The Impact of Engineering Halide/Thiol Methyltransferase-mediated Cl– volatilization on Salt Tolerance of Tomato Plants

Ritika, Ritika

17 July 2013

Many higher plants can synthesize methyl chloride gas via a common metabolic route, also known as the biological chloride methylation. The reaction is catalyzed by an S-adenosyl-L- methionine (AdoMet) dependent halide/thiol methyltransferase (H/TMT). It is speculated that plants use chloride methylation to remove excess chloride via volatilization and hence maintain homeostatic levels of cytoplasmic chloride ion, suggesting a role of H/TMT in salt tolerance. In this project, the effect of engineering a Brassica oleracea thiol methyltransferase (BoTMT) into tomato was studied to determine the physiological relevance of this enzyme in conferring salt tolerance. Transgenic tomato plants acquired the ability to release methyl chloride in response to NaCl treatment, but exhibited no greater tolerance to NaCl, based on several morphological and physiological measurements, as compared to the wild-type plants. The results indicate that AdoMet dependent chloride methylation is unlikely to contribute to an increase in salt tolerance in higher plants.

Halide/Thiol methyltransferase

Thiol Methyltransferase

Halide methylation

salinity

Tomato

AdoMet

Salt tolerance

H/TMT

0817

The Impact of Engineering Halide/Thiol Methyltransferase-mediated Cl– volatilization on Salt Tolerance of Tomato Plants

Ritika, Ritika

17 July 2013

Many higher plants can synthesize methyl chloride gas via a common metabolic route, also known as the biological chloride methylation. The reaction is catalyzed by an S-adenosyl-L- methionine (AdoMet) dependent halide/thiol methyltransferase (H/TMT). It is speculated that plants use chloride methylation to remove excess chloride via volatilization and hence maintain homeostatic levels of cytoplasmic chloride ion, suggesting a role of H/TMT in salt tolerance. In this project, the effect of engineering a Brassica oleracea thiol methyltransferase (BoTMT) into tomato was studied to determine the physiological relevance of this enzyme in conferring salt tolerance. Transgenic tomato plants acquired the ability to release methyl chloride in response to NaCl treatment, but exhibited no greater tolerance to NaCl, based on several morphological and physiological measurements, as compared to the wild-type plants. The results indicate that AdoMet dependent chloride methylation is unlikely to contribute to an increase in salt tolerance in higher plants.

Halide/Thiol methyltransferase

Thiol Methyltransferase

Halide methylation

salinity

Tomato

AdoMet

Salt tolerance

H/TMT

0817

Identification and isolation of plant promoters induced by thiocyanate

Nasr, Zeina

January 2007

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Thiol methyltransferase

Thiol methyl transférase

Thiocyanate

Selectable marker

Marqueur de sélection

Inducible promoter

Pormoteurs inductibles

Differential display

Analyse différentielle

Identification and isolation of plant promoters induced by thiocyanate

Nasr, Zeina

January 2007

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Thiol methyltransferase

Thiol methyl transférase

Thiocyanate

Selectable marker

Marqueur de sélection

Inducible promoter

Pormoteurs inductibles

Differential display

Analyse différentielle