Members of the Rhizobiaceae contain 27-hydroxyoctacosanoic acid (27OHC 28:0 ) in their lipid A. A Rhizobium leguminosarum 3841 acpXL mutant (named here Rlv22) lacking a functional specialized acyl carrier lacked 27OHC 28:0 in its lipid A, had altered growth and physiological properties (e.g., it was unable to grow in the presence of an elevated salt concentration [0.5% NaCl]), and formed irregularly shaped bacteroids, and the synchronous division of this mutant and the host plant-derived symbiosome membrane was disrupted. In spite of these defects, the mutant was able to persist within the root nodule cells and eventually form, albeit inefficiently, nitrogen-fixing bacteroids. This result suggested that while it is in a host root nodule, the mutant may have some mechanism by which it adapts to the loss of 27OHC 28:0 from its lipid A. In order to further define the function of this fatty acyl residue, it was necessary to examine the lipid A isolated from mutant bacteroids. In this report we show that addition of 27OHC 28:0 to the lipid A of Rlv22 lipopolysaccharides is partially restored in Rlv22 acpXL mutant bacteroids. We hypothesize that R. leguminosarum bv. viciae 3841 contains an alternate mechanism (e.g., another acp gene) for the synthesis of 27OHC 28:0 , which is activated when the bacteria are in the nodule environment, and that it is this alternative mechanism which functionally replaces acpXL and is responsible for the synthesis of 27OHC 28:0 -containing lipid A in the Rlv22 acpXL bacteroids.Rhizobium leguminosarum cells have an envelope similar to that of other gram-negative bacteria. Lipopolysaccharide (LPS) is the primary component of the bacterial outer leaflet and is comprised of three structural regions: the O-chain polysaccharide, the core oligosaccharide, and lipid A. The lipid A region is anchored in the bacterial outer membrane, and the carbohydrate portion projects from the outer surface into the surrounding milieu and is the primary immunogenic determinant. Correlating LPS structure with function has been difficult as LPS is a very complex molecule and LPS preparations consist of structurally heterogeneous mixtures of molecules. There are pronounced variations in LPS structure from strain to strain, and even within a strain there are different sizes and compositions of LPS (23). Interestingly, there are marked differences between LPSs from free-living cultures and LPSs from nitrogen-fixing bacteroids in terms of size, composition, and antigenic properties (10,32,33). It has been shown that the rhizobial LPS undergoes structural modifications during the formation of bacteroids and that there are composition differences between the bacterial and bacteroid LPSs (10, 32).Variation in LPS structure due to environmental changes has been studied in cultured rhizobia by altering the growth conditions, such as lowering the oxygen level, lowering the pH, altering the carbon source, or adding plant-derived compounds (2,14,21,23,27). Such studies have shown that cues from the environment play an import...
