Fate of Nodule-Specific Polysaccharide Produced by Bradyrhizobium japonicum Bacteroids.

A polysaccharide produced by Bradyrhizobium japonicum bacteroids in nodules (NPS) on soybean (Glycine max [L.] Merr.) roots is different in composition and structure from the extracellular polysaccharide produced in culture by this organism. Isogenic strains either capable or incapable of NPS synthesis supported similar rates of plant growth and nitrogenase activity, indicating that polysaccharide deposition was not detrimental. The possibility that NPS may have some protective or nutritional role for bacteroids was considered. Analysis of disintegrating nodules over periods of 1 to 3 months indicated greater recovery of viable bacteria from NPS+ nodules prior to the breakdown of NPS. During and after the breakdown of NPS, the decline in viable bacteria was similar for NPS+ and NPS- strains. Bacteroid destruction in senescing nodules may be accelerated by exposure to proteolytic enzymes in host cytoplasm; however, highly purified NPS had no significant effect on the in vitro activity of partially purified proteases, so protection of bacteroids via this mechanism is unlikely. B. japonicum USDA 438 did not utilize NPS as a carbon source for growth in liquid culture. In vitro assays of NPS depolymerase activity in cultured bacteria and bacteroids were negative using a variety of strains, all of which contained extracellular polysaccharide depolymerase. It seems highly unlikely that B. japonicum can utilize the polysaccharide it synthesizes in nodules, and NPS breakdown in senescing nodules is probably caused by saprophytic fungi.

Proteolysis during Development and Senescence of Effective and Plant Gene-Controlled Ineffective Alfalfa Nodules.

Plant-controlled ineffective root nodules, conditioned by the in1 gene in Medicago sativa L. cv Saranac, undergo premature senescence and have reduced levels of many late nodulins. To ascertain which factors contribute to premature senescence, we have evaluated proteolysis as it occurs throughout the development of ineffective Saranac (in1Sa) and effective Saranac nodules. Cysteine protease activities with acidic pH optimum and enzyme proteins were present in both genotypes. We found that acidic protease activity was low in effective Saranac nodules throughout their development. In contrast, by 2 weeks after inoculation, acid protease activity of in1Sa nodules was severalfold higher than that of Saranac nodules and remained high until the experiment was terminated 8 weeks later. This increase in protease enzyme activity correlated with an increase in protease protein amounts. Increased protease activity and amount in in1Sa nodules was correlated with a decrease in nodule soluble protein. The time at which in1Sa nodules initially showed increased protease activity corresponded to when symbiosis deteriorated. High levels of phosphoenolpyruvate carboxylase (PEPC) protein were expressed in effective nodules by 12 d after inoculation and expression was associated with low proteolytic enzyme activity. In contrast, although PEPC was expressed in in1Sa nodules, PEPC protein was not found 12 d after inoculation and thereafter. Acidic protease from in1Sa nodules could also degrade purified leghemoglobin. These data indicate that premature senescence and low levels of late nodulins in in1Sa nodules can be correlated in part with increased proteolysis.

Localization of a protease in protoplast preparations in infected cells of French bean nodules.

Protoplasts from infected and uninfected cells were isolated from the central nitrogen fixing tissue of French bean (Phaseolus vulgaris L. cv Contender) root nodules. Successive filtrations allowed the separation of the infected cells, whereas the small uninfected cells were isolated on a discontinuous Percoll gradient. Higher yields of intact protoplasts were obtained from young (4-week-old) nodules whereas no protoplasts could be isolated from the oldest nodules. When proteolysis was determined in the cytosolic fraction of both infected and uninfected cells, at pH 5.0 and 8.0, with leghemoglobin or azocasein as substrate, activity was present only in infected cell protoplasts and increased with nodule age. A protease with an acidic pH optimum, mainly responsible for this increasing activity, was highly purified from senescing nodules by electro-elution after nondenaturing polyacrylamide gel electrophoresis and used to produce polyclonal antibodies. Western blots of nodule protein separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and probed with purified anti-protease immunoglobulin G showed the molecular mass of the protease to be 58 kilodaltons. Blots also confirmed that protease protein was located in infected cell protoplasts only, regardless of nodule age.