Cours : Transgénèse Végétale

Aperçu des sections

Généralités
Généralités
- Annonces Forum
Section 1
Section 1
- Fiche contact de l'enseignant :
  
  Nom / Prénom : Hakima BELATTAR
  Email : h.belattar@centre-univ-mila.dz
  Matière :Transgénèse végétale
  Unité d'enseignement : UEF1
  Semestre : 3 - Année Universitaire : 2023/2024
  Crédit : 6
  Coefficient : 3
  Volume horaire d’enseignement hebdomadaire: cours (3h00) + TD (1h30)
  Mode d'évaluation : Continu / examen
Section 2
Section 2
- Objectifs de l'enseignement:
  
  A la fin de la formation, l’étudiant devrait être en mesure de :
  Comprendre l’évolution de la biotechnologie
  Permettre une approche objective et raisonnée des organismes végétaux génétiquement modifiés
  Donner les bases biologiques et pratiques de la création d’une plante transgénique
  Connaître les applications agronomiques et industrielles
  Evaluer les impactes des plantes transgéniques sur la santé et l’environnement
  Entraîner la réflexion sur les avantages et les risques liés à l’utilisation des plantes issues du génie génétique
Section 3
Section 3
- Connaissances préalables recommandées :
  
  Génétique
  Biologie végétale
  Botanique
  Reproduction des végétaux
  Amélioration des plantes
Section 4
Section 4
- Cours Transgénèse végétale Dossier
- Travaux dirigés
- TD1 Fichier
- TD2 Fichier
- TD 3 Fichier
Section 5
Section 5
- Bibliographie :
  
  1. Backert S., and Meyer TF. (2006) Type IV secretion systems and their effectors in bacterial
  2. Berntsson RP., Smits SH., Schmitt L., Slotboom DJ., and Poolman B. (2010) A structural classification of substrate-binding proteins. FEBS Lett., 12, 2606-2617.
  3. Costechareyre D ., Rhouma A., Lavire C., Portier P., Chapulliot D., Bertolla F., Boubaker A., Dessaux Y., and Nesme X. (2010) Rapid and efficient identification of Agrobacterium species by recA allele analysis: Agrobacterium recA diversity. Microb Ecol. 60, 862-872.
  4. De Neve M., De Buck S., Jacobs A., Van Montagu M., and Depicker A. (1997) T-DNA integration patterns in cotransformed plant cells suggest thatT-DNA repeats originate from cointegration of separate T-DNAs. Plant J. 11, 15-29.
  5. Gelvin SB. (2003) Agrobacterium-mediated plant transformation: the biology behind the "genejockeying" tool. Microbiol Mol Biol Rev. 67, 16-37.
  6. Hwang HH., and Gelvin SB. (2004) Plant proteins that interact with VirB2, the Agrobacterium tumefaciens pilin protein, mediate plant transformation. Plant Cell. 16, 3148-3167.
  7.Li Y., Rosso MG., Ulker B., and Weisshaar B. (2006) Analysis of T-DNA insertion site distribution patterns in Arabidopsis thaliana reveals special features of genes without insertions. Genomics. 87, 645-652.
  8.Pitzschke A., and Hirt H. (2010) New insights into an old story: Agrobacterium-induced tumour formation in plants by plant transformation. EMBO J. 6, 1021-1032.
  9.Salman H., Abu-Arish A., Oliel S., Loyter A., Klafter J., Granel R., and Elbaum M. (2005) Nuclear localization signal peptides induce molecular delivery along microtubules. Biophys J. 89,2134-2145.
  10.Tzfira T., and Citovsky V. (2006) Agrobacterium-mediated genetic transformation of plants: biology and biotechnology. Curr Opin Biotechnol. 17, 147-154.
  11.Valdivia RH., Wang L., and Winans SC. (1991) Characterization of a putative periplasmic transport system for octopine accumulation encoded by Agrobacterium tumefaciens Ti plasmid pTiA6. J. Bacteriol. 173, 6398-6405.
  12.Waters CM., and Bassler BL. (2005). Quorum sensing: cell-to-cell communication in bacteria. Annu Rev Cell Dev Biol. 21, 319-346.
  13.White CE ., and Winans SC. (2007) The quorum-sensing transcription factor TraR decodes its DNA binding site by direct contacts with DNA bases and by detection of DNA flexibility. Mol Microbiol. 64, 245-256.

Transgénèse Végétale

Aperçu des sections

Généralités

Section 1

Fiche contact de l'enseignant :

Nom / Prénom : Hakima BELATTAR
Email : h.belattar@centre-univ-mila.dz
Matière :Transgénèse végétale
Unité d'enseignement : UEF1
Semestre : 3 - Année Universitaire : 2023/2024
Crédit : 6
Coefficient : 3
Volume horaire d’enseignement hebdomadaire: cours (3h00) + TD (1h30)

Mode d'évaluation : Continu / examen

Section 2

Objectifs de l'enseignement:

Section 3

Connaissances préalables recommandées :

Génétique
Biologie végétale
Botanique
Reproduction des végétaux
Amélioration des plantes

Section 4

Section 5

Bibliographie :

1. Backert S., and Meyer TF. (2006) Type IV secretion systems and their effectors in bacterial

2. Berntsson RP., Smits SH., Schmitt L., Slotboom DJ., and Poolman B. (2010) A structural classification of substrate-binding proteins. FEBS Lett., 12, 2606-2617.

3. Costechareyre D ., Rhouma A., Lavire C., Portier P., Chapulliot D., Bertolla F., Boubaker A., Dessaux Y., and Nesme X. (2010) Rapid and efficient identification of Agrobacterium species by recA allele analysis: Agrobacterium recA diversity. Microb Ecol. 60, 862-872.

4. De Neve M., De Buck S., Jacobs A., Van Montagu M., and Depicker A. (1997) T-DNA integration patterns in cotransformed plant cells suggest thatT-DNA repeats originate from cointegration of separate T-DNAs. Plant J. 11, 15-29.

5. Gelvin SB. (2003) Agrobacterium-mediated plant transformation: the biology behind the "genejockeying" tool. Microbiol Mol Biol Rev. 67, 16-37.

6. Hwang HH., and Gelvin SB. (2004) Plant proteins that interact with VirB2, the Agrobacterium tumefaciens pilin protein, mediate plant transformation. Plant Cell. 16, 3148-3167.

7.Li Y., Rosso MG., Ulker B., and Weisshaar B. (2006) Analysis of T-DNA insertion site distribution patterns in Arabidopsis thaliana reveals special features of genes without insertions. Genomics. 87, 645-652.

8.Pitzschke A., and Hirt H. (2010) New insights into an old story: Agrobacterium-induced tumour formation in plants by plant transformation. EMBO J. 6, 1021-1032.

9.Salman H., Abu-Arish A., Oliel S., Loyter A., Klafter J., Granel R., and Elbaum M. (2005) Nuclear localization signal peptides induce molecular delivery along microtubules. Biophys J. 89,2134-2145.

10.Tzfira T., and Citovsky V. (2006) Agrobacterium-mediated genetic transformation of plants: biology and biotechnology. Curr Opin Biotechnol. 17, 147-154.

11.Valdivia RH., Wang L., and Winans SC. (1991) Characterization of a putative periplasmic transport system for octopine accumulation encoded by Agrobacterium tumefaciens Ti plasmid pTiA6. J. Bacteriol. 173, 6398-6405.

12.Waters CM., and Bassler BL. (2005). Quorum sensing: cell-to-cell communication in bacteria. Annu Rev Cell Dev Biol. 21, 319-346.

13.White CE ., and Winans SC. (2007) The quorum-sensing transcription factor TraR decodes its DNA binding site by direct contacts with DNA bases and by detection of DNA flexibility. Mol Microbiol. 64, 245-256.

Aperçu des sections

Généralités

Section 1

Fiche contact de l'enseignant :

Nom / Prénom : Hakima BELATTAREmail : h.belattar@centre-univ-mila.dzMatière :Transgénèse végétaleUnité d'enseignement : UEF1Semestre : 3 - Année Universitaire : 2023/2024Crédit : 6Coefficient : 3Volume horaire d’enseignement hebdomadaire: cours (3h00) + TD (1h30)

Mode d'évaluation : Continu / examen

Section 2

Objectifs de l'enseignement:

Section 3

Connaissances préalables recommandées :

GénétiqueBiologie végétaleBotaniqueReproduction des végétauxAmélioration des plantes

Section 4

Section 5

Bibliographie :

1. Backert S., and Meyer TF. (2006) Type IV secretion systems and their effectors in bacterial

2. Berntsson RP., Smits SH., Schmitt L., Slotboom DJ., and Poolman B. (2010) A structural classification of substrate-binding proteins. FEBS Lett., 12, 2606-2617.

3. Costechareyre D ., Rhouma A., Lavire C., Portier P., Chapulliot D., Bertolla F., Boubaker A., Dessaux Y., and Nesme X. (2010) Rapid and efficient identification of Agrobacterium species by recA allele analysis: Agrobacterium recA diversity. Microb Ecol. 60, 862-872.

4. De Neve M., De Buck S., Jacobs A., Van Montagu M., and Depicker A. (1997) T-DNA integration patterns in cotransformed plant cells suggest thatT-DNA repeats originate from cointegration of separate T-DNAs. Plant J. 11, 15-29.

5. Gelvin SB. (2003) Agrobacterium-mediated plant transformation: the biology behind the "genejockeying" tool. Microbiol Mol Biol Rev. 67, 16-37.

6. Hwang HH., and Gelvin SB. (2004) Plant proteins that interact with VirB2, the Agrobacterium tumefaciens pilin protein, mediate plant transformation. Plant Cell. 16, 3148-3167.

7.Li Y., Rosso MG., Ulker B., and Weisshaar B. (2006) Analysis of T-DNA insertion site distribution patterns in Arabidopsis thaliana reveals special features of genes without insertions. Genomics. 87, 645-652.

8.Pitzschke A., and Hirt H. (2010) New insights into an old story: Agrobacterium-induced tumour formation in plants by plant transformation. EMBO J. 6, 1021-1032.

9.Salman H., Abu-Arish A., Oliel S., Loyter A., Klafter J., Granel R., and Elbaum M. (2005) Nuclear localization signal peptides induce molecular delivery along microtubules. Biophys J. 89,2134-2145.

10.Tzfira T., and Citovsky V. (2006) Agrobacterium-mediated genetic transformation of plants: biology and biotechnology. Curr Opin Biotechnol. 17, 147-154.

11.Valdivia RH., Wang L., and Winans SC. (1991) Characterization of a putative periplasmic transport system for octopine accumulation encoded by Agrobacterium tumefaciens Ti plasmid pTiA6. J. Bacteriol. 173, 6398-6405.

12.Waters CM., and Bassler BL. (2005). Quorum sensing: cell-to-cell communication in bacteria. Annu Rev Cell Dev Biol. 21, 319-346.

13.White CE ., and Winans SC. (2007) The quorum-sensing transcription factor TraR decodes its DNA binding site by direct contacts with DNA bases and by detection of DNA flexibility. Mol Microbiol. 64, 245-256.

Nom / Prénom : Hakima BELATTAR
Email : h.belattar@centre-univ-mila.dz
Matière :Transgénèse végétale
Unité d'enseignement : UEF1
Semestre : 3 - Année Universitaire : 2023/2024
Crédit : 6
Coefficient : 3
Volume horaire d’enseignement hebdomadaire: cours (3h00) + TD (1h30)

Génétique
Biologie végétale
Botanique
Reproduction des végétaux
Amélioration des plantes