viability during extended incubations

Fluconazole is an azole agent with primarily fungistatic activity in standard in vitro susceptibility tests. However, recent work has demonstrated that this drug can reduce Candida albicans viability during prolonged incubations under non-growing conditions. The present study was undertaken to examine more closely some of the parameters of this killing activity. Fungicidal effects of 1.0 microg ml-1 of fluconazole were found during 7-14-day exposures in each of two media that prevented proliferation, distilled water and metal-depleted RPMI 1640 tissue-culture medium. Fluconazole appeared to be stable after being incubated at 37 degreesC for either 7 or 14 days. Strains of C. albicans resistant to fluconazole in standard short-term growth-inhibition assays were also found to be resistant to fluconazoles effect on viability in prolonged culture, suggesting similar mechanisms of action for these effects. C. albicans yeast cells pre-incubated for 7 days in distilled water were not more sensitive to the drug in short-term susceptibility assays. Although all proliferation of the organisms in distilled water cultures appeared to cease after 3 days, fluconazole added at 7 days still reduced C. albicans viability. Therefore, the drug appeared to kill the non-proliferating organisms directly rather than preventing growth and thereby the emergence of younger organisms that would live longer. Transmission electron microscopy demonstrated damage to the cell wall-cell membrane complex and interior contents of yeast cells incubated in distilled water alone; fluconazole appeared to increase the percentages of cells so affected. In summary, extended-incubation susceptibility tests demonstrated that fluconazole has direct fungicidal activity of non-proliferating C. albicans yeast cells. These results may be relevant to the manner in which this drug promotes clearance of chronic fungal infections.

A human B-lymphoblastoid cell line constitutively producing Epstein-Barr herpesvirus and JHK retrovirus

The human B-lymphoblastoid cell line, designated JHK-3, with pre-B-cell characteristics, chronically produces two viruses, Epstein-Barr virus (EBV) and JHK virus, an apparently novel retrovirus. The JHK-3 cells are much more productive of extracellular EBV than the high-producer marmoset line B95-8. The extracellular virus of the JHK-3 EBV strain is relatively fragile, more broadly dispersed in an ultracentrifuged sucrose gradient than the B95-8 EBV and more susceptible to disruption by combined treatment with urea and dithiothreitol. By restriction fragment length polymorphism analysis, the JHK-3 EBV strain resembles the EBV strain FF-41. The JHK-3 cells also produce an incompletely characterized, relatively fragile, enveloped, icosahedral RNA virus that contains Mn(++)-dependent reverse transcriptase. JHK virions measure 85 nm in ultrathin sections, much smaller than other Retroviridae. The JHK virus exhibits a distinctive morphogenesis, most nearly resembling C-type retroviruses. The JHK-3 cell line provides a human cell model for investigating virus/virus interactions and their pathogenetic affects on host cells which chronically and simultaneously produce DNA and RNA viruses.

The cellular internalization of recombinant gamma interferon differs from that of natural interferon gamma.

Purified natural and recombinant murine gamma interferons (MuIFN-gamma) bind at 4 degrees C to cultured L929 mouse fibroblasts with comparable receptor-binding affinity (Kd = 9 x 10(-10) M). Both 125I-labeled MuIFNs are rapidly internalized by cells at 37 degrees C, although recombinant IFN is internalized somewhat more slowly than natural IFN (t1/2 = 90 sec and 45 sec, respectively). Immunoelectronmicroscopy showed that the majority of bound recombinant MuIFN-gamma was located on the plasma membrane outside of coated areas, whereas natural interferon was found mainly in coated pits. At 37 degrees C most of the recombinant molecules entered the cytoplasm in pinocytotic vesicles, while natural interferon was internalized by the specific mechanism of receptor-mediated endocytosis [1]. However, nearly equal amounts of immunocytochemically detectable molecules of both IFNs were found in the cell nucleus within 2-3 min incubation at 37 degrees C. Thus, the process of translocation of the recombinant IFN-gamma appears to differ from that of the natural product.

Diphtheria toxin induces leakage of acidic liposomes.

Diphtheria toxin (DT) induces the leakage of dipalmitoylphosphatidic acid (DPPA) membranes but not neutral dipalmitoylphosphatidylcholine (DPPC) membranes. Cholesterol incorporated into liposomes enhances the membrane leakage induced by DT in acidic DPPA membranes but not in neutral DPPC membranes. Membrane leakage was determined by assaying the release of TEMPOcholine, a cationic spin probe from the multilamellar vesicles by using electron spin resonance methods. The effect of DT on membrane leakage is noticeable at 3 micrograms/ml concentrations, and reaches a plateau of about 20% leakage at 20 micrograms/ml. This saturation phenomenon led to the postulation that DT binds to the first shell of DPPA membranes and induces the leakage of TEMPOcholine limited to this layer of DPPA multimellar vesicles.

Ruthenium Red Preserves Glycoprotein Peplomers of C-Type Retroviruses for Transmission Electron Microscopy

Peplomers, the glycoprotein projections of the outer viral envelope, are distinctive for many viruses. Peplomers of retroviral C-type particles are fragile and are not preserved in standard preparations for transmission electron microscopy of thin sections, whereas the peplomers of B- and D- type retroviruses are usually preserved. Ruthenium red, extensively used in transmission electron microscopy to enhance the preservation of glycosylated proteins, was used in the preparation of three retrovirus-producing lymphoblastoid cell lines: murine SC-1 cells producing the C-type murine leukemia retrovirus LP-BM5 that causes immunodeficiency, human DG-75 cells producing a murine leukemia retrovirus, and human C5/MJ cells producing human T-cell lymphotropic virus type I (HTLV-I). Fixation of cells was carried out with ruthenium red present in the glutaraldehyde, osmium tetroxide, and the ethanol dehydration through the 70% ethanol step. The detailed structure of peplomers of these three different viruses was well preserved.

Nuclear Localization of Internalized Interferons-β and -γ: A Role for Nuclear Receptors

The mechanism by which IFN treatment alters gene expression remains unknown, although IFN binding to plasma membrane receptors appears to be a crucial step in processing (1), This binding has been thought to be sufficient to trigger intracellular activities by still unidentified transmembrane signals or messengers. Recent reports indicate that newly induced RNA transcripts can appear within several minutes after the cells are treated with IFN (2 – 5). Since different lines of evidence indicate that IFN molecules are transported into the nucleus within a few minutes by facilitated receptor-mediated endocytosis (6,7), IFNs may act as their own messengers, alone or in combination with their receptors.