ASSEMBLY AND FUNCTION OF A TCR-ALPHA ENHANCER COMPLEX IS DEPENDENT ON LEF-1-INDUCED DNA BENDING AND MULTIPLE PROTEIN-PROTEIN INTERACTIONS

被引：491

作者：

GIESE, K

KINGSLEY, C

KIRSHNER, JR

GROSSCHEDL, R

机构：

[1] UNIV CALIF SAN FRANCISCO,DEPT MICROBIOL,HOWARD HUGHES MED INST,SAN FRANCISCO,CA 94143

[2] UNIV CALIF SAN FRANCISCO,DEPT BIOCHEM,SAN FRANCISCO,CA 94143

来源：

GENES & DEVELOPMENT | 1995年 / 9卷 / 08期

关键词：

LEF-1; PEBP2-ALPHA; ETS-1; TCR-ALPHA ENHANCER; DNA BENDING;

D O I：

10.1101/gad.9.8.995

中图分类号：

Q2 [细胞生物学];

学科分类号：

071009 ; 090102 ;

摘要：

In this study we examine the molecular basis for the synergistic regulation of the minimal TCR alpha enhancer by multiple proteins. We find that reconstitution of TCR alpha enhancer function in nonlymphoid cells requires expression of the lymphoid-specific proteins LEF-1, Ets-1 and PEBP2 alpha (CBF alpha), and a specific arrangement of their binding sites in the enhancer. We show that Ets-1 cooperates with PEBP2 alpha to bind adjacent sites at one end of the enhancer, forming a ternary complex that is unstable by itself. Stable occupancy of the Ets-1- and PEBP2 alpha-binding sites in a DNase I protection assay was found to depend on both a specific helical phasing relationship with a nonadjacent ATE/CREB-binding site at the other end of the enhancer and on LEF-1. The HMG domain of LEF-1 was found previously to bend the DNA helix in the center of the TCR alpha enhancer. We now show that the HMG domain of the distantly related SRY protein, which also bends DNA, can partially replace LEF-1 in stimulating enhancer function in transfection assays. Taken together with the observation that Ets-1 and members of the ATP/CREB family have the potential to associate in vitro, these data suggest that LEF-1 can coordinate the assembly of a specific higher-order enhancer complex by facilitating interactions between proteins bound at nonadjacent sites.

引用

页码：995 / 1008

页数：14

共 73 条

[21] Gunther C., Graves B., Identification of ETS domain proteins in murine T lymphocytes that interact with the moloney murine leukemia virus enhancer, Mol. Cell. Biol., 14, pp. 7569-7580, (1994)
[22] Hai T., Liu F., Coukos W., Green M., Transcription factor ATF cDNA clones: An extensive family of leucine zipper proteins able to selectively form DNA binding heterodimers, Genes & Dev., 3, pp. 2083-2090, (1990)
[23] Herr W., Clarke J., The SV40 enhancer is composed of multiple functional elements that can compensate for one another, Cell, 45, pp. 461-470, (1986)
[24] Herskowitz I., A regulatory hierarchy for cell specialization in yeast, Nature, 342, pp. 749-757, (1990)
[25] Hill C., Marais R., John S., Wynne J., Dalton S., Treisman R., The SRF accessory protein Elk-1 contains a growth factor-regulated transcriptional activation domain, Cell, 73, pp. 395-406, (1993)
[26] Ho I., Leiden J., Regulation of the human T-cell receptor α gene enhancer: Multiple ubiquitous and T-cell-specific nuclear proteins interact with four hypomethylated enhancer elements, Mol. Cell. Biol., 10, pp. 4720-4727, (1990)
[27] Ho I., Yang L., Morle G., Leiden J., A T-cell specific transcriptional enhancer element 3′ of the Cα in the human T-cell receptor α locus, Proc. Natl. Acad. Sci., 86, pp. 6714-6718, (1989)
[28] Ho I., Bhat N., Gottschalk L., Lindsten T., Thompson C., Papas T., Leiden J., Sequence-specific binding of hu-man Ets-1 to the T cell receptor α gene enhancer, Science, 250, pp. 814-817, (1990)
[29] Hoey T., Weinzierl R., Gill G., Chen J., Dynlacht B., Tjian R., Molecular cloning and functional analysis of Drosophila TAF110 reveal properties expected of coactivators, Cell, 72, pp. 247-260, (1993)
[30] Hoover T., Santero E., Porter S., Kustu S., The integration host factor stimulates interaction of RNA polymerase with NIFA, the transcription activator for nitrogen fixation operons, Cell, 63, pp. 11-22, (1990)

← 1 2 3 4 5 6 7 8 →