YB-1 regulation of the human and rat gelatinase A genes via similar enhancer elements.

Experimental and clinical studies strongly suggest that gelatinase A plays a central role in the evolution of glomerular injury and sclerosis. The sequences of the 5' flanking regions of the human and rat gelatinase A genes do not share similarities with other members of the matrix metalloproteinase gene family and are regulated in a distinctive manner. The human and rat gelatinase A genes include regions of significant homology (r2 human; RE-1 rat), which have been shown to act as potent cis-activators of transcription. The rat RE-1 sequence interacts specifically with the developmentally regulated transcription factors AP2 and YB-1, resulting in a synergistic activation of gelatinase A transcription. Although the human r2 sequence specifically interacts with AP2 (Mol Cell Biol 10: 6524-6532, 1990), there is no clear evidence for the presence of a canonical YB-1 binding site (Y-box) within this sequence. This study demonstrates, despite the absence of a canonical Y-box sequence in the r2 element, that YB-1 and AP2 specifically interact with r2, yielding synergistic transactivation of the human gelatinase A gene. It is concluded that the r2 element is the conserved functional analog of the RE-1 element, and that interactions of AP2 and YB-1 govern human gelatinase A gene expression.

A synergistic interaction of transcription factors AP2 and YB-1 regulates gelatinase A enhancer-dependent transcription.

The matrix metalloproteinase gelatinase A plays a central role in several critical physiologic processes, including angiogenesis, tumor invasion/metastasis, and chronic inflammation. We demonstrate that high level gelatinase A expression is mediated by a unique interaction of two developmentally regulated transcription factors, AP2 and YB-1, within a discrete 40-base pair enhancer element (RE-1) located in the 5'-flanking region of the gelatinase A gene. Electrophoretic mobility shift assay studies and immunoprecipitation experiments confirmed a direct interaction of AP2 with this binding sequence in the form of AP2.YB-1 heteromeric complexes. Binding of AP2.YB-1 complexes to the RE-1 sequence results in the formation of extended single-stranded DNA regions and may stabilize DNA conformational changes. Overexpression of YB-1 and AP2 proteins by gelatinase A synthesizing hepatoma HepG2 cells induced a synergistic increase in the RE-1-mediated transcription of nearly 160-fold. Thus, the transcription of gelatinase A is subject to a previously unrecognized interplay of double (AP2) and single-stranded (YB-1) DNA binding transcription factors to yield a highly regulated pattern of gene expression.