Multiple marker abundance profiling:combining selected reaction monitoring and data-dependent acquisition for rapid estimation of organelle abundance in subcellular samples

Measuring changes in protein or organelle abundance in the cell is an essential, but challenging aspect of cell biology. Frequently-used methods for determining organelle abundance typically rely on detection of a very few marker proteins, so are unsatisfactory. In silico estimates of protein abundances from publicly available protein spectra can provide useful standard abundance values but contain only data from tissue proteomes, and are not coupled to organelle localization data. A new protein abundance score, the normalized protein abundance scale (NPAS), expands on the number of scored proteins and the scoring accuracy of lower-abundance proteins in Arabidopsis. NPAS was combined with subcellular protein localization data, facilitating quantitative estimations of organelle abundance during routine experimental procedures. A suite of targeted proteomics markers for subcellular compartment markers was developed, enabling independent verification of in silico estimates for relative organelle abundance. Estimation of relative organelle abundance was found to be reproducible and consistent over a range of tissues and growth conditions. In silico abundance estimations and localization data have been combined into an online tool, multiple marker abundance profiling, available in the SUBA4 toolbox (http://suba.live)

Opine utilization by Agrobacterium spp.: octopine-type Ti plasmids encode two pathways for mannopinic acid degradation.

Octopine-type strains of Agrobacterium tumefaciens degrade the opine mannopinic acid through a specific pathway which involves cleavage of the molecule at the C--N bond between the amino acid and the sugar moieties. Mannose was identified as a product of the reaction. This pathway was inducible by mannopinic and agropinic acids, but not by mannopine or agropine, the two other mannityl opines. The transport system for this pathway appeared to be specific for mannopinic acid. A second, nonspecific pathway for mannopinic acid degradation was also identified. This involved some of the catabolic functions associated with the metabolism of mannopine and agropine. This second pathway was inducible by mannopine and agropine but not by mannopinic or agropinic acids. The transport system for this pathway appeared to have a broad specificity. Transposon Tn5 insertion mutants affected in the specific catabolic pathway were isolated and analyzed. These mutants continued to catabolize mannopine and agropine. Both mapped to a region of the Ti plasmid previously shown to be associated with the catabolism of mannopinic acid. Restriction enzyme analysis of the Ti plasmid from strain 89.10, an octopine strain that is naturally unable to utilize mannopinic acid, showed a deletion in this same region encoding the specific mannopinic acid degradation pathway. Analysis of recombinant clones showed that the second, nonspecific pathway was encoded in a region of the Ti plasmid associated with mannopine and agropine catabolism. This region shared no structural overlap with the segment of the plasmid encoding the specific mannopinic acid degradative pathway