Cj. Baker et al., Oxygen metabolism in plant/bacteria interactions: characterization of the oxygen uptake response of plant suspension cells, PHYSL MOL P, 57(4), 2000, pp. 159-167
In recent years the accumulation of reactive oxygen species (ROS) has been
studied in plant cell suspension systems treated with bacterial pathogens.
However, the associated utilization of molecular oxygen has not been well c
haracterized. Using a multi-electrode oxygen analyser, the rates of oxygen
consumption by tobacco cells during bacterial interactions were monitored.
Heat-killed (HK) bacteria, which initiate an immediate ROS response in plan
t cells, were used as an elicitor to avoid complications of oxygen consumpt
ion by viable bacteria. An increase in oxygen uptake by the tobacco cells o
ccurred within 4 min after addition of HK-bacteria and lasted for about 10
min, returning to a steady state at approximately twice the initial basal r
ate. The initial burst in oxygen uptake coincided with production of H2O2.
Calculation of the total oxygen consumption by the plant cells indicated th
at less than 5 % of the increased oxygen uptake was utilized in ROS product
ion. Use of respiratory inhibitors indicated that respiration, especially t
he cytochrome pathway, played a significant role in this response. Results
from the use of K-252, a protein kinase inhibitor, and DPI, an inhibitor of
membrane bound NADPH oxidases, indicated that triggering of the oxygen upt
ake response may involve protein phosphorylation and is at least partially
activated by the membrane bound NADPH oxidase activity. The involvement of
mitochondrial respiration in the oxygen uptake response described here indi
cates that early events in plant recognition of pathogens involves more of
the cellular machinery than previously hypothesized.