Transcriptional Regulation of the Copper Transporter Mfc1 in Meiotic Cells

Beaudoin, Jude; Ioannoni, Raphaël; Mailloux, Stéphane; Plante, Samuel; Labbé, Simon

doi:10.1128/ec.00019-13

Cited by 9 publications

(19 citation statements)

References 54 publications

(82 reference statements)

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“…Secondly, whereas the deletion of cuf1 + ( cuf1 Δ) impairs the induction of ctr4 + , activation of mfc1 + is unaffected, suggesting the existence of a distinct transcriptional regulator for the induction of mfc1 + in response to copper starvation [28]. Analysis of promoter regions in mfc1 + has revealed that two TCGGCG regulatory elements containing CGG triplets are responsible for transcriptional activation of mfc1 + under low-copper conditions [38]. Consistent with the fact that cis -acting elements containing CGG triplets are known to serve as binding sites for members of the Zn 2 Cys 6 binuclear cluster class of regulators [39], Mca1 (a Zn 2 Cys 6 cluster-type transcription factor) was found to be necessary for maximum induction of mfc1 + gene expression [38].…”

Section: Transactivator Mca1mentioning

confidence: 99%

“…Analysis of promoter regions in mfc1 + has revealed that two TCGGCG regulatory elements containing CGG triplets are responsible for transcriptional activation of mfc1 + under low-copper conditions [38]. Consistent with the fact that cis -acting elements containing CGG triplets are known to serve as binding sites for members of the Zn 2 Cys 6 binuclear cluster class of regulators [39], Mca1 (a Zn 2 Cys 6 cluster-type transcription factor) was found to be necessary for maximum induction of mfc1 + gene expression [38]. Both mfc1 Δ and mca1 Δ mutant strains display phenotypes linked to copper starvation.…”

Section: Transactivator Mca1mentioning

confidence: 99%

“…For example, under copper-limiting conditions, mfc1 Δ/ mfc1 Δ mutant cells exhibit a meiotic progression that is delayed and prolonged (by ~2–3 h) compared with the wild-type strain. Under the same copper-limiting conditions, cells lacking Mca1 ( mca1 Δ/ mca1 Δ mutants) undergo a meiotic arrest at metaphase I that blocks cellular differentiation [38]. These observations suggest that Mca1 may play an important role in activation of other meiotic genes aside from mfc1 + , especially those expressed in early meiosis that precedes metaphase I.…”

Section: Transactivator Mca1mentioning

confidence: 99%

“…On the basis of previous studies on Zn 2 Cys 6 cluster-type transcription factors, it can be suggested that the zinc-finger motif, the linker and the dimerization region form the putative N-terminal DNA-binding domain of Mca1 (residues 1–138). Binding studies have revealed that the N-terminal 150-residue segment of Mca1 (including residues 1–138) specifically recognizes the TCGGCGN 13 TCGGCG sequence of the mfc1 + promoter region [38]. Given the fact that two zinc-finger units are required to bind a pair of CGG triplets, this restriction implies that Mca1 may bind the TCGGCGN 13 TCGGCG sequence as a homodimer.…”

Section: Transactivator Mca1mentioning

confidence: 99%

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Copper transport and regulation in Schizosaccharomyces pombe

Beaudoin

Ekici

Daldal

et al. 2013

Biochemical Society Transactions

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The fission yeast Schizosaccharomyces pombe has been successfully used as a model to gain fundamental knowledge in understanding how eukaryotic cells acquire copper during vegetative growth. These studies have revealed the existence of a heteromeric Ctr4–Ctr5 plasma membrane complex that mediates uptake of copper within the cells. Furthermore, additional studies have led to the identification of one of the first vacuolar copper transporters, Ctr6, as well as the copper-responsive Cuf1 transcription factor. Recent investigations have extended the use of S. pombe to elucidate new roles for copper metabolism in meiotic differentiation. For example, these studies have led to the discovery of Mfc1, which turned out to be the first example of a meiosis-specific copper transporter. Whereas copper-dependent transcriptional regulation of the Ctr family members is under the control of Cuf1 during mitosis or meiosis, meiosis-specific copper transporter Mfc1 is regulated by the recently discovered transactivator Mca1. It is foreseeable that identification of novel meiotic copper-related proteins will serve as stepping stones to unravel fundamental aspects of copper homoeostasis.

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Section: Transactivator Mca1mentioning

confidence: 99%

Section: Transactivator Mca1mentioning

confidence: 99%

Section: Transactivator Mca1mentioning

confidence: 99%

Section: Transactivator Mca1mentioning

confidence: 99%

See 2 more Smart Citations

Copper transport and regulation in Schizosaccharomyces pombe

Beaudoin

Ekici

Daldal

et al. 2013

Biochemical Society Transactions

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“…Synchronous meiosis of pat1-114/pat1-114 diploid cells was carried out as described previously (28). Treatments of meiotic cells were performed using low concentrations of TTM (150 M) and CuSO 4 (50 M) as described previously (30). Monitoring progression of meiotic cells throughout the differentiation program was performed as described previously (31).…”

Section: Methodsmentioning

confidence: 99%

An Antisense RNA-mediated Mechanism Eliminates a Meiosis-specific Copper-regulated Transcript in Mitotic Cells

Normant

Beaudoin

Labbé

2015

Journal of Biological Chemistry

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Mutagenesis: Site‐Specific

Walquist

Buvang

El-Gewely

2014

Encyclopedia of Life Sciences

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Site‐specific mutagenesis techniques, also known as site‐directed mutagenesis (SDM), aim to introduce precise alterations in any coding or noncoding deoxyribonucleic acid (DNA) sequence, usually in vitro . These modifications could be as small as a nucleotide or several hundreds; in one site or in multisite in the same DNA sequence. Recently, these alterations have been also developed in vivo . SDM success depends on how changes are introduced and mutant selection is done. DNA sequence analysis has to be made to verify change(s) before any biochemical or biological experiments are done. Recent methods for SDM and most used commercial kits are discussed. A list of companies offering SDM service is included. The authors have also listed software used for mutagenic oligonucleotide primer‐design. These techniques are revolutionising our understanding of the genetic and molecular mechanisms, protein structure–function relationship, protein–protein interaction, binding sites in any biological system. In addition to the academic benefits of SDM, SDM techniques have impacted biotechnology and the applied field such as engineering new enzymes, drug development, optimisation of heterologous gene expression and secretion. Key Concepts: All site‐specific alterations requiring site‐directed mutagenesis technique are done at the DNA level making it heritable modifications. Modifications done at the protein levels are not heritable. The results of these alterations are reflected in the encoded amino acids sequence of the proteins or in any targeted binding site in the DNA sequence. Several simplified Techniques are now available. Selection of the altered DNA molecules from the pool of nonmodified parental molecules is essential. DNA sequence to verify the DNA change is fundamental part of the technique. Biological and biochemical ramifications as a result of SDM are usually the purpose that SDM is done in the first place.

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Transcriptional Regulation of the Copper Transporter Mfc1 in Meiotic Cells

Cited by 9 publications

References 54 publications

Copper transport and regulation in Schizosaccharomyces pombe

Copper transport and regulation in Schizosaccharomyces pombe

An Antisense RNA-mediated Mechanism Eliminates a Meiosis-specific Copper-regulated Transcript in Mitotic Cells

Mutagenesis: Site‐Specific

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