The cell cycle dependence of thermotolerance. III. HeLa cells heated at 45.0 degrees C

We have extended our studies on the cell cycle dependence of thermotolerance to include HeLa cells heated at 45.0 degrees C to compare the results to Chinese hamster ovary (CHO) cells. We found that asynchronous HeLa cells were more resistant to heat than CHO cells but showed a similar development and decay of thermotolerance. Flow cytometry (FCM) was used to study redistributions in the cell cycle after an initial heat dose. Cells heated for 35 min at 45.0 degrees C were delayed in G1 by about 7 h compared to controls, with delays in late S and G2/M phase also. The heat sensitivity varied through the cell cycle; G1 cells were the most resistant to heat, while S-phase cells were uniformly sensitive throughout S phase, and G2 cells were resistant. Thermotolerance could be induced and expressed in early or late S-phase cells, but to a lesser extent than for G1 cells. The results were similar in many respects to CHO cells, but there were significant differences.     

The localization and rate of disappearance of a synaptic vesicle antigen following denervation

Summary A proteoglycan-specific antiserum has been used to monitor the effects of denervation in the electric organ of Torpedo marmorata. The antiserum was produced by injecting a highly purified synaptic vesicle fraction prepared from the electric organs of Torpedo marmorata. Following absorption the serum appears to be specific towards synaptic vesicles. The ultrastructural localization of the antigen determined by immuno-electron microscopy confirmed the specificity of the antiserum and showed that it did not crossreact with the proteoglycans of the basal lamina. The rate of disappearance of the vesicle proteoglycans following denervation was evaluated by means of the antiserum and was compared to the rate of disappearance of other vesicular and nerve terminal-associated markers. The results suggest that degeneration affects the vesicular constituents at varying rates resulting in a progressive disappearance of the entire functional capacity of the synaptic vesicles.     

Investigations into the sequence-selective binding of mithramycin and related ligands to DNA.

The preferred binding sites for mithramycin on four different DNA fragments have been investigated by DNAase I footprinting. Sites containing at least two contiguous GC base pairs are protected by the antibiotic, the preferred binding site consisting of the dinucleotide step GpG (or CpC). Related antibiotics chromomycin and olivomycin produce similar, but not identical footprinting patterns suggesting that they can recognize other sequences as well. All three antibiotics induce enhanced rates of enzyme cleavage at regions flanking some of their binding sites. These effects are generally observed in runs of A and T and are attributed to DNA structural variations induced in the vicinity of the ligand binding site. The reaction of dimethylsulphate with N7 of guanine was modified by the presence of mithramycin so that we cannot exclude the possibility that these antibiotics bind to DNA via the major groove.     

DNA repair, DNA synthesis and cell cycle delay in human lymphoblastoid cells differentially sensitive to the cytotoxic effects of nitrogen mustard

Two cloned human lymphoblastoid cell lines, Raji and TK6, differ in their sensitivity to the cytotoxic effects of nitrogen mustard (HN2). Raji cells exhibit a biphasic response with an initial D value of 0.06 microgram/ml and a final slope of 0.25 microgram/ml. TK6 cells were considerably more sensitive, D0 value 0.02 microgram/ml. Dose-response relationships for delay in cell cycle progression were measured using flow cytometry. Delay in S-phase traverse was concentration-dependent in both cell lines, and at a given concentration was 2-fold greater in TK6 than in Raji. Numbers of crosslinks (determined by alkaline elution) increased linearly with increasing HN2 concentration and were approximately 2-fold higher in TK6 than in Raji. At equal levels of DNA crosslinks, rates of removal were similar in both cell lines. Inhibition of [3H]TdR uptake was concentration-dependent and the extent of inhibition was similar in both cell lines. Recovery from HN2-induced inhibition of cell cycle progression markedly preceded recovery from inhibition of [3H]TdR incorporation suggesting that nucleotide pools are markedly perturbed in HN2-treated cells. The difference in sensitivity of these two cell lines cannot be adequately explained by differences in amounts of initial DNA damage, rates of repair, differential S-phase delay or rate of loss of DNA crosslinks.     

Two new monoclonal antibodies (LN-1, LN-2) reactive in B5 formalin-fixed, paraffin-embedded tissues with follicular center and mantle zone human B lymphocytes and derived tumors

Two monoclonal antibodies (LN-1, LN-2) reactive with B lymphocytes in B5 formalin-fixed, paraffin-embedded tissue sections have been produced by utilizing cell extracts from pokeweed mitogen-stimulated peripheral blood lymphocytes and diffuse histiocytic lymphoma SU-DHL-4 cells, respectively. Both monoclonal antibodies were initially identified by indirect immunofluorescence screening techniques on paraformaldehyde-acetone-fixed cell preparations. Specificity screens with 36 well-characterized human lymphoma and leukemia cell lines showed that both LN-1 and LN-2 stained cell lines of B cell lineage but were unreactive with those of T cell or, with one exception, myeloid derivation. Null cell acute lymphoblastic leukemia cell lines were found to be LN-2+ but LN-1-. The B cell specificity of these reagents was confirmed on 15 lymphoma and 17 leukemia biopsy specimens by using indirect immunofluorescence techniques. Immunoperoxidase staining of sections from B5-fixed, paraffin-embedded human lymphoid tissues showed that LN-1 bound to the cell membrane and cytoplasm of germinal center cells whereas LN-2 stained the nuclear membrane and cytoplasm of germinal center and mantle zone B lymphocytes as well as interfollicular histiocytes and thymic medullary dendritic cells. Both monoclonal antibodies failed to stain cortical thymocytes, lymph node T cells, and peripheral blood T and myeloid cells. Immunoperoxidase staining of 20 nonlymphoid human organs and tissues revealed that LN-1 reacted positively with red blood cell precursors of the bone marrow, ciliated epithelial cells of the bronchus, distal tubular cells of the kidney, and ductal cells from several organs including the breast and prostate. In contrast, LN-2 was unreactive with all human nonlymphoid organs and tissues including the bone marrow. Indirect immunofluorescence staining of a panel of 26 solid tumor cells lines showed that LN-1 was reactive with the majority of epithelium-derived cell lines, glioblastomas, and astrocytomas but was unreactive with neuroblastomas, small cell carcinoma of the lung, and sarcomas. LN-2 was unreactive with 25 of 26 of the solid tumor cell lines by these techniques. Immunobiochemical studies have shown that LN-1 recognizes a cell surface sialoantigen whereas LN-2 is directed against a 35,000 dalton nuclear membrane protein. Because of their high specificity for B cell tumors and their ability to stain B5-fixed, paraffin-embedded tissues, LN-1 and LN-2 are useful reagents for the diagnosis and classification of the human lymphomas and leukemias.     

Ta1, a novel 105 KD human T cell activation antigen defined by a monoclonal antibody

By using a murine monoclonal antibody produced against an IL 2-dependent human T cell line, we defined a T lineage-specific molecule, termed Ta1, that is expressed strongly on activated T lymphocytes of both the T4 and T8 subsets, as well as on T cell lines and clones, but only weakly on a fraction of resting T cells. SDS-PAGE analysis of immunoprecipitates from 125I-labeled, activated T cells demonstrates a single major band of apparent m.w. 105 KD under both reducing and nonreducing conditions. Unlike anti-IL 2 receptor antibodies, anti-Ta1 does not inhibit T cell proliferative responses to mitogen, antigen, or IL 2-containing medium. Moreover, anti-Ta1 has no effect on T cell-mediated cytotoxicity. Ta1 appears to be a novel human T cell-specific activation antigen that may serve as a useful marker of T cell activation in human disease.     

Cellular requirements for induction of human primary proliferative responses to trinitrophenyl-modified cells

Cellular requirements for induction of primary proliferative responses by human T cells to trinitrophenylated autologous stimulators have been characterized. Substantial proliferative responses were observed with each of the Ia+ stimulator populations tested. Nevertheless, major differences in the hapten specificity of such responses were observed. Thus purified macrophages/monocytes (M phi) when TNP-modified induced responses that were relatively modest in absolute magnitude, but were highly hapten specific. This reflected the very limited capacity of purified M phi to induce proliferation when unmodified, i.e., an autologous mixed leukocyte response (AMLR). In contrast, unmodified M phi-depleted B plus null cells were potent stimulators of AMLR, but hapten modification did not significantly enhance the responses induced by these cells. Moreover, when M phi were added to B plus null cell stimulators AMLR responses were reduced and, with TNP-modified stimulators, hapten-specific responses were restored. The data thus suggest that M phi may have important roles in induction of primary T cell responses to conventional antigens but function largely as regulators rather than stimulators of AMLR. Finally, we have introduced a novel antigen-presenting cell population, the irradiated Ia+ TNP-specific cloned T cell. The possibility that such cells may utilize autostimulatory positive feedback circuits for activation of naive T cells and in interactions between subpopulations of hapten-reactive T cells is discussed.