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Titolo:
EFFECT OF COLD HARDENING ON THE COMPONENTS OF RESPIRATORY DECARBOXYLATION IN THE LIGHT AND IN THE DARK IN LEAVES OF WINTER RYE
Autore:
HURRY V; KEERBERG O; PARNIK T; OQUIST G; GARDESTROM P;
Indirizzi:
AUSTRALIAN NATL UNIV,COOPERAT RES CTR PLANT SCI,GPO BOX 475 CANBERRA ACT 2601 AUSTRALIA INST EXPTL BIOL EE-3051 KHARKU ESTONIA UMEA UNIV,DEPT PLANT PHYSIOL S-90187 UMEA SWEDEN
Titolo Testata:
Plant physiology
fascicolo: 3, volume: 111, anno: 1996,
pagine: 713 - 719
SICI:
0032-0889(1996)111:3<713:EOCHOT>2.0.ZU;2-4
Fonte:
ISI
Lingua:
ENG
Soggetto:
PYRUVATE-DEHYDROGENASE COMPLEX; RIBULOSE-1,5-BISPHOSPHATE CARBOXYLASE-OXYGENASE; SUCROSE-PHOSPHATE SYNTHASE; CARBON METABOLISM; LOW-TEMPERATURE; GLUTATHIONE-REDUCTASE; STARCHLESS MUTANT; HYDROGEN-PEROXIDE; MAIZE SEEDLINGS; CHILLING INJURY;
Tipo documento:
Article
Natura:
Periodico
Settore Disciplinare:
Science Citation Index Expanded
Citazioni:
49
Recensione:
Indirizzi per estratti:
Citazione:
V. Hurry et al., "EFFECT OF COLD HARDENING ON THE COMPONENTS OF RESPIRATORY DECARBOXYLATION IN THE LIGHT AND IN THE DARK IN LEAVES OF WINTER RYE", Plant physiology, 111(3), 1996, pp. 713-719

Abstract

In the dark, all decarboxylation reactions are associated with the oxidase reactions of mitochondrial electron transport. In the light, photorespiration is also active in photosynthetic cells. In winter rye (Secale cereale L.), cold hardening resulted in a P-fold increase in therate of dark respiratory CO2 release from leaves compared with nonhardened (NH) controls. However, in the light, NH and cold-hardened (CH) leaves had comparable rates of oxidase decarboxylation and total intracellular decarboxylation, Furthermore, whereas CH leaves showed similar rates of total oxidase decarboxylation in the dark and light, NH leaves showed a 2-fold increase in total oxidase activity in the light compared with the dark. Light suppressed oxidase decarboxylation of end products of photosynthesis 2-fold in NH leaves and 3-fold in CH leavesin air. However, in high-CO2, light did not suppress the oxidase decarboxylation of end products. Thus, the decrease in oxidase decarboxylation of end products observed in the light and in air reflected glycolate-cycle-related inhibition of tricarboxylic acid cycle activity. We also showed that the glycolate cycle was involved in the decarboxylation of the end products of photosynthesis in both NH and CH leaves, suggesting a flow of fixed carbon out of the starch pool in the light.

ASDD Area Sistemi Dipartimentali e Documentali, Università di Bologna, Catalogo delle riviste ed altri periodici
Documento generato il 28/11/20 alle ore 12:15:49