A Proteomic Study of SUMO-2 Target Proteins

Vertegaal, Alfred C.O.; Ogg, Stephen C.; Jaffray, Ellis; Rodríguez, Manuel Sánchez; Hay, Ronald T.; Andersen, Jens S.; Mann, Matthias; Lamond, Angus I.

doi:10.1074/jbc.m404201200

Cited by 209 publications

(174 citation statements)

References 72 publications

(65 reference statements)

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“…These results indicate that a substantial fraction of the sites seems to be unrelated to proteasomal-mediated degradation and suggests that Ub conjugation to SR proteins may work as a regulatory signal instead of as a degradation labeling (16,49). Likewise, proteomic approaches revealed that RNA-binding proteins are the predominant group among small Ubiquitin-like modifier (SUMO) conjugation substrates, including several hnRNPs, SR family members and spliceosome components (50,51). Furthermore, SUMO conjugation has been found to regulate different aspects of mRNA metabolism such as pre-mRNA 3 0 end processing and RNA editing, by modifying the function of poly(A) polymerase, symplekin and CPSF-73 in the former case and ADAR1 in the latter (52,53).…”

Section: Post-translational Modifications Of Sr Proteins: Above and Bmentioning

confidence: 97%

Regulating the regulators: Serine/arginine‐rich proteins under scrutiny

et al. 2012

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SummarySerine/arginine-rich (SR) proteins are among the most studied splicing regulators. They constitute a family of evolutionarily conserved proteins that, apart from their initially identified and deeply studied role in splicing regulation, have been implicated in genome stability, chromatin binding, transcription elongation, mRNA stability, mRNA export and mRNA translation. Remarkably, this list of SR protein activities seems far from complete, as unexpected functions keep being unraveled. An intriguing aspect that awaits further investigation is how the multiple tasks of SR proteins are concertedly regulated within mammalian cells. In this article, we first discuss recent findings regarding the regulation of SR protein expression, activity and accessibility. We dive into recent studies describing SR protein auto-regulatory feedback loops involving different molecular mechanisms such as unproductive splicing, microRNA-mediated regulation and translational repression. In addition, we take into account another step of regulation of SR proteins, presenting new findings about a variety of post-translational modifications by proteomics approaches and how some of these modifications can regulate SR protein sub-cellular localization or stability. Towards the end, we focus in two recently revealed functions of SR proteins beyond mRNA biogenesis and metabolism, the regulation of micro-RNA processing and the regulation of small ubiquitin-like modifier (SUMO) conjugation.

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Section: Post-translational Modifications Of Sr Proteins: Above and Bmentioning

confidence: 97%

Regulating the regulators: Serine/arginine‐rich proteins under scrutiny

et al. 2012

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“…With the long distances that mRNAs and RNA-binding proteins must travel in neurons, sumoylation may provide a means to recycle some proteins to the nucleus by targeting these proteins for retrograde transport. Sumoylation has recently been demonstrated for a few RNAbinding proteins (19)(20)(21)(22). Sumoylation of hnRNP C decreases its nucleic acid binding (21).…”

Section: Discussionmentioning

confidence: 99%

Sumoylation in axons triggers retrograde transport of the RNA-binding protein La

Niekerk

Willis

Chang

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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A surprisingly large population of mRNAs has been shown to localize to sensory axons, but few RNA-binding proteins have been detected in these axons. These axonal mRNAs include several potential binding targets for the La RNA chaperone protein. La is transported into axonal processes in both culture and peripheral nerve. Interestingly, La is posttranslationally modified in sensory neurons by sumoylation. In axons, small ubiquitin-like modifying polypeptides (SUMO)-La interacts with dynein, whereas native La interacts with kinesin. Lysine 41 is required for sumoylation, and sumoylation-incompetent La K41R shows only anterograde transport, whereas WT La shows both anterograde and retrograde transport in axons. Thus, sumoylation of La determines the directionality of its transport within the axonal compartment, with SUMO-La likely recycling to the cell body.axonal transport ͉ La/SSB ͉ RNA localization ͉ small ubiquitin-like modifying polypeptide

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“…Proteomic analyses have demonstrated that the pool of cellular proteins SUMOylated with SUMO1 only partially overlaps the pool of proteins SUMOylated with SUMO2/3 (47)(48)(49). Furthermore, conjugation with SUMO2/3 is known to exert at least one potentially different effect on the target from that exerted by SUMO1 conjugation, namely, the formation of SUMO2/3 chains followed by the recognition of the poly-SUMOylated target by SUMO-dependent ubiquitin ligases that polyubiquitinylate it and direct it toward proteasomal degradation, as previously reviewed (50)(51)(52).…”

Section: Pr8mentioning

confidence: 99%

SUMOylation Affects the Interferon Blocking Activity of the Influenza A Nonstructural Protein NS1 without Affecting Its Stability or Cellular Localization

Santos

Pal

Chacon

et al. 2013

J Virol

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Our pioneering studies on the interplay between the small ubiquitin-like modifier (SUMO) and influenza A virus identified the nonstructural protein NS1 as the first known SUMO target of influenza virus and one of the most abundantly SUMOylated influenza virus proteins. Here, we further characterize the role of SUMOylation for the A/Puerto Rico/8/1934 (PR8) NS1 protein, demonstrating that NS1 is SUMOylated not only by SUMO1 but also by SUMO2/3 and mapping the main SUMOylation sites in NS1 to residues K219 and K70. Furthermore, by using SUMOylatable and non-SUMOylatable forms of NS1 and an NS1-specific artificial SUMO ligase (ASL) that increases NS1 SUMOylation ϳ4-fold, we demonstrate that SUMOylation does not affect the stability or cellular localization of PR8 NS1. However, NS1's ability to be SUMOylated appears to affect virus multiplication, as indicated by the delayed growth of a virus expressing the non-SUMOylatable form of NS1 in the interferon (IFN)-competent MDCK cell line. Remarkably, while a non-SUMOylatable form of NS1 exhibited a substantially diminished ability to neutralize IFN production, increasing NS1 SUMOylation beyond its normal levels also exerted a negative effect on its IFN-blocking function. This observation indicates the existence of an optimal level of NS1 SUMOylation that allows NS1 to achieve maximal activity and suggests that the limited amount of SUMOylation normally observed for most SUMO targets may correspond to an optimal level that maximizes the contribution of SUMOylation to protein function. Finally, protein cross-linking data suggest that SUMOylation may affect NS1 function by regulating the abundance of NS1 dimers and trimers in the cell.

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A Proteomic Study of SUMO-2 Target Proteins

Cited by 209 publications

References 72 publications

Regulating the regulators: Serine/arginine‐rich proteins under scrutiny

Regulating the regulators: Serine/arginine‐rich proteins under scrutiny

Sumoylation in axons triggers retrograde transport of the RNA-binding protein La

SUMOylation Affects the Interferon Blocking Activity of the Influenza A Nonstructural Protein NS1 without Affecting Its Stability or Cellular Localization

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