Abstract
Mac1 is a transcriptional activator whose activity is inhibited by copper ions. Mutagenesis studies were carried out to map residues important in the copper inhibition of Mac1 activity. Seven new missense mutations were identified that resulted in copper-independent Mac1 transcriptional activation. All seven mutations were clustered in one of two C-terminal cysteine-rich motifs, designated the C1 motif. All but one of the constitutive Mac1 mutations occurred in one of the conserved six residues in the (264)CXC[(X)(4)]CXC[(X)(2)]C[(X)(2)][H(279)]C1 motif. The lone exception was a L260S substitution. Two additional MAC1 mutations exhibiting constitutive activity were in-frame deletions encompassing portions C1. Engineered mutations in the second cysteine-rich motif did not yield a constitutively active Mac1. These results are consistent with the C1 motif being the copper-regulatory switch. Both cysteine-rich motifs exhibited transactivation activity, although the C1 activator was weak relative to the C2 activator. Limited copper metalloregulation of Mac1 was observed with only the C1 activator fused to the N-terminal DNA binding domain. Thus, the two Cys-rich motifs appear to function independently. The C1 motif appears to be a functional copper-regulatory domain.
Highlights
The high affinity uptake system in yeast consists of two copper ion permeases, Ctr[1] and Ctr[3], and a metalloreductase Fre[1] capable of cupric ion reduction (6)
We show in the current work that the C1 motif is an independent copper regulatory domain
Mutagenesis studies were conducted on MAC1 to map residues important in the copper inhibition of Mac[1] activity
Summary
The high affinity uptake system in yeast consists of two copper ion permeases, Ctr[1] and Ctr[3], and a metalloreductase Fre[1] capable of cupric ion reduction (6). The initial event is the specific inhibition of DNA binding and transactivation functions of Mac[1] that occurs in cells cultured in medium containing nM Cu(II) (4, 8, 9). The copper repression of Mac[1] function appears to arise from a copper-induced, intramolecular interaction of the C-terminal Cys-rich motifs and the N-terminal DNA binding domain (13). Since mutations in the C1 motif abolish the inhibitory interaction, we sought to map the interactive region in the N-terminal DNA binding domain of Mac[1] by isolating additional constitutive Mac[1] mutants. The second motive for the present work was to determine whether the repeated Cys-rich sequence motifs function separately or as a single domain in mediating copper metalloregulation of Mac[1]. We show in the current work that the C1 motif is an independent copper regulatory domain
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