Revised primary structures of rat pituitary gamma-lipotrophin and beta-endorphin.

In-depth investigations, by high performance liquid chromatographic purification, radio-immunoassay, mass spectrometry, tandem mass spectrometry, Edman sequencing and limited C-terminal ladder sequencing, were prompted by mass spectrometric charting experiments which suggested that the amino acid sequences for rat gamma-lipotrophin and beta-endorphin require revision. The results for gamma-lipotrophin identify a histidine for glutamine substitution at position 12, and heterogeneity in the expressed protein presumably due to partial dehydration. Partial dehydration for acidic joining peptide, previously reported by Toney et al was corroborated.

Proferrorosamines and phytopathogenicity in Erwinia spp.

Proferrorosamine A (pFR A) of the plant pathogenic bacterium Erwinia rhapontici was shown to inhibit growth of wheat and cress seedlings at the > or = 10 ppm level. When the seeds were continuously exposed to 100 ppm pFR A, the germination of cress and wheat seeds was inhibited up to 90% and 80%, respectively. The inhibition could be reversed through addition of equimolar amounts of ferrous iron, which indicates that the strong iron chelating capability of pFR A is responsible for the observed effect.

Proferrioxamine synthesis in Erwinia amylovora in response to precursor or hydroxylysine feeding: metabolic profiling with liquid chromatography-electrospray mass spectrometry.

Metabolic profiling by capillary liquid chromatography-electrospray mass spectrometry was used to monitor shifts in the proferrioxamine profiles of Erwinia amylovora in response to externally supplied potential proferrioxamine precursors, selected stable-isotope-labeled precursors and atypical precursors. Based on the qualitative and quantitative shifts in the proferrioxamine profiles, lysine and arginine are unambiguous, and agmatine, ornithine, diaminobutyric acid and the corresponding C3-5 diamines are highly likely precursors for proferrioxamine biosynthesis in E. amylovora.

On the collision-activated fragmentation of proferrioxamines: Evidence for a succinimide-mediated mechanism.

The fragmentation mechanism of acyclic proferrioxamines has been studied by tandem mass spectrometry in a triple stage quadrupole mass analyzer by using activation in the collision cell as well as in the high pressure region prior to the first mass analyzer. The data suggest that proferrioxamines fragment preferentially at the hydroxamate bonds via cyclic rearrangement to succinimide derivatives. This pattern was observed most clearly for the peracetyl derivatives, in which the influence of terminal functional groups was masked.

Metabolism of polyamines and basic amino acids in Erwinia amylovora: application of liquid chromatography/electrospray mass spectrometry to proferrioxamine precursor feeding and inhibition studies.

Erwinia amylovora, the etiological agent of fire blight, produces a family of proferrioxamine siderophores, which may be essential for the pathogen to establish itself in its hosts. If so, then control of fire blight may perhaps be possible via interference with proferrioxamine biosynthesis. Proof of this hypothesis requires prior knowledge of the corresponding biosynthetic pathways in E.