Synergy between AUUUA motif disruption and enhancer insertion results in autocrine transformation of interleukin-3-dependent hematopoietic cells

Previously, we characterized the transposition of an intracisternal type A particle (IAP) to the 32 untranslated region (UTR) of the interleukin-3 (IL-3) gene, which displaced two of the six AUUUA motifs associated with mRNA stability in an IL-3-secreting clone. To determine whether this rearrangement was involved in the autocrine transformation of the parental IL-3-dependent FL5.12 cell line, the germline (gIL-3) and rearranged IL-3 (rIL-3) genes were isolated and subcloned into a gene transfer vector. Moreover, the IAP-long terminal repeat (LTR) and the IL-3 32 UTR AUUUA motifs were deleted (rIL-3 + delta LTR and gIL-3 + delta AUUUA) in some IL-3 constructs to ascertain their role in the transformation process. The IAP-LTR was also added to these constructs (rIL-3 + delta LTR + IAP-LTR, gIL-3 + delta AUUUA + IAP-LTR, and gIL-3 + IAP-LTR), to determine whether it was necessary for autocrine transformation. The ability of the modified IL-3 genes to abrogate the IL-3 dependency of FL5.12 cells had the following rank order: rIL-3 was greater than rIL-3 + delta LTR + IAP-LTR, which was greater than gIL-3 + delta AUUUA + IAP-LTR, which was greater than gIL-3 + delta AUUUA, which was equal to rIL-3 + delta LTR, which was greater than gIL-3. The half-life of IL-3 mRNA was 20-fold longer in cells containing a mutated as opposed to a wild-type AUUUA region. All of the factor-independent cells that expressed the IL-3 transgenes secreted IL-3 and were tumorigenic after injection into BALB/c nude mice. These results indicated that two events could synergize in the autocrine transformation of hematopoietic cells: (1) addition of a transcriptional enhancer present in a retroviral LTR, and (2) disruption of an mRNA stability region.

Synergy between AUUUA motif disruption and enhancer insertion results in autocrine transformation of interleukin-3-dependent hematopoietic cells

Previously, we characterized the transposition of an intracisternal type A particle (IAP) to the 32 untranslated region (UTR) of the interleukin-3 (IL-3) gene, which displaced two of the six AUUUA motifs associated with mRNA stability in an IL-3-secreting clone. To determine whether this rearrangement was involved in the autocrine transformation of the parental IL-3-dependent FL5.12 cell line, the germline (gIL-3) and rearranged IL-3 (rIL-3) genes were isolated and subcloned into a gene transfer vector. Moreover, the IAP-long terminal repeat (LTR) and the IL-3 32 UTR AUUUA motifs were deleted (rIL-3 + delta LTR and gIL-3 + delta AUUUA) in some IL-3 constructs to ascertain their role in the transformation process. The IAP-LTR was also added to these constructs (rIL-3 + delta LTR + IAP-LTR, gIL-3 + delta AUUUA + IAP-LTR, and gIL-3 + IAP-LTR), to determine whether it was necessary for autocrine transformation. The ability of the modified IL-3 genes to abrogate the IL-3 dependency of FL5.12 cells had the following rank order: rIL-3 was greater than rIL-3 + delta LTR + IAP-LTR, which was greater than gIL-3 + delta AUUUA + IAP-LTR, which was greater than gIL-3 + delta AUUUA, which was equal to rIL-3 + delta LTR, which was greater than gIL-3. The half-life of IL-3 mRNA was 20-fold longer in cells containing a mutated as opposed to a wild-type AUUUA region. All of the factor-independent cells that expressed the IL-3 transgenes secreted IL-3 and were tumorigenic after injection into BALB/c nude mice. These results indicated that two events could synergize in the autocrine transformation of hematopoietic cells: (1) addition of a transcriptional enhancer present in a retroviral LTR, and (2) disruption of an mRNA stability region.

Intracellular retention of membrane-anchored v-sis protein abrogates autocrine signal transduction.

An important question regarding autocrine transformation by v-sis is whether intracellularly activated PDGF receptors are sufficient to transform cells or whether activated receptor-ligand complexes are required at the cell surface. We have addressed this question by inhibiting cell surface transport of a membrane-anchored v-sis protein utilizing the ER retention signal of the adenoviral transmembrane protein E3/19K. A v-sis fusion protein containing this signal was retained within the cell and not transported to the cell surface as confirmed by immunofluorescent localization experiments. Also, proteolytic maturation of this protein was suppressed, indicating inefficient transport to post-Golgi compartments of the secretory pathway. When compared with v-sis proteins lacking a functional retention signal, the ER-retained protein showed a diminished ability to transform NIH 3T3 cells, as measured by the number and size of foci formed. In newly established cell lines, the ER-retained protein did not down-regulate PDGF receptors. However, continued passage of these cells selected for a fully transformed phenotype exhibiting downregulated PDGF receptors and proteolytically processed v-sis protein. These results indicate that productive autocrine interactions occur in a post-ER compartment of the secretory pathway. Transport of v-sis protein beyond the Golgi correlated with acquisition of the transformed phenotype. Furthermore, suramin treatment reversed transformation and upregulated the expression of cell surface PDGF receptors, suggesting an important role for receptor-ligand complexes localized to the cell surface.