Tsuyoshi Uchida

One molecule of diphtheria toxin fragment a introduced into a cell can kill the cell

Erythrocyte ghosts containing a known number of molecules of purified fragment A of diphtheria toxin with a constant amount of FITC-BSA as a fluorescence marker were prepared by dialyzing a mixture of erythrocytes and these substances against hypotonic solution. These substances were then introduced into diphtheria toxin-resistant mouse L cells by virus-mediated cell fusion of the cells with the ghosts, and mononuclear recipients that has fused with only one erythrocyte ghost were separated in a flourescence-activated cell sorter (FACS) on the basis of their cell size and fluorescence intensity. After separation, the viability of cells containing known numbers of fragment A was examined by measuring colony-forming ability. The results demonstrated that a single molecule of fragment A was sufficient to kill a cell. This fact was confirmed by introduction into cells of fragment A from an immunologically related mutant toxin, CRM 176 (fragment A176); this has a completely functional fragment B region, but in cell extracts, the enzymic activity of its fragment A is about 10 fold less than that of wild toxin. The cytotoxicity of CRM 176 is about two hundredths of that of the wild-type (Uchida, Pappenheimer and Greany, 1973). As expected, about 100-200 fold excess of fragment A-176 was needed to kill the cells.

Reversible inhibition of protein import into the nucleus by wheat germ agglutinin injected into cultured cells

The importance of glycoproteins located in the nuclear envelope in nuclear transport was tested by microinjection of karyophilic proteins into the cytoplasm of cultured human cells together with various lectins. Wheat germ agglutinin (WGA) blocked the nuclear transport of nucleoplasmin, a nuclear protein of Xenopus laevis oocytes, and of nonnuclear proteins conjugated with a synthetic peptide containing the nuclear localization signal sequence for simian virus 40 (SV40) large T antigen. Its inhibitory activity persisted for about 1 h after its injection into the cells and then gradually decreased. Export of at least some kinds of RNA from the nucleus seemed not to be affected by WGA even when import of the proteins into the nucleus was completely blocked (within 1 h after WGA injection). Moreover, WGA did not inhibit the passive diffusion of fluorescein isothiocyanate (FITC)-dextran (average Mr 17,900) into the nucleus. Wistaria floribunda agglutinin (WFA), concanavalin A (Con A), and lentil lectin did not block nuclear transport. These results indicate that WGA specifically blocks active protein import, but not passive diffusion of materials into the nucleus.

The improved efficient method for introducing macromolecules into cells using HVJ (Sendai virus) liposomes with gangliosides

Macromolecules such as DNA and RNA can be entrapped within liposomes associated with gangliosides by reverse-phase evaporation. When these liposomes are incubated with HVJ2 (Sendai virus), they deliver their contents into cultured cells efficiently. More than 95% cells of a Ltk- cell line (thymidine kinase-deficient cells) transiently expressed thymidine kinase activity by thymidine kinase gene transfer using HVJ liposomes with gangliosides. Stable transformants could be obtained efficiently from various cell lines by use of HVJ liposomes containing the neoR gene. The neo+ transformants were obtained at frequencies of about 0.2-1.0, 0.06-0.25, and 0.06-0.1% in monolayers of L, CHO-Kl, and HeLa-S3 cells, respectively. Moreover, in Ehrlich ascites tumor cells which grow in suspension, the frequency was more than 0.01%. On introduction of plasmid pTK4 into Ltk- cells, about 0.5-1.0% TK+ transformants were obtained. Cosmid DNA containing the neoR gene (about 45 kbp) was also introduced into L cells by this method and neo+ transformants were obtained at a frequency of 0.1%. When rat liver mRNA was introduced into L cells by HVJ liposomes with gangliosides, immunoprecipitation studies showed that the L cells secreted rat albumin and some other proteins into the cultured medium. Moreover, using erythrocyte membrane vesicles containing IgM that had been incubated with HVJ empty liposomes with gangliosides, the IgM could be introduced into all the L cells.

Efficient introduction of contents of liposomes into cells using HVJ (Sendai virus).

The conditions for efficient introduction of the contents of liposomes into cells were examined using fragment A of diphtheria toxin (DA) as a marker; one molecule of DA can kill a cell when introduced into the cytoplasm. Liposomes containing DA (DA liposomes) were toxic to cells treated with HVJ (Sendai virus) at 4 degrees C just before exposure to DA liposomes at 37 degrees C, but were not toxic to untreated cells. This toxicity was temperature-dependent. DA outside of liposomes was not toxic to HVJ-treated cells. Results also showed that liposomes could fuse with HVJ at 37 degrees but not at 4 degrees C and that liposomes preincubated with HVJ at 37 degrees C could associate with cells. DA liposomes preincubated with HVJ at 37 degrees C were highly toxic to cells. This toxicity was dependent on the duration of preincubation with HVJ and the dose of HVJ. When plasmid DNA coded herpes simplex virus thymidine kinase was trapped in liposomes and fused with Ltk- cells with HVJ, the thymidine kinase activity was expressed in about 10% of the cells. These data show that naked liposomes fuse efficiently with cells with HVJ and that the contents of the liposomes can be introduced into the cytoplasm 100-10 000 times more efficiently by treatment of the cells or liposomes with HVJ.

HVJ (Sendai virus)-induced envelope fusion and cell fusion are blocked by monoclonal anti-HN protein antibody that does not inhibit hemagglutination activity of HVJ

Abstract Two kinds of monoclonal antibodies against HN protein of HVJ were isolated. In competitive binding assay, binding of one of these antibodies to HN protein did not inhibit binding of the other antibody to the same molecule. One of the antibodies, named HN-1 antibody, inhibited hemagglutination activity of HVJ and also blocked neuraminidase activity of the virus when fetuin and Ehrlich ascites tumor cells were used as substrates, but it did not inhibit the activity when neuramine-lactose was used as substrate. The other antibody, HN-2, did not inhibit hemagglutination activity or neuraminidase activity, but blocked HVJ-induced viral envelope-cell fusion, cell-cell fusion and hemolysis. The mechanism by which HN-2 antibody blocked the fusion process is discussed.

Synthetic peptides containing a region of SV40 large T-antigen involved in nuclear localization direct the transport of proteins into the nucleus

We studied the mechanism of transport of proteins into the nucleus using synthetic peptides containing the nuclear location signal sequence of Simian virus 40 (SV 40) large T-antigen. When chick erythrocytes containing a synthetic large T-antigen nuclear translocation signal were fused with SV 40-transformed human fibroblasts, the migration of native large T-antigen into the chick nuclei was suppressed. Migration of proteins detected by human specific antinuclear autoimmune antibody was not blocked. An analog of the nuclear location signal peptide did not inhibit entry of large T-antigen into the chick nuclei. This result suggests that the peptide blocked the migration of only native large T-antigen into the nucleus, and that the signal of the majority of nuclear proteins for nuclear transport is not the same as that of the large T-antigen. The synthetic peptide was conjugated chemically with bovine serum albumin (BSA) and introduced into the cytoplasm of cultured human cells by red blood cell ghost-mediated microinjection. The BSA-synthetic peptide conjugate was found predominantly in the nucleus within 2 h after its introduction into the cells. BSA conjugated with the cross-linking reagent alone was not transported into the nucleus. Acetylated synthetic peptide was not effective in promoting nuclear localization of BSA. Mild trypsin treatment of the BSA-synthetic peptide conjugate suppressed nuclear localization. Conjugates of the synthetic peptide with phycoerythrin (Mr about 150 kD) and with secretory IgA (Mr about 380 kD) were both found in the nucleus very shortly after their introduction into the cytoplasm. These results suggest that the synthetic peptide containing the nuclear location signal sequence provides exogenous proteins with the ability to migrate into the nucleus. But, since a conjugate of the synthetic peptide with IgM (Mr about 940 kD) did not migrate into the nucleus after its microinjection, there may be a size limit in nuclear transport of conjugated proteins.

Neutralization of diphtheria toxin in living cells by microinjection of antifragment A contained within resealed erythrocyte ghosts

When human erythrocytes suspended in phosphate-buffered saline (PBS) containing lgG were first dialyzed against a hypotonic solution and then dialyzed against PBS, lgG molecules were entrapped within resealed erythrocyte ghosts. The concentration of lgG inside the ghosts was about 33% of its concentration in the dialysis bag. With the aid of HVJ (Sendai virus), ghosts containing rabbit lgG antibody against fragment A of diphtheria toxin were fused with toxin-sensitive FL cells. The fused FL recipients were found to be resistant to the action of diphtheria toxin. Clones derived from the resistant recipient cells, however, became sensitive to the toxin again. Antifragment A neutralized the enzymic activity of isolated fragment A in vitro, but did not protect FL cells or rabbit skin against the complete toxin.

A case of Fabry's disease in a patient with no α-galactosidase A activity caused by a single amino acid substitution of Pro-40 by Ser

We analyzed a male patient with Fabrys disease who had no activity of the lysosomal hydrolase α‐galactosidase A (α‐GalA) and female members of his family. We cloned a cDNA that encoded the mutant α‐GalA, determined its nucleotide sequence, and found two nucleotide differences between the mutant and the wild‐type cDNAs. Although one difference was silent, the other difference, a C‐to‐T transition at nucleotide number 118, resulted in an amino acid substitution of Pro‐40 by Ser. A transient expression assay demonstrated that this missense mutation was the cause of the deficiency of α‐GalA activity in the patient. In vitro mutagenesis experiments demonstrated that Pro‐40 is critical for the appearance ofa‐GalA activity.

Glycoproteins of Sendai virus (HVJ) have a critical ratio for fusion between virus envelopes and cell membranes

The biological activity of two glycoproteins, hemagglutinin and neuraminidase (HN) and fusion (F) proteins, of Sendai virus (HVJ) were studied using purified proteins. The proteins were purified by chromatography on DEAE and CM cellulose in the presence of Nonidet P-40 (NP40). The glycoproteins were reconstituted at various ratios of F to HN into lipid vesicles containing fragment A of diphtheria toxin. The association of HN and F proteins with the vesicles was confirmed by electron microscopy and sucrose density gradient centrifugation. The cytotoxic activity of vesicles containing fragment A on fusion with L cells was determined by measuring colony formation of the cells. It was found that for maximum cytotoxic activity of the vesicles, there was an optimal ratio of F to HN of two. This suggests that HN is not merely the initial binding site to the cell surface, and that interactions between HN and F proteins on the virus surface may be important for the biological activities of these proteins on the cells.

Macromolecules can penetrate the host cell membrane during the early period of incubation with HVJ (Sendai virus)

Abstract Fragment A of diphtheria toxin (MW 22,000) can penetrate the cell membrane during incubation with uv-inactivated HVJ. The amount of fragment A transfered to cells depends on the concentrations of both fragment A and HVJ. The penetration occurs most effectively during the early period of incubation at 37° (within 7 min) and the enhanced permeability of the cell membrane to macromolecules persists for at least 15 min at 37°. When uv-inactivated HVJ is adsorbed to erythrocyte ghosts containing fragment A, the HVJ virions released from the ghosts contain fragment A. These findings suggest that both the cell membrane and viral envelope become disordered during envelope-cell fusion.