Literature DB >> 21150267

Selective autophagy and viruses.

Rhea Sumpter1, Beth Levine.   

Abstract

In recent years, the process of selective autophagy has received much attention with respect to the clearance of protein aggregates, damaged mitochondria and bacteria. However, until recently, there have been virtually no studies on the selective autophagy of viruses, although they are perhaps one of the most ubiquitous unwanted constituents in human cells. Recently, we have shown that the ability of neuronal Atg5 to protect against lethal Sindbis virus central nervous system (CNS) infection in mice is associated with impaired viral capsid clearance, increased p62 accumulation and increased neuronal cell death. In vitro, we showed that p62 interacts with the Sindbis capsid protein and targets it for degradation in autophagosomes. Herein, we review these findings and broadly speculate about potential roles of selective viral autophagy in the regulation of host immunity and viral pathogenesis.

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Year:  2011        PMID: 21150267      PMCID: PMC3060412          DOI: 10.4161/auto.7.3.14281

Source DB:  PubMed          Journal:  Autophagy        ISSN: 1554-8627            Impact factor:   16.016


  38 in total

1.  Sindbis virus vector system for functional analysis of apoptosis regulators.

Authors:  J M Hardwick; B Levine
Journal:  Methods Enzymol       Date:  2000       Impact factor: 1.600

Review 2.  Apoptosis in viral infections of neurons: a protective or pathologic host response?

Authors:  B Levine
Journal:  Curr Top Microbiol Immunol       Date:  2002       Impact factor: 4.291

Review 3.  Selective degradation of p62 by autophagy.

Authors:  Yoshinobu Ichimura; Masaaki Komatsu
Journal:  Semin Immunopathol       Date:  2010-09-03       Impact factor: 9.623

4.  Immunological cross-reactions and interactions between the Drosophila melanogaster ref(2)P protein and sigma rhabdovirus proteins.

Authors:  F Wyers; P Dru; B Simonet; D Contamine
Journal:  J Virol       Date:  1993-06       Impact factor: 5.103

5.  Is Paget's disease of bone a viral infection?

Authors:  A Rebel; K Malkani; M Baslé; C Bregeon
Journal:  Calcif Tissue Res       Date:  1977-05

6.  [Drosophila genes which intervene in multiplication of sigma virus (author's transl)].

Authors:  P Gay
Journal:  Mol Gen Genet       Date:  1978-02-27

7.  Paramyxoviruses in Paget's disease.

Authors:  M T Gordon; A P Mee; P T Sharpe
Journal:  Semin Arthritis Rheum       Date:  1994-02       Impact factor: 5.532

8.  Nuclear inclusions in Paget's disease of bone.

Authors:  B G Mills; F R Singer
Journal:  Science       Date:  1976-10-08       Impact factor: 47.728

9.  Unusual variability of the Drosophila melanogaster ref(2)P protein which controls the multiplication of sigma rhabdovirus.

Authors:  P Dru; F Bras; S Dezélée; P Gay; A M Petitjean; A Pierre-Deneubourg; D Teninges; D Contamine
Journal:  Genetics       Date:  1993-04       Impact factor: 4.562

10.  Evidence for both respiratory syncytial virus and measles virus antigens in the osteoclasts of patients with Paget's disease of bone.

Authors:  B G Mills; F R Singer; L P Weiner; S C Suffin; E Stabile; P Holst
Journal:  Clin Orthop Relat Res       Date:  1984-03       Impact factor: 4.176
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  39 in total

1.  Evolutionary trends and functional anatomy of the human expanded autophagy network.

Authors:  Andreas Till; Rintaro Saito; Daria Merkurjev; Jing-Jing Liu; Gulam Hussain Syed; Martin Kolnik; Aleem Siddiqui; Martin Glas; Björn Scheffler; Trey Ideker; Suresh Subramani
Journal:  Autophagy       Date:  2015       Impact factor: 16.016

Review 2.  Targeting autophagy for the treatment of liver diseases.

Authors:  Hong-Min Ni; Jessica A Williams; Hua Yang; Ying-Hong Shi; Jia Fan; Wen-Xing Ding
Journal:  Pharmacol Res       Date:  2012-07-31       Impact factor: 7.658

3.  Rubella virus perturbs autophagy.

Authors:  Kata Pásztor; László Orosz; György Seprényi; Klára Megyeri
Journal:  Med Microbiol Immunol       Date:  2014-05-14       Impact factor: 3.402

4.  Autophagy restricts HIV-1 infection by selectively degrading Tat in CD4+ T lymphocytes.

Authors:  Sophie Sagnier; Coralie F Daussy; Sophie Borel; Véronique Robert-Hebmann; Mathias Faure; Fabien P Blanchet; Bruno Beaumelle; Martine Biard-Piechaczyk; Lucile Espert
Journal:  J Virol       Date:  2014-10-22       Impact factor: 5.103

5.  Autophagy/virophagy: a "disposal strategy" to combat COVID-19.

Authors:  Dalibor Mijaljica; Daniel J Klionsky
Journal:  Autophagy       Date:  2020-06-24       Impact factor: 16.016

6.  Fanconi Anemia Proteins Function in Mitophagy and Immunity.

Authors:  Rhea Sumpter; Shyam Sirasanagandla; Álvaro F Fernández; Yongjie Wei; Xiaonan Dong; Luis Franco; Zhongju Zou; Christophe Marchal; Ming Yeh Lee; D Wade Clapp; Helmut Hanenberg; Beth Levine
Journal:  Cell       Date:  2016-04-28       Impact factor: 41.582

7.  Critical Role of Autophagy in the Processing of Adenovirus Capsid-Incorporated Cancer-Specific Antigens.

Authors:  Sarah R Klein; Hong Jiang; Mohammad B Hossain; Xuejun Fan; Joy Gumin; Andrew Dong; Marta M Alonso; Candelaria Gomez-Manzano; Juan Fueyo
Journal:  PLoS One       Date:  2016-04-19       Impact factor: 3.240

Review 8.  Modulating macroautophagy: a neuronal perspective.

Authors:  Christopher W Johnson; Thomas J Melia; Ai Yamamoto
Journal:  Future Med Chem       Date:  2012-09       Impact factor: 3.808

Review 9.  Autophagy interaction with herpes simplex virus type-1 infection.

Authors:  Douglas O'Connell; Chengyu Liang
Journal:  Autophagy       Date:  2016-03-02       Impact factor: 16.016

10.  Inflammation-Induced, STING-Dependent Autophagy Restricts Zika Virus Infection in the Drosophila Brain.

Authors:  Yuan Liu; Beth Gordesky-Gold; Michael Leney-Greene; Nathan L Weinbren; Matthew Tudor; Sara Cherry
Journal:  Cell Host Microbe       Date:  2018-06-19       Impact factor: 21.023
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