Substitution of DNA-contacting amino acids with functional variants in the Gata-1 zinc finger: a structurally and phylogenetically guided mutagenesis.

DNA-binding functionality among transcription factor proteins is afforded by a number of structural motifs, such as the helix-turn-helix, helix-loop-helix, and zinc finger domains. The common thread among these diverse structures is their sequence-specific binding to essential promoter or other genetic regulatory sequences with high selectivity and affinity. One such motif, present in a wide range of organisms from bacteria to vertebrates, is the Gata-type zinc finger. This family of DNA-binding proteins is characterized by the presence of one or two (Cys)(4) metal binding sites which recognize the protein's eponymous binding site, GATA. Unlike other conserved DNA-binding domains, Gata proteins appear to be restricted to binding consensus GATA sequences, or near variations, in DNA. Since the architecture of the Gata finger seems built around recognizing this particular sequence, we set out to define the allowable range of amino acid substitutions along the DNA-binding surface of a Gata finger that could continue to support sequence-specific DNA-binding activity. Accordingly, we set up a one-hybrid screen in yeast based on the chicken Gata-1 C-terminal zinc finger. Mutant libraries were generated at five amino acids identified in the Gata-DNA structure as likely to mediate sequence-specific contacts between the Gata finger and DNA. These libraries were designed to give as exhaustive amino acid coverage as possible such that almost all alternative amino acids were screened at each of the five probed positions. Screening and characterization of these libraries revealed several functional amino acid substitutions at two leucines which contact the DNA at the 3' and 5' flanks of the GATA binding site, but no functional substituents for amino acids near the core of the binding site. This pattern is consistent with amino acid sequences of known DNA-binding Gata fingers.

Spectroscopic and functional determination of the interaction of Pb2+ with GATA proteins.

GATA proteins are transcription factors that bind GATA DNA elements through Cys4 structural zinc-binding domains and play critical regulatory roles in neurological and urogenital development and the development of cardiac disease. To evaluate GATA proteins as potential targets for lead, spectroscopically monitored metal-binding titrations were used to measure the affinity of Pb2+ for the C-terminal zinc-binding domain from chicken GATA-1 (CF) and the double-finger domain from human GATA-1 (DF). Using this method, Pb2+ coordinating to CF and DF was directly observed through the appearance of intense bands in the near-ultraviolet region of the spectrum (250-380 nm). Absorption data collected from these experiments were best fit to a 1:1 Pb2+ -CF model and a 2:1 Pb2+ -DF model. Competition experiments using Zn2+ were used to determine the absolute affinities of Pb2+ for these proteins. These studies reveal that Pb2+ forms tight complexes with cysteine residues in the zinc-binding sites in GATA proteins, beta1Pb = 6.4 (+/- 2.0) x 10(9) M(-1) for CF and beta2 = 6.3 (+/- 6.3) x 10(19) M(-2) for Pb(2+)2-DF, and within an order of magnitude of the affinity of Zn2+ for these proteins. Furthermore, Pb2+ was able to displace bound Zn2+ from CF and DF. Upon addition of Pb2+, GATA shows a decreased ability to bind to DNA and subsequently activate transcription. Therefore, the DNA binding and transcriptional activity of GATA proteins are most likely to be targeted by Pb2+ in cells and tissues that sequester Pb2+ in vivo, which include the brain and the heart.