Valeria Pallotta scite author profile

Nibrin (also named NBN or NBS1) is a component of the MRE11/RAD50/NBN complex, which is involved in early steps of DNA double strand breaks sensing and repair. Mutations within the NBN gene are responsible for the Nijmegen breakage syndrome (NBS). The 90% of NBS patients are homozygous for the 657del5 mutation, which determines the synthesis of two truncated proteins of 26 kDa (p26) and 70 kDa (p70). Here, HEK293 cells have been exploited to transiently express either the full-length NBN protein or the p26 or p70 fragments, followed by affinity chromatography enrichment of the eluates. The application of an unsupervised proteomics approach, based upon SDS-PAGE separation and shotgun digestion of protein bands followed by MS/MS protein identification, indicates the occurrence of previously unreported protein interacting partners of the full-length NBN protein and the p26 fragment containing the FHA/BRCT1 domains, especially after cell irradiation. In particular, results obtained shed light on new possible roles of NBN and of the p26 fragment in ROS scavenging, in the DNA damage response, and in protein folding and degradation. In particular, here we show that p26 interacts with PARP1 after irradiation, and this interaction exerts an inhibitory effect on PARP1 activity as measured by NAD+ levels. Furthermore, the p26-PARP1 interaction seems to be responsible for the persistence of ROS, and in turn of DSBs, at 24 h from IR. Since some of the newly identified interactors of the p26 and p70 fragments have not been found to interact with the full-length NBN, these interactions may somehow contribute to the key biological phenomena underpinning NBS.

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Native Protein Complexes in the Cytoplasm of Red Blood Cells

Pallotta

D’Alessandro

Rinalducci

et al. 2013

J. Proteome Res.

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Despite decades of advancements, the investigation of the red blood cell (RBC) cytosolic proteome still represents a challenging task because of the overwhelming abundance of hemoglobin. Besides, the separation method is one of the main limiting factors when investigating protein complexes. In this study, we performed for the first time a 2D-clear native (CN)-SDS-PAGE followed by mass spectrometry-based identification to screen multiprotein complexes (MCPs) in the cytosol of human RBCs. Upstream to 2D-CN-SDS-PAGE, we applied a recently developed native pre-enrichment strategy that allows discriminating and separately collecting three distinct fractions, one of which is highly enriched for hemoglobin. Such prefractionation strategy is conservative, in that it makes soluble native-complex analyses amenable without loss of biological information. Because of the resolution of native gel electrophoresis techniques, we could observe and describe 55 potential hetero-oligomeric MPCs from the RBC native cytosolic proteome, among which ultratetrameric hemoglobin. The detected protein complexes were characterized by proteins mainly involved in oxygen transport, antioxidant responses, metabolism, and protein degradation cascades, in agreement with recent in silico models. Metabolic enzyme oligomers also interacted with complexes of proteins involved in oxidative stress responses, thus suggesting a functional relationship between metabolic modulation and antioxidant defenses.

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Red blood cell storage affects the stability of cytosolic native protein complexes

2015

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The use of native gel-based proteomics to investigate MPCs present in the RBC cytosolic fraction proved to be a powerful tool. Results collected represent a preliminary advance in the knowledge of the key role of native cytosolic MPCs in context of RBC storage lesion. Multiprotein organization and interacting partners of some key enzymes have been found to change during storage duration, suggesting that future studies will be needed to assess whether such alterations could influence their activity and efficiency.

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Proteomics and transcriptomics investigation on longissimus muscles in Large White and Casertana pig breeds

Timperio

Gevi

Longo

et al. 2013

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Consumer complaints against the blandness of modern lean meat and the frequent reference to the more strongly flavored meat that was available years ago have prompted reconsideration of high fatdepositing typical pig breeds. Casertana and Large White pig breeds are characterized by a different tendency toward fat accumulation as they exhibit opposite genetic and physiological traits with respect to the energy metabolism. These physiological differences were investigated in longissimus lumborum muscles through proteomics (2-DE, MS/MS) and microarray approaches. Data were analyzed for pathway and network analyses, as well as GO term enrichment of biological functions. As a result, Casertana showed a greater amount of proteins involved in glycolitic metabolism and mainly rely on fast-mobilizable energy sources. Large White overexpressed cell cycle and skeletal muscle growth related genes. Metabolic behavior and other implications are discussed.

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