DNA, RNA, AND PROTEIN COMPARISONS BETWEEN NODULATED AND NON‐NODULATED MALE‐STERILE AND MALE‐FERTILE GENOTYPES OF SOYBEAN (GLYCINE MAX L.)

Abstract

Four soybean (Glycine max L. Merr.) lines isogenic except for loci controlling male sterility (ms1) and nodulation (rj1) were developed to study the effects of reproductive development and nitrogen source on the nucleic acid and protein levels within the leaves. Changes in DNA, RNA, protein, and cellular viability were measured from flowering (77 days after emergence) until maturity (147 days after emergence) in leaves of nodulated and non‐nodulated male‐sterile and fertile soybean genotypes. Leaf nuclei from the sterile genotypes yielded DNA amounts that were significantly higher than those from the fertile lines. The average DNA values for the nodulated sterile and nodulated fertile lines at 147 days after emergence were 7.01 and 2.45 picograms, respectively. The average 2C DNA amount as determined from dividing root‐tip nuclei was 2.83 picograms, which indicated occurrence of endopolyploid mechanisms in the sterile lines and age‐related loss of DNA in fertile lines. Similar to DNA findings, the RNA and protein values in the sterile lines were significantly higher than those values observed in the fertile lines, suggesting an increased capacity to synthesize protein. The soybean leaf nuclear DNA declined, especially in the fertile lines in terms of the percent endopolyploid nuclei as well as the average DNA content during maturation. The DNA decline in leaves of fertile genotypes suggests that the leaves may be exporting nucleosides and phosphates to the seeds during embryo formation. In the sterile lines, due to the reduced pod‐set, these ready reserves of nucleosides and phosphates tended to accumulate in the chromatin of the leaf nucleus as manifested by the DNA specific Feulgen stain.By the end of the study (147 days after emergence), the nodulated fertile genotypes had experienced a dramatic loss in DNA, RNA, and protein. The nodulated sterile genotypes, however, indicated 65% more DNA, 59% more RNA, and 53% more protein as compared to the nodulated fertile genotypes at 147 days after emergence. The sterile lines also indicated the slowest increase in the death of cells, while the fertile lines indicated the fastest increase in nonviable cells, as shown by trypan blue staining. The fertile lines displayed normal monocarpic senescence throughout the study. The reproductive structures of fertile plants utilized the molecules in seed production, whereas in the sterile lines, these accumulated in leaf cells.