Kenneth A. Chapman scite author profile

We isolated the ntrC gene from Bradyrhizobiumjaponicum, the endosymbiont of soybean (Glycine max), and examined its role in regulating nitrogen assimilation. Two independent ntrC mutants were constructed by gene replacement techniques. One mutant was unable to produce NtrC protein, while the other constitutively produced a stable, truncated NtrC protein. Both ntrC mutants were unable to utilize potassium nitrate as a sole nitrogen source. In contrast to wild-type B. japonicum, the NtrC null mutant lacked ginII transcripts in aerobic, nitrogen-starved cultures. However, the truncated-NtrC mutant expressed glnIl in both nitrogenstarved and nitrogen-excess cultures. Both mutants expressed glnll under oxygen-limited culture condiftions and in symbiotic cells. These results suggest that nitrogen assimilation in B. japonicum is regulated in response to both nitrogen limitation and oxygen limitation and that separate regulatory networks exist in free-living and symbiotic cells.

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Interactions of T7 RNA polymerase with T7 late promoters measured by footprinting with methidiumpropyl-EDTA-iron(II)

Gunderson¹,

Chapman²,

Burgess³

1987

Biochemistry

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The interactions of T7 RNA polymerase with T7 late promoters were studied by using quantitative footprinting with methidiumpropyl-EDTA X Fe(II) [MPE-Fe(II)] as the DNA cleaving agent. Class II and class III T7 promoters have a highly conserved 23 base pair sequence from -17 to +6. Among class III promoters the -22 to -18 region is also highly conserved. For a class II promoter, T7 RNA polymerase protects the -17 to -4 region from MPE-Fe(II) cleavage; when GTP is present, protection extends from -17 to +5 (noncoding strand). For a class III promoter, protection extends from -20 to -4 and in the presence of GTP from -20 to +5 (noncoding strand). The protected regions for the coding strands of both promoters were nearly identical with that seen for the noncoding strands. The binding constant for the class III promoter is (4 +/- 1.5) X 10(7) M-1 and in the presence of GTP increases to (10 +/- 1.7) X 10(7) M-1. These binding constants are about 1000 and 200 times greater, respectively, than values reported previously [Ikeda, R. A., & Richardson, C. C. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 3614-3618]. The differences in binding constants are probably due to tRNA and high salt used in those earlier experiments. Both tRNA and high salt (greater than 50 mM NaCl and greater than 10 mM MgCl2) inhibit the binding of the polymerase to the promoter. Optimal binding conditions occur at 2-5 mM MgCl2 and 0-10 mM NaCl.(ABSTRACT TRUNCATED AT 250 WORDS)

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Construction of bacteriophage T7 late promoters with point mutations and characterization byin vitrotranscription properties

Chapman

Burgess

1987

Nucl Acids Res

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This paper describes the construction of 18 cloned bacteriophage T7 late promoters with single point mutations. In vitro transcription experiments were used to characterize the properties of these promoters. Since the mutated promoters are cloned into identical backgrounds, differences seen in the transcription assays are directly attributable to the point mutations. All of the mutated promoters are less active than wildtype, but they can be divided into two types. Type A mutations map from -4 to +1 and reduce promoter activity when the template is linearized or when 60mM NaCl is added to the reaction buffer. Type B mutations map from -9 to -7 and reduce promoter activity under all conditions tested. At several sites all three possible point mutations are available. At these sites we observed hierarchies of base pair preference, as determined by promoter activity, that may indicate that T7 RNA polymerase interacts with groups in the major groove.

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Rhizobium lipopolysaccharide modulates infection thread development in white clover root hairs

et al. 1991

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The interaction between Rhizobium lipopolysaccharide (LPS) and white clover roots was examined. The Limulus lysate assay indicated that Rhizobium leguminosarum bv. trifolii (hereafter called R. trifolii) released LPS into the external root environment of slide cultures. Immunofluorescence and immunoelectron microscopy showed that purified LPS from R. tnifolii 0403 bound rapidly to root hair tips and infiltrated across the root hair wall. Infection thread formation in root hairs was promoted by preinoculation treatment of roots with R. trifolii LPS at a low dose (up to 5 ,ug per plant) but inhibited at a higher dose. This biological activity of LPS was restricted to the region of the root present at the time of exposure to LPS, higher with LPS from cells in the early stationary phase than in the mid-exponential phase, incubation time dependent, incapable of reversing inhibition of infection by N03 or NH4', and conserved among serologically distinct LPSs from several wild-type R. trifolii strains (0403, 2S-2, and ANU843). In contrast, infections were not increased by preinoculation treatment of roots with LPSs from R. leguminosarum bv. viciae strain 300, R. meliloti 102F28, or members of the family Enterobacteriaceae. Most infection threads developed successfully in root hairs pretreated with R. trifolii LPS, whereas many infections aborted near their origins and accumulated brown deposits if pretreated with LPS from R. meliloti 102F28. LPS from R. leguminosarum 300 also caused most infection threads to abort. Other specific responses of root hairs to infection-stimulating LPS from R. trifolii included acceleration of cytoplasmic streaming and production of novel proteins. Combined gas chromatography-mass spectroscopy and proton nuclear magnetic resonance analyses indicated that biologically active LPS from R. trifolii 0403 in the early stationary phase had less fucose but more 2-0-methylfucose, quinovosamine, 3,6-dideoxy-3-(methylamino)galactose, and noncarbohydrate substituents (0-methyl, N-methyl, and acetyl groups) on glycosyl components than did inactive LPS in the mid-exponential phase. We conclude that LPS-root hair interactions trigger metabolic events that have a significant impact on successful development of infection threads in this Rhizobium-legume symbiosis.Establishment of an effective Rhizobium-legume symbiosis can be viewed as a process of cellular recognition and compatibility between bacterial and plant cells. The infection process involves bacterial attachment, root hair deformation, bacterial penetration of the root hair wall, formation and sustained development of the infection thread, bacterial release from infection threads within emerging root nodule cells, and bacterial differentiation into nitrogen-fixing bacteroids.The lipopolysaccharides (LPS) of rhizobia are likely to be involved in the infection process. They are major glycoconjugates on the surface of Rhizobium leguminosarum biovars * Corresponding author. t Present address: Laboratoire des Relationes Plantes-Microorganismes,

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Bacteriophage T7 late promoters with point mutations: quantitative footprinting andin vivoexpression

et al. 1988

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