Rôle de Sim1 et Sim2 dans la guidance des axones du corps mammillaire

Marion, Jean-François

January 2004

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Sim1

Sim2

Guidance axonale

Axones

bHLH-PAS

Corps mammillaire

Sim1 function in the developing and adult brain

Yang, Chun

January 2006

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

Sim1

Protéine bHLH-PAS

AHR

Noyau paraventriculaire (PVN)

Promoteur

Régulation génique

Prise alimentaire

Hyperphagie

Adénovirus

Juvenile hormone signaling in insect development and reproduction / Juvenile hormone signaling in insect development and reproduction

SMÝKAL, Vlastimil

January 2014

This thesis comprises three published papers and one manuscript, all focused on the role of juvenile hormone (JH), the JH receptor Methoprene-tolerant (Met) and its target gene Krüppel-homolog 1 (Kr-h1) in insect development and reproduction. The JH-Met-Kr-h1 pathway is critical for metamorphic transition in hemimetabolan Pyrrhocoris apterus (Hemiptera) and holometabolan Bombyx mori (Lepidoptera) but seems to be dispensable during early larval postembryonic development. The results also show that Met and its heterodimeric partner Taiman (Tai) but not Kr-h1 are critical for ovarian development and vitellogenesis in Pyrrhocoris females. In vitro, in vivo and cell-based techniques in Drosophila melanogaster have demonstrated that Met and its paralog Gce are a bona fide receptor for JH. Only Gce capable of binding JH rescued Drosophila deficient for Met and Gce proteins, and the capacity of Gce to bind JH was necessary for JH-dependent transcriptional activation by Gce and Tai.

Molecular Biology of bHLH PAS Genes Involved in Dipteran Juvenile Hormone Signaling

Baumann, Aaron A.

01 November 2010

No description available.

Molecular Biology

methoprene

Diptera

juvenile hormone

bHLH PAS

evolution

molecular biology

metamorphosis

Methoprene-tolerant

germ cell expressed

Met

gce

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