The most conspicuous plant hemoglobins are the symbiotic hemoglobins of legumes; these hemoglobins accumulate in root nodules and give these specialized organs their distinctive red color. Legume root nodules accommodate bacteria, called rhizobia, that reduce atmospheric nitrogen to ammonia, which is subsequently used by the plant for growth and colonization of nitrogen-poor soils. Symbiotic nitrogen fixation is important for sustainable agriculture and contributes millions of tons of reduced nitrogen to crops and pastures each year.
As reported this week, researchers led by Dr. Michael Udvardi at the Max Planck Institute of Molecular Plant Physiology have succeeded in eliminating the production of symbiotic hemoglobins in nodules of the model legume Lotus japonicus, enabling researchers to assess for the first time the role and importance of these proteins in plants. The results of the study indicate that symbiotic hemoglobins are important for oxygen transport and energy metabolism in plant root nodules. Furthermore, these proteins help to maintain free-oxygen concentrations in nodules at levels low enough to avoid damage of oxygen-sensitive nitrogenase, the bacterial enzyme complex responsible for symbiotic nitrogen fixation. Thus, plant hemoglobins fulfill roles analogous to those of animal hemoglobins, as well as novel roles that are apparently unique to symbiotic nitrogen fixation.
Thomas Ott, Joost van Dongen, Catrin Günther, Lene Krusell, Guilhem Desbrosses,1 Helene Vigeolas, Vivien Bock, Tomasz Czechowski, Peter Geigenberger, and Michael K. Udvardi: "Symbiotic Leghemoglobins Are Crucial for Nitrogen Fixation in Legume Root Nodules but Not for General Plant Growth and Development"
The members of the research team include Thomas Ott, Joost van Dongen, Catrin Günther, Lene Krusell, Helene Vigeolas, Vivien Bock, Tomasz Czechowski, Peter Geigenberger, and Michael K. Udvardi of the Max Planck Institute of Molecular Plant Physiology; and Guilhem Desbrosses of the Max Planck Institute of Molecular Plant Physiology and presently at Université Montpellier. This work was partly funded by Max Planck Society, the Deutsche Forschungsgemeinschaft, and the European Union.
Publishing in Current Biology, Volume 15, Number 6, March 29, 2005, pages 531-535. http://www.