Literature DB >> 24418849

Diverse post-translational modifications of the pannexin family of channel-forming proteins.

Silvia Penuela1, Alexander W Lohman2, Wesley Lai3, Laszlo Gyenis4, David W Litchfield4, Brant E Isakson2, Dale W Laird1.   

Abstract

The pannexin family of channel-forming proteins is composed of 3 distinct but related members called Panx1, Panx2, and Panx3. Pannexins have been implicated in many physiological processes as well as pathological conditions, primarily through their function as ATP release channels. However, it is currently unclear if all pannexins are subject to similar or different post-translational modifications as most studies have focused primarily on Panx1. Using in vitro biochemical assays performed on ectopically expressed pannexins in HEK-293T cells, we confirmed that all 3 pannexins are N-glycosylated to different degrees, but they are not modified by sialylation or O-linked glycosylation in a manner that changes their apparent molecular weight. Using cell-free caspase assays, we also discovered that similar to Panx1, the C-terminus of Panx2 is a substrate for caspase cleavage. Panx3, on the other hand, is not subject to caspase digestion but an in vitro biotin switch assay revealed that it was S-nitrosylated by nitric oxide donors. Taken together, our findings uncover novel and diverse pannexin post-translational modifications suggesting that they may be differentially regulated for distinct or overlapping cellular and physiological functions.

Entities:  

Keywords:  Pannexin; Panx1; Panx2; Panx3; caspase; glycosylation; nitrosylation; post-translational modifications

Mesh:

Substances:

Year:  2014        PMID: 24418849      PMCID: PMC4048301          DOI: 10.4161/chan.27422

Source DB:  PubMed          Journal:  Channels (Austin)        ISSN: 1933-6950            Impact factor:   2.581


  45 in total

1.  Caspase assays.

Authors:  H R Stennicke; G S Salvesen
Journal:  Methods Enzymol       Date:  2000       Impact factor: 1.600

2.  Pannexin membrane channels are mechanosensitive conduits for ATP.

Authors:  Li Bao; Silviu Locovei; Gerhard Dahl
Journal:  FEBS Lett       Date:  2004-08-13       Impact factor: 4.124

3.  Caspase activation and neuroprotection in caspase-3- deficient mice after in vivo cerebral ischemia and in vitro oxygen glucose deprivation.

Authors:  Dean A Le; Yongqin Wu; Zhihong Huang; Kohji Matsushita; Nikolaus Plesnila; Jean C Augustinack; Bradley T Hyman; Junying Yuan; Keisuke Kuida; Richard A Flavell; Michael A Moskowitz
Journal:  Proc Natl Acad Sci U S A       Date:  2002-11-01       Impact factor: 11.205

4.  Identification of copper/zinc superoxide dismutase as a nitric oxide-regulated gene in human (HaCaT) keratinocytes: implications for keratinocyte proliferation.

Authors:  S Frank; H Kämpfer; M Podda; R Kaufmann; J Pfeilschifter
Journal:  Biochem J       Date:  2000-03-15       Impact factor: 3.857

5.  Protein S-nitrosylation: a physiological signal for neuronal nitric oxide.

Authors:  S R Jaffrey; H Erdjument-Bromage; C D Ferris; P Tempst; S H Snyder
Journal:  Nat Cell Biol       Date:  2001-02       Impact factor: 28.824

6.  Nitric oxide regulates exocytosis by S-nitrosylation of N-ethylmaleimide-sensitive factor.

Authors:  Kenji Matsushita; Craig N Morrell; Beatrice Cambien; Shui Xiang Yang; Munekazu Yamakuchi; Clare Bao; Makoto R Hara; Richard A Quick; Wangsen Cao; Brian O'Rourke; John M Lowenstein; Jonathan Pevsner; Denisa D Wagner; Charles J Lowenstein
Journal:  Cell       Date:  2003-10-17       Impact factor: 41.582

7.  The carbohydrate chains of the beta subunit of human chorionic gonadotropin produced by the choriocarcinoma cell line BeWo. Novel O-linked and novel bisecting-GlcNAc-containing N-linked carbohydrates.

Authors:  K Hård; J B Damm; M P Spruijt; A A Bergwerff; J P Kamerling; G W Van Dedem; J F Vliegenthart
Journal:  Eur J Biochem       Date:  1992-04-15

8.  Functional outcome of pannexin-deficient mice after cerebral ischemia.

Authors:  Panagiotis Bargiotas; Antje Krenz; Hannah Monyer; Markus Schwaninger
Journal:  Channels (Austin)       Date:  2012-10-30       Impact factor: 2.581

9.  The mammalian pannexin family is homologous to the invertebrate innexin gap junction proteins.

Authors:  Ancha Baranova; Dmitry Ivanov; Nadezda Petrash; Anya Pestova; Mikhail Skoblov; Ilya Kelmanson; Dmitry Shagin; Svetlana Nazarenko; Elena Geraymovych; Oxana Litvin; Anya Tiunova; Timothy L Born; Natalia Usman; Dmitry Staroverov; Sergey Lukyanov; Yury Panchin
Journal:  Genomics       Date:  2004-04       Impact factor: 5.736

10.  Evidence for posttranslational O-glycosylation of fetuin.

Authors:  W V Johnson; E C Heath
Journal:  Biochemistry       Date:  1986-09-23       Impact factor: 3.162
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  14 in total

1.  Constitutive SRC-mediated phosphorylation of pannexin 1 at tyrosine 198 occurs at the plasma membrane.

Authors:  Leon J DeLalio; Marie Billaud; Claire A Ruddiman; Scott R Johnstone; Joshua T Butcher; Abigail G Wolpe; Xueyao Jin; T C Stevenson Keller; Alexander S Keller; Thibaud Rivière; Miranda E Good; Angela K Best; Alexander W Lohman; Leigh Anne Swayne; Silvia Penuela; Roger J Thompson; Paul D Lampe; Mark Yeager; Brant E Isakson
Journal:  J Biol Chem       Date:  2019-02-27       Impact factor: 5.157

2.  Interaction Between Pannexin 1 and Caveolin-1 in Smooth Muscle Can Regulate Blood Pressure.

Authors:  Leon J DeLalio; Alexander S Keller; Jiwang Chen; Andrew K J Boyce; Mykhaylo V Artamonov; Henry R Askew-Page; T C Stevenson Keller; Scott R Johnstone; Rachel B Weaver; Miranda E Good; Sara A Murphy; Angela K Best; Ellen L Mintz; Silvia Penuela; Iain A Greenwood; Roberto F Machado; Avril V Somlyo; Leigh Anne Swayne; Richard D Minshall; Brant E Isakson
Journal:  Arterioscler Thromb Vasc Biol       Date:  2018-09       Impact factor: 8.311

Review 3.  Interactions of Pannexin1 channels with purinergic and NMDA receptor channels.

Authors:  Shuo Li; Ivana Bjelobaba; Stanko S Stojilkovic
Journal:  Biochim Biophys Acta Biomembr       Date:  2017-04-04       Impact factor: 3.747

4.  Modulation of Cav3.2 T-type calcium channel permeability by asparagine-linked glycosylation.

Authors:  Katarina Ondacova; Maria Karmazinova; Joanna Lazniewska; Norbert Weiss; Lubica Lacinova
Journal:  Channels (Austin)       Date:  2016-01-08       Impact factor: 2.581

5.  Epithelial and Endothelial Pannexin1 Channels Mediate AKI.

Authors:  Jakub Jankowski; Heather M Perry; Christopher B Medina; Liping Huang; Junlan Yao; Amandeep Bajwa; Ulrike M Lorenz; Diane L Rosin; Kodi S Ravichandran; Brant E Isakson; Mark D Okusa
Journal:  J Am Soc Nephrol       Date:  2018-06-04       Impact factor: 10.121

Review 6.  The role of pannexin1 in the induction and resolution of inflammation.

Authors:  Samantha E Adamson; Norbert Leitinger
Journal:  FEBS Lett       Date:  2014-03-15       Impact factor: 4.124

Review 7.  The pannexins: past and present.

Authors:  Stephen R Bond; Christian C Naus
Journal:  Front Physiol       Date:  2014-02-19       Impact factor: 4.566

8.  Pannexin2 oligomers localize in the membranes of endosomal vesicles in mammalian cells while Pannexin1 channels traffic to the plasma membrane.

Authors:  Daniela Boassa; Phuong Nguyen; Junru Hu; Mark H Ellisman; Gina E Sosinsky
Journal:  Front Cell Neurosci       Date:  2015-02-02       Impact factor: 5.505

9.  Pannexin 1 and pannexin 3 channels regulate skeletal muscle myoblast proliferation and differentiation.

Authors:  Stéphanie Langlois; Xiao Xiang; Kelsey Young; Bryce J Cowan; Silvia Penuela; Kyle N Cowan
Journal:  J Biol Chem       Date:  2014-09-19       Impact factor: 5.157

Review 10.  Pannexin1 as mediator of inflammation and cell death.

Authors:  Sara Crespo Yanguas; Joost Willebrords; Scott R Johnstone; Michaël Maes; Elke Decrock; Marijke De Bock; Luc Leybaert; Bruno Cogliati; Mathieu Vinken
Journal:  Biochim Biophys Acta Mol Cell Res       Date:  2016-10-11       Impact factor: 4.739
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