Putting the Pieces Together: High-performance LC-MS/MS Provides Network-, Pathway-, and Protein-level Perspectives in Populus

Abraham, Paul E.; Giannone, Richard J.; Adams, Rachel M; Kalluri, Udaya C.; Tuskan, Gerald A.; Hettich, Robert L.

doi:10.1074/mcp.m112.022996

Cited by 27 publications

(27 citation statements)

References 55 publications

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“…Clearly, therefore, comprehensive proteomic profiling at high spatial resolution could not only pinpoint changes in levels of key proteins during wood formation, but also provide important indications of the pathways and key regulatory switches involved. However, characterization of protein expression in plant stems is complicated by the heterogeneous mixtures of cell types and the dynamic range in protein abundance across developmental zones (Abraham et al, 2013 [ 10 ]; Qiu et al, 2013 [ 11 ]). Partly for this reason previous studies on wood development have generally focused on one or a few developmental gradients, relatively large sections, or tissue samples collected from a few positions in developmental sequences (Gion et al, 2005 [ 1 ]; Mishima et al, 2014 [ 2 ]; Hertzberg et al, 2001 [ 3 ]; Tuskan et al, 2006 [ 4 ]; Kalluri et al, 2009 [ 5 ]; Nilsson et al, 2010 [ 6 ]; Zhong et al, 2007 [ 7 ]).…”

Section: Introductionmentioning

confidence: 99%

Quantitative proteomics reveals protein profiles underlying major transitions in aspen wood development

et al. 2016

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BackgroundWood development is of outstanding interest both to basic research and industry due to the associated cellulose and lignin biomass production. Efforts to elucidate wood formation (which is essential for numerous aspects of both pure and applied plant science) have been made using transcriptomic analyses and/or low-resolution sampling. However, transcriptomic data do not correlate perfectly with levels of expressed proteins due to effects of post-translational modifications and variations in turnover rates. In addition, high-resolution analysis is needed to characterize key transitions. In order to identify protein profiles across the developmental region of wood formation, an in-depth and tissue specific sampling was performed.ResultsWe examined protein profiles, using an ultra-performance liquid chromatography/quadrupole time of flight mass spectrometry system, in high-resolution tangential sections spanning all wood development zones in Populus tremula from undifferentiated cambium to mature phloem and xylem, including cell expansion and cell death zones. In total, we analyzed 482 sections, 20–160 μm thick, from four 47-year-old trees growing wild in Sweden. We obtained high quality expression profiles for 3,082 proteins exhibiting consistency across the replicates, considering that the trees were growing in an uncontrolled environment. A combination of Principal Component Analysis (PCA), Orthogonal Projections to Latent Structures (OPLS) modeling and an enhanced stepwise linear modeling approach identified several major transitions in global protein expression profiles, pinpointing (for example) locations of the cambial division leading to phloem and xylem cells, and secondary cell wall formation zones. We also identified key proteins and associated pathways underlying these developmental landmarks. For example, many of the lignocellulosic related proteins were upregulated in the expansion to the early developmental xylem zone, and for laccases with a rapid decrease in early xylem zones. We observed upregulation of two forms of xylem cysteine protease (Potri.002G005700.1 and Potri.005G256000.2; Pt-XCP2.1) in early xylem and their downregulation in late maturing xylem. Our data also show that Pt-KOR1.3 (Potri.003G151700.2) exhibits an expression pattern that supports the hypothesis put forward in previous studies that this is a key xyloglucanase involved in cellulose biosynthesis in primary cell walls and reduction of cellulose crystallinity in secondary walls.ConclusionOur novel multivariate approach highlights important processes and provides confirmatory insights into the molecular foundations of wood development.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-016-2458-z) contains supplementary material, which is available to authorized users.

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Section: Introductionmentioning

confidence: 99%

Quantitative proteomics reveals protein profiles underlying major transitions in aspen wood development

et al. 2016

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“…The development of MS with high resolution, high mass accuracy, and high sequencing speed now allows routine identification and quantification of proteins in a comprehensive and unbiased manner in biological samples with high confidence (32). These technological advances in LC-MS now allow the study of protein expression on a system-wide level (33). Therefore, an in-depth characterization of the proteome changes during the honey bee embryogenesis will provide greater understanding of the molecular mechanisms that underlie the process of embryogenesis in honey bee workers, and offers new insights into the embryology of other social insects.…”

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confidence: 99%

In-depth Proteomics Characterization of Embryogenesis of the Honey Bee Worker (Apis mellifera ligustica)

Mao

Han

et al. 2014

Molecular & Cellular Proteomics

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Identifying proteome changes of honey bee embryogenesis is of prime importance for unraveling the molecular mechanisms that they underlie. However, many proteomic changes during the embryonic period are not well characterized. We analyzed the proteomic alterations over the complete time course of honey bee worker embryogenesis at 24, 48, and 72 h of age, using mass spectrometry-based proteomics, label-free quantitation, and bioinformatics. Of the 1460 proteins identified the embryo of all three ages, the core proteome (proteins shared by the embryos of all three ages, accounting for 40%) was mainly involved in protein synthesis, metabolic energy, development, and molecular transporter, which indicates their centrality in driving embryogenesis. However, embryos at different developmental stages have their own specific proteome and pathway signatures to coordinate and modulate developmental events. The young embryos (<24 h) stronger expression of proteins related to nutrition storage and nucleic acid metabolism may correlate with the cell proliferation occurring at this stage. The middle aged embryos (24 -48 h) enhanced expression of proteins associated with cell cycle control, transporters, antioxidant activity, and the cytoskeleton suggest their roles to support rudimentary organogenesis. Among these proteins, the biological pathways of aminoacyl-tRNA biosynthesis, ␤-alanine metabolism, and protein export are intensively activated in the embryos of middle age. The old embryos (48 -72 h) elevated expression of proteins implicated in fatty acid metabolism and morphogenesis indicate their functionality for the formation and development of organs and dorsal closure, in which the biological pathways of fatty acid metabolism and RNA transport are highly activated. These findings add novel understanding to the molecular details of honey bee embryogenesis, in which the programmed activation of the proteome matches with the physiological transition observed during embryogenesis. The identified biological pathways and key node proteins allow for further functional analysis and genetic manipulation for both the honey bee embryos and other eusocial insects. Molecular & Cellular Proteomics 13:

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“…The mapping analysis consisted of 300 HPLC‐MS/MS runs which generated 1 457 281 matched spectra at 2% false discovery rate (FDR) representing 89 754 unique peptides when searched against the IWGSC1.0 + popseq 28 peptide sequence database. This depth of analysis is equivalent to studies conducted in Arabidopsis (Baerenfaller et al ., ) (86 456 unique peptides) and Poplar (Abraham et al ., ) (63 056). Our use of Q‐TOF rather than TRAP mass spectrometry provides higher resolution, full range MS/MS spectra for each peptide.…”

Section: Resultsmentioning

confidence: 99%

“…Mature harvested grain was imbibed and incubated for 24 h before dissecting the embryo, endosperm and pericarp ( Figure 1d). (Abraham et al, 2013) (63 056). Our use of Q-TOF rather than TRAP mass spectrometry provides higher resolution, full range MS/MS spectra for each peptide.…”

Section: Spatial and Developmental Dissection Of The Wheat Proteomementioning

confidence: 99%

Resource: Mapping the Triticum aestivum proteome

et al. 2017

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Yield and quality improvement of bread wheat (Triticum aestivum) is a focus in efforts to meet new demands from population growth and changing human diets. As the complexity of the wheat genome is unravelled, determining how it is used to build the protein machinery of wheat plants is a key next step in explaining detailed aspects of wheat growth and development. The specific functions of wheat organs during vegetative development and the role of metabolism, protein degradation and remobilisation in driving grain production are the foundations of crop performance and have recently become accessible through studies of the wheat proteome. We present a large scale, publicly accessible proteome mapping of wheat consisting of 24 organ and developmental samples. Tissue specific sub-proteomes and ubiquitously expressed markers of the wheat proteome are identified, alongside hierarchical assessment of protein functional classes, their presence in different tissues and correlations between the abundance of functional classes of proteins. Gene-specific identifications and protein family relationships are accounted for in the organisation of the data and 202 new protein-coding transcripts identified by proteogenomic mapping. The interactive database will serve as a vehicle to build, refine and deposit confirmed targeted proteomic assays for wheat proteins and protein families to assess function (www.wheatproteome.org).

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Putting the Pieces Together: High-performance LC-MS/MS Provides Network-, Pathway-, and Protein-level Perspectives in Populus

Cited by 27 publications

References 55 publications

Quantitative proteomics reveals protein profiles underlying major transitions in aspen wood development

Quantitative proteomics reveals protein profiles underlying major transitions in aspen wood development

In-depth Proteomics Characterization of Embryogenesis of the Honey Bee Worker (Apis mellifera ligustica)

Resource: Mapping the Triticum aestivum proteome

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