Differentiation of Nodules of Glycine Max : Ultrastructural Studies of Plant Cells and Bacteroids

Overview

Journal Planta

Specialty Biology

Date 2014 Jan 14

PMID 24414773

Citations 10

Authors

D Werner

E Morschel

Affiliations

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Abstract

Plants of Glycine max var. Caloria, infected as 14 d old seedlings with a defined titre of Rhizobium japonicum 3Il b85 in a 10 min inoculation test, develop a sharp maximum of nitrogenase activity between 17 and 25 d after infection. This maximum (14±3 nmol C2H4 h(-1) mg nodule fresh weight(-1)), expressed as per mg nodule or per plant is followed by a 15 d period of reduced nitrogen fixation (20-30% of peak activity). 11 d after infection the first bacteroids develop as single cells inside infection vacuoles in the plant cells, close to the cell wall and infection threads. As a cytological marker for peak multiplication of bacteroids and for peak N2-fixation a few days later the association of a special type of nodule mitochondria with amyloplasts is described. 20 d after inoculation, more than 80% of the volume of infected plant cells is occupied by infection vacuoles, mostly containing only one bacteroid. The storage of poly-β-hydroxybutyrate starts to accumulate at both ends of the bacteroids. Non infected plant cells are squeezed between infected cells (25d), with infection vacuoles containing now more than two (up to five) bacteroids per section. Bacteroid development including a membrane envelope is also observed in the intercellular space between plant cells. 35 d after infection, more than 50% of the bacteroid volume is occupied by poly-β-hydroxybutyrate. The ultrastructural differentiation is discussed in relation to some enzymatic data in bacteroids and plant cell cytoplasm during nodule development.

Citing Articles

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Development of nodules of Glycine max infected with an ineffective strain of Rhizobium japonicum.

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Leghaemoglobin within bacteroid-enclosing membrane envelopes from soybean root nodules.

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