Carbohydrate Kinase (RhaK)-Dependent ABC Transport of Rhamnose in Rhizobium leguminosarum Demonstrates Genetic Separation of Kinase and Transport Activities
In Rhizobium leguminosarum the ABC transporter responsible for rhamnose transport is dependent on RhaK, a sugar kinase that is necessary for the catabolism of rhamnose. This has led to a working hypothesis that RhaK has two biochemical functions: phosphorylation of its substrate and affecting the activity of the rhamnose ABC transporter. To address this hypothesis, a linkerscanning random mutagenesis of rhaK was carried out. Thirty-nine linker-scanning mutations were generated and mapped. Alleles were then systematically tested for their ability to physiologically complement kinase and transport activity in a strain carrying an rhaK mutation. The rhaK alleles generated could be divided into three classes: mutations that did not affect either kinase or transport activity, mutations that eliminated both transport and kinase activity, and mutations that affected transport activity but not kinase activity. Two genes of the last class (rhaK72 and rhaK73) were found to have similar biochemical phenotypes but manifested different physiological phenotypes. Whereas rhaK72 conferred a slow-growth phenotype when used to complement rhaK mutants, the rhaK73 allele did not complement the inability to use rhamnose as a sole carbon source. To provide insight to how these insertional variants might be affecting rhamnose transport and catabolism, structural models of RhaK were generated based on the crystal structure of related sugar kinases. Structural modeling suggests that both rhaK72 and rhaK73 affect surface-exposed residues in two distinct regions that are found on one face of the protein, suggesting that this protein's face may play a role in protein-protein interaction that affects rhamnose transport. C ells require a specific and regulated way to transport substrates across membranes. One of the largest families of transporters is the ATP binding cassette (ABC) transporters. ABC transporters utilize free energy from ATP hydrolysis to transport substrates across a membrane. They are widely distributed in all domains of life and are involved in transport that affects diverse biological functions (1-3).Members of the ABC superfamily are defined by the ATPase protein that contains the Walker A and Walker B motifs, along with an LSGGQ conserved consensus sequence (4, 5). Functional ABC importers generally consist of two proteins that have transmembrane domains consisting of six membrane-spanning regions (permeases), two ABC proteins that are cytoplasmically localized and contain the ATP binding domains, and a periplasmically localized substrate binding protein for the function of the transport system (6). Relatively few sequence similarities are found between binding proteins for different substrates as the periplasmic substrate binding protein plays a central role in substrate specificity (7).Gram-negative bacterial ABC transport systems responsible for the import of carbohydrates can be broken into two main classes: carbohydrate uptake transporters 1 and 2 (CUT1 and -2, respectively) (8). Most work on bacterial carbohydrate...
The Sugar Kinase That Is Necessary for the Catabolism of Rhamnose in Rhizobium leguminosarum Directly Interacts with the ABC Transporter Necessary for Rhamnose Transport
Rhamnose catabolism in Rhizobium leguminosarum was found to be necessary for the ability of the organism to compete for nodule occupancy. Characterization of the locus necessary for the catabolism of rhamnose showed that the transport of rhamnose was dependent upon a carbohydrate uptake transporter 2 (CUT2) ABC transporter encoded by rhaSTPQ and on the presence of RhaK, a protein known to have sugar kinase activity. A linker-scanning mutagenesis analysis of rhaK showed that the kinase and transport activities of RhaK could be separated genetically. More specifically, two pentapeptide insertions defined by the alleles rhaK72 and rhaK73 were able to uncouple the transport and kinase activities of RhaK, such that the kinase activity was retained, but cells carrying these alleles did not have measurable rhamnose transport rates. These linker-scanning alleles were localized to the C terminus and N terminus of RhaK, respectively. Taken together, the data led to the hypothesis that RhaK might interact either directly or indirectly with the ABC transporter defined by rhaSTPQ. In this work, we show that both N-and C-terminal fragments of RhaK are capable of interacting with the N-terminal fragment of the ABC protein RhaT using a 2-hybrid system. Moreover, if RhaK fragments carrying either the rhaK72 or rhaK73 allele were used, this interaction was abolished. Phylogenetic and bioinformatic analysis of the RhaK fragments suggested that a conserved region in the N terminus of RhaK may represent a putative binding domain. Alanine-scanning mutagenesis of this region followed by 2-hybrid analysis revealed that a substitution of any of the conserved residues greatly affected the interaction between RhaT and RhaK fragments, suggesting that the sugar kinase RhaK and the ABC protein RhaT interact directly. IMPORTANCEABC transporters involved in the transport of carbohydrates help define the overall physiological fitness of bacteria. The two largest groups of transporters are the carbohydrate uptake transporter classes 1 and 2 (CUT1 and CUT2, respectively). This work provides the first evidence that a kinase that is necessary for the catabolism of a sugar can directly interact with a domain from the ABC protein that is necessary for its transport. C ells are separated from the external environment by a selectively permeable membrane. A means to transport physiologically relevant substrates across these membranes is required (1-3). The largest and most widely distributed family of transporters is the ATP binding cassette (ABC) transporters (1). ABC transporters are responsible for the transport of a very diverse set of substrates and can be broken into two main classes, importers and exporters (1, 3-5). Much of our understanding of the structure, mechanism, and kinetics of these systems has been derived from the study of relatively few model transporters (6).Gram-negative ABC importers typically consist of a permease component that is made up of two membrane-spanning proteins (encoded by either one or two genes), a periplasm...
Rhizobium leguminosarum strains unable to grow on rhamnose as a sole carbon source are less competitive for nodule occupancy. To determine if the ability to use rhamnose as a sole carbon source affects competition for nodule occupancy in Sinorhizobium meliloti, Tn5 mutants unable to use rhamnose as a sole carbon source were isolated. S. meliloti mutations affecting rhamnose utilization were found in two operons syntenous to those of R. leguminosarum. Although the S. meliloti Tn5 mutants were complemented using an R. leguminosarum cosmid that contains the entire wild-type rhamnose catabolic locus, complementation did not occur if the cosmids carried Tn5 insertions within the locus. Through a series of heterologous complementation experiments, enzyme assays, gene fusion, and transport experiments, we show that the S. meliloti regulator, RhaR, is dominant to its R. leguminosarum counterpart. In addition, the data support the hypothesis that the R. leguminosarum kinase is capable of directly phosphorylating rhamnose and rhamnulose, whereas the S. meliloti kinase does not possess rhamnose kinase activity. In nodule competition assays, S. meliloti mutants incapable of rhamnose transport were shown to be less competitive than the wild-type and had a decreased ability to bind plant roots in the presence of rhamnose. The data suggests that rhamnose catabolism is a general determinant in competition for nodule occupancy that spans across rhizobial species.
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