Interaction of bZIP and bHLH Transcription Factors with the G-box

De Jong, Antonia Thelma-Jean

07 August 2013

Transcription factors are proteins that regulate transcription of genes by binding to specific DNA sequences proximal to the gene. The specificity and affinity of protein-DNA recognition is critical for proper gene regulation. This thesis explores the mechanisms of binding to the sequence 5’CACGTG, a common recognition sequence both in plants where it is known as the G-box and in mammalian cells where it is termed the E-box. This sequence is of clinical interest because it is the target of the transcription factor Myc, an oncogene linked to many cancers. A number of alpha-helical proteins with different dimerization elements, from the basic region-leucine zipper (bZIP), basic region helix-loop-helix leucine zipper (bHLHZ) and basic region helix-loop-helix-PAS (bHLH-PAS) protein families, are capable of binding to this sequence. The basic regions of all these protein families contain residues that contact DNA and determine DNA sequence specificity while the other subdomains are responsible for dimerization specificity. First, the influence of protein-DNA contacts on sequence specificity of the plant bZIP protein EmBP-1 was probed by point mutations in the basic region. Residues that contact the DNA outside the core G-box sequence and residues that contact the phosphate backbone were found to be important for sequence specificity. Second, the impact of the dimerization subdomains of bHLHZ protein Max, the required heterodimerization partner of the Myc protein, and bHLH-PAS protein Arnt was probed by mutation, deletion and inter-family subdomain swapping studies. All studied protein families are intrinsically disordered, forming structure upon dimerization and DNA binding. The dimerization domains were found to indirectly influence DNA binding by affecting folding, dimerization ability or proper orientation of the basic regions relative to DNA. Lastly, a new strategy for selection of G-box binding proteins in the Yeast One-hybrid system is explored. Together, these studies broaden our understanding of the structure-function relationship of the DNA-binding activities of these closely related families of transcription factors. The creation and characterization of mutants with altered specificity, affinity and dimerization specificity may also be useful for biotechnology applications.

bZIP

bHLH

bHLHZ

bHLH-PAS

E-box

G-box

Max

Arnt

EmBP-1

transcription factor

leucine zipper

Fos

E47

yeast one-hybrid

sequence specificity

protein-DNA interaction

0487

Interaction of bZIP and bHLH Transcription Factors with the G-box

De Jong, Antonia Thelma-Jean

07 August 2013

Transcription factors are proteins that regulate transcription of genes by binding to specific DNA sequences proximal to the gene. The specificity and affinity of protein-DNA recognition is critical for proper gene regulation. This thesis explores the mechanisms of binding to the sequence 5’CACGTG, a common recognition sequence both in plants where it is known as the G-box and in mammalian cells where it is termed the E-box. This sequence is of clinical interest because it is the target of the transcription factor Myc, an oncogene linked to many cancers. A number of alpha-helical proteins with different dimerization elements, from the basic region-leucine zipper (bZIP), basic region helix-loop-helix leucine zipper (bHLHZ) and basic region helix-loop-helix-PAS (bHLH-PAS) protein families, are capable of binding to this sequence. The basic regions of all these protein families contain residues that contact DNA and determine DNA sequence specificity while the other subdomains are responsible for dimerization specificity. First, the influence of protein-DNA contacts on sequence specificity of the plant bZIP protein EmBP-1 was probed by point mutations in the basic region. Residues that contact the DNA outside the core G-box sequence and residues that contact the phosphate backbone were found to be important for sequence specificity. Second, the impact of the dimerization subdomains of bHLHZ protein Max, the required heterodimerization partner of the Myc protein, and bHLH-PAS protein Arnt was probed by mutation, deletion and inter-family subdomain swapping studies. All studied protein families are intrinsically disordered, forming structure upon dimerization and DNA binding. The dimerization domains were found to indirectly influence DNA binding by affecting folding, dimerization ability or proper orientation of the basic regions relative to DNA. Lastly, a new strategy for selection of G-box binding proteins in the Yeast One-hybrid system is explored. Together, these studies broaden our understanding of the structure-function relationship of the DNA-binding activities of these closely related families of transcription factors. The creation and characterization of mutants with altered specificity, affinity and dimerization specificity may also be useful for biotechnology applications.

bZIP

bHLH

bHLHZ

bHLH-PAS

E-box

G-box

Max

Arnt

EmBP-1

transcription factor

leucine zipper

Fos

E47

yeast one-hybrid

sequence specificity

protein-DNA interaction

0487

Identification de facteurs de transcription régulateurs de la voie de biosynthèse des alcaloïdes indoliques monoterpéniques chez Catharanthus roseus / Identification of transcription factors regulating the biosynthesis pathway of monoterpene indole alkaloids in catharanthus roseus

Ginis, Olivia

08 June 2012

Catharanthus roseus est une plante tropicale qui produit spécifiquement des alcaloïdes indoliques monoterpéniques (AIM) d’intérêt thérapeutique. Chez C. roseus, la branche terpénique incluant la voie du méthylérythritol phosphate (MEP) est considérée comme limitante et présente une régulation transcriptionnelle coordonnée en réponse aux hormones inductrices de l’accumulation alcaloïdique. Lors de ce travail, suite à des analyses bioinformatiques et à la caractérisation de promoteurs de gènes de la voie MEP, nous avons identifié de nouvelles familles de facteurs de transcription impliquées dans la régulation de la biosynthèse des AIM. Des membres de la famille des ZCT, des WRKY et des RR type B interagissent avec le promoteur du gène hds de la voie MEP et régulent son activité. Ces travaux ont permis d’approfondir les connaissances sur les réseaux transcriptionnels régulateurs de la biosynthèse des AIM. L’utilisation de ces nouveaux facteurs de transcription activateurs peut désormais être envisagée dans le cadre d’expériences d’ingénierie métabolique afin d’augmenter l’accumulation d’alcaloïdes d’intérêt pharmaceutique chez C. roseus. / Catharanthus roseus is a tropical plant producing specifically monoterpene indole alkaloids (MIA) of high interest due to their therapeutical values. In C. roseus cells, the terpenoid branch including the methyl erythritol phosphate pathway (MEP) provides the MIA terpenoid moiety and is regarded as limited for MIA biosynthesis. This branch presents a coordinated transcriptional regulation in response to hormonal signals leading to MIA production. In this context, bioinformatic analysises and functional characterization of MEP pathway gene promoters allowed the identification of new transcription factor families involved in the MIA pathway regulation. Members of ZCT proteins, WRKY and type B RR families specifically interact with the hds promoter from the MEP pathway and regulate its activity. This work permits to gain into insight the transcriptional network controlling the MIA biosynthesis. It is possible now to consider using transcription factor that act as activators and target genes from the terpenoid branch to increase the accumulation of alkaloids of pharmaceutical interest in C. roseus by metabolic engineering approaches.

Catharanthus roseus

Cultures cellulaires

Alcaloïdes indoliques monoterpéniques

Terpènes

MEP

Promoteur

Facteur de transcription

Phytohormones

Signalisation cytokinine

Biolistique

Criblage par simple hybride de levure

Ingénierie métabolique

Méthylérytritol Phosphate

Catharanthus roseus

Cell cultures

Monoterpene indole alkaloids

Terpanoid

MEP

Promoter

Transcription factor

Plant hormones

Cytokinin signaling

Boilistic

Yeast one-hybrid screening

Metabolic engineering

Implication de facteurs de transcription de type doigt de zinc et de la famille des WRKY dans la régulation de la voie du MEP et de la biosynthèse des alcaloïdes indoliques monoterpéniques de Catharanthus roseus / Involvment of transcription factors of the zinc finger and the WRKY families in the regulation of the MEP pathway and the MIA biosynthesis in Catharanthus roseus

Chebbi, Mouadh

19 February 2015

Les alcaloïdes indoliques monoterpéniques (AIM) sont des molécules à propriétés anti-tumorales extraites de Catharanthus roseus. Leur coût de production et les besoins encore importants de ces médicaments en chimiothérapie, en font des cibles majeures pour la recherche de stratégies de production plus efficaces. L’objectif de ce travail vise à identifier de nouveaux facteurs de transcription (FT) régulateurs de la production des AIM. Cette étude porte plus particulièrement sur la caractérisation fonctionnelle et l’implication dans la régulation de la biosynthèse des AIM, de protéines de la famille des WRKY (CrWRKYs) et des protéines de type doigt de zinc (ZCTs) précédemment isolées au sein de l’EA2106 « Biomolécules et Biotechnologies Végétales ». Nos expériences ont révélé que, parmi ces protéines, CrWRKY22, CrWRKY32, ZCT1 et ZCT2 agissent en tant que facteurs de transcription et plus spécifiquement interagissent avec le promoteur du gène Crhds. Ce dernier code une enzyme de la voie du méthyl érythritol phosphate (MEP) considérée limitante pour la production des AIM. Ces travaux ont permis d’identifier de nouveaux FT ciblant la voie du MEP dont la régulation via les FT est encore peu élucidée à ce jour et d’envisager leur utilisation en ingénierie métabolique pour augmenter la production d’AIM par la modulation du flux terpénique chez C. roseus. / Monoterpene indole alkaloids (MIA) are molecules with anti-cancer properties from Catharanthus roseus. Their production cost and the important need in chemiotherapy make them major targets for the research of more efficient production strategies. The aim of this work is to identify new transcription factors (TF) that regulate MIA production. This study focuses especially on the functional characterization and the involvement in the MIA biosynthesis regulation, of proteins previously isolated in the EA2106 “Plant Biocompounds and Biotechnology” laboratory: 3 proteins that belong to the WRKY family (CrWRKYs) and 3 zinc finger proteins named ZCTs. Our experiments revealed that among them, CrWRKY22, CrWRKY32, ZCT1 and ZCT2 act as transcription factors and more specifically interact with the promoter of Crhds gene. Crhds encodes an enzyme of the methyl erythritol phosphate (MEP) pathway that is considered as limiting for MIA production. Our work allowed identifying new TFs targeting the MEP pathway those regulation through TFs is mostly unknown. Using such transcription factors in metabolic engineering could be now considered increasing MIA production by the modulation of terpenoid flux in C. roseus.

Catharanthus roseus

Alcaloïdes indoliques monoterpéniques

Facteurs de transcription

WRKY

ZCT

Méthyl érythritol phosphate

Criblage par simple de levure

Transactivation

Promoteur Crhds

Régulation génique

Catharanthus roseus

Monoterpene indole alkaloids

Transcription factors

WRKY

ZCT

Methyl erythritol phosphate

Yeast one-hybrid screening

Transactivation

Crhds promoter

Gene regulation