Establishment and characterization of a leukemic murine cell line derived from MCF 247 MuLV-induced T-cell lymphoma

Chromosome studies of murine T-cell lymphoid leukemia and derived cell lines

Several cell lines were previously established from a spontaneous murine T-cell leukemia (LB). The aim of this study was to analyze the G- and C-banded karyotypes of the parental LB tumor cells and the derived cell lines. A sensitive cell line (LBL) from which two sublines originated, as well as Vincristine (LBR-V160) and Doxorubicin (LBR-D160) resistant cell lines, were used. Our results showed that LB cells had a pseudo-diploid karyotype with 40 acrocentric chromosomes in which trisomy of chromosome 14 was the most relevant alteration. The sensitive cell line showed this alteration in all metaphases studied; no changes in karyotypes were observed in either subline, despite their dissimilar morphology and growth patterns. In contrast, both resistant lines displayed a more heterogeneous karyotype with no common markers, except for the finding that chromosome 5 was involved in a trisomy in LBR-V160 and in a translocation with chromosome 12 in LBR-D160. Taking into account that the mdr genes are located in chromosome 5, these results suggest a possible association between such alterations and the acquisition of drug resistance.

Bidirectional induction of the cognate receptor-ligand α4/VCAM-1 pair defines a novel mechanism of tumor intravasation

Engagement of cell surface adhesion receptors with extracellular constituents and with cellular counter-receptors is crucial for the extravasation of blood-borne neoplastic cells and their seeding at distant sites; however, the early events of tumor dissemination—ie, the intravasation step(s)—have been largely neglected. A role for the 4β7 integrin was hypothesized to explain the high leukemogenicity exhibited by one (NQ22) among several T-cell lymphomas studied. To clarify the mechanisms of early aggressivity, the behavior of highly and poorly leukemogenic cell lines were compared in vitro. Cocultivation of physically separated leukemic cells with resting endothelial cells resulted in the up-regulation of VCAM-1 expression. NQ22 cells expressed mRNA of different cytokines that up-regulate VCAM-1 and at higher levels than cells of a nonaggressive lymphoma, and they migrated more efficiently through an activated endothelial cell layer. With the use of neutralizing antibodies against interferon-γ, granulocyte macrophage colony-stimulating factor, and tumor necrosis factor (TNF)-, it was determined that TNF- is one of the soluble factors released by NQ22 cells involved in the up-regulation of VCAM-1. The finding that vascular cells within the early local growth were strongly positive for VCAM-1 indicated that NQ22 cells could activate endothelial cells also in vivo. Finally, cocultivation of preleukemic 4−NQ22 cells with TNF--activated endothelial cells induced the expression of 4 integrins on the former cells. Reciprocal up-regulation and engagement of 4/VCAM-1 pairs determined the sequential transmigration and intravasation steps, and similar mechanisms might affect the aggressivity of human T lymphoblastic lymphomas.

Bidirectional induction of the cognate receptor-ligand α4/VCAM-1 pair defines a novel mechanism of tumor intravasation

Engagement of cell surface adhesion receptors with extracellular constituents and with cellular counter-receptors is crucial for the extravasation of blood-borne neoplastic cells and their seeding at distant sites; however, the early events of tumor dissemination—ie, the intravasation step(s)—have been largely neglected. A role for the 4β7 integrin was hypothesized to explain the high leukemogenicity exhibited by one (NQ22) among several T-cell lymphomas studied. To clarify the mechanisms of early aggressivity, the behavior of highly and poorly leukemogenic cell lines were compared in vitro. Cocultivation of physically separated leukemic cells with resting endothelial cells resulted in the up-regulation of VCAM-1 expression. NQ22 cells expressed mRNA of different cytokines that up-regulate VCAM-1 and at higher levels than cells of a nonaggressive lymphoma, and they migrated more efficiently through an activated endothelial cell layer. With the use of neutralizing antibodies against interferon-γ, granulocyte macrophage colony-stimulating factor, and tumor necrosis factor (TNF)-, it was determined that TNF- is one of the soluble factors released by NQ22 cells involved in the up-regulation of VCAM-1. The finding that vascular cells within the early local growth were strongly positive for VCAM-1 indicated that NQ22 cells could activate endothelial cells also in vivo. Finally, cocultivation of preleukemic 4−NQ22 cells with TNF--activated endothelial cells induced the expression of 4 integrins on the former cells. Reciprocal up-regulation and engagement of 4/VCAM-1 pairs determined the sequential transmigration and intravasation steps, and similar mechanisms might affect the aggressivity of human T lymphoblastic lymphomas.

In vivo phenotypic characteristics of AKR T-cell lymphomas with different leukemic potential: possible role of alpha 4 beta 7 integrin in the progression towards the leukemic phenotype

The present study was undertaken in order to determine whether the expression of specific surface molecules which mediate immune recognition as well as cell-cell and cell-matrix interactions is associated with the leukemic evolution of T-cell lymphomas. To this end, we have investigated the in vivo phenotypic characteristics and the in vitro natural-killer(NK)-cell susceptibility of a group of MCF-247-induced AKR/J T-cell lymphomas with different leukemic potential. We found that in the AKR/J model, the biological aggressiveness of leukemic cells is not dependent upon an escape from host immune surveillance as a consequence of an in vivo down-regulation of H2-Kk determinants or a resistance to NK lysis. Moreover, NK susceptibility of AKR/J lymphomas does not seem to correlate with the level of H2-antigen expression. No obvious correlation was found between the leukemic phenotype and the amount of MEL-14, LFA-1, ICAM-1, Pgp-1/CD44 and THAM/CD26 antigen expression. An in vivo coordinated up-regulation of alpha 4 and beta 7 integrin chains, with the highest levels of expression detected in secondary sites of leukemic infiltration, was observed in the highly leukemic lymphoma NQ22 and, albeit to a lesser extent, in lymphomas with moderate leukemic potential. Conversely, non-leukemic lymphomas were repeatedly alpha 4- and beta 7-negative. These findings suggest that in the AKR/J system the expression of alpha 4 beta 7 integrin may contribute to leukemic spreading of T-cell lymphomas.

High-mobility-group (HMG) proteins and histone H1 subtypes expression in normal and tumor tissues of mouse

Exhaustive extraction of mouse tissues with perchloric acid has been used together with reverse-phase HPLC and electrophoresis to quantify the amounts of chromosomal proteins HMG17, HMG14 and HMGI, relative to histone H1. Normal lung and thymus contain approximately 3% HMG17/HMG14 but only approximately 2% HMGI. In tumor tissues (Lewis lung carcinoma and lymphoma NQ35), the amount of HMG17/HMG14 is not greatly altered but HMGI levels rise considerably, reaching 10% in Lewis lung carcinoma. HMGI synthesis does not replace HMG17/HMG14 proteins, suggesting that HMGI proteins contribute to the structure of chromatin regions in a manner distinct from those of HMG17/HMG14. Ion-spray mass spectrometry has been used to determine the molecular masses of H1 subtypes from the same four mouse tissues. In addition to the six known species H1 zero, H1a, H1b, H1c, H1d and H1e, a newly defined subtype of mass 21,756 Da from Lewis lung carcinoma, named H1L was identified. Several phosphorylated H1 subtypes have also been defined by mass spectrometry. The combined use of reverse-phase HPLC and electrophoresis permitted quantification of these seven histone H1 subtypes in the four mouse tissues. Increased phosphorylation of H1 subtypes in tumors parallels the phosphorylation of HMGI proteins which are present in great amounts, showing that both are involved as post-translational-modified forms in the structure of the chromatin of neoplastic systems.