Structural basis for regulation of the nucleo-cytoplasmic distribution of Bag6 by TRC35

Mock, Jee‐Young; Xu, Yue; Ye, Yihong; Clemons, William M.

doi:10.1073/pnas.1702940114

Cited by 18 publications

(25 citation statements)

References 57 publications

(56 reference statements)

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“…Moreover, due to evolutionary pressure on the BAG domain, it has undergone phylogenetic divergence to accommodate for more complex demands in mammals. This indicates that on a functional and sequence level, the BAG6 C-terminal BAG domain is unique (Kuwabara et al, 2015;Mock et al, 2017).…”

Section: Bag6 Structure: C-terminal Bag Domainmentioning

confidence: 97%

“…The binding of hydrophobic stretches of protein onto BAG6 is imperative for substrate discrimination. Domain I contains ECI1 and ECI2, both of which are capable of binding hydrophobic substrates, but cannot ; NLS (residues 1008-1050, orange) and TRC35 (residues 23-305, gray) from PDB: 6AU8 (Mock, Xu, Ye, & Clemons, 2017); BAG domain (blue) in complex with UBL4A (residues 95-147, gray), from PDB: 4X86 (Kuwabara et al, 2015).…”

Section: Bag6 Structure: N-terminal Ubl Domainmentioning

confidence: 99%

“…BAG6 variants lacking the NLS due to alternative splicing have shown preferential localization at the cytosol. Although BAG6 is primarily localized in the cytosol, the NLS domain indicates that its presence in the nucleus is important too, and functions of BAG6 as a quality control site have been displayed in both localities (Mock et al, 2017). However, some cases show that increased nuclear levels of BAG6 can be associated with tumorigenesis, for example, in osteosarcoma tissue (Tsukahara et al, 2009).…”

Section: Bag6 Structure: Nls Domainmentioning

confidence: 99%

See 2 more Smart Citations

The roles of cytosolic quality control proteins, SGTA and the BAG6 complex, in disease

Benarroch

Austin

Ahmed

et al. 2019

Molecular Chaperones in Human Disorders

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Section: Bag6 Structure: C-terminal Bag Domainmentioning

confidence: 97%

Section: Bag6 Structure: N-terminal Ubl Domainmentioning

confidence: 99%

Section: Bag6 Structure: Nls Domainmentioning

confidence: 99%

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The roles of cytosolic quality control proteins, SGTA and the BAG6 complex, in disease

Benarroch

Austin

Ahmed

et al. 2019

Molecular Chaperones in Human Disorders

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“…Some phylogenetic aspects of other GET pathway components have been recently discussed, in particular the evolutionary relationships between components of the pretargeting complex comprising Get4, Get5 and Bag6 and the legacy of membrane protein biogenesis factors similar to bacterial Oxa1 that also include Get1 . Here, we combine a review of the literature on Get3 structure and function with a comprehensive bioinformatic analysis of the structural elements of the protein involved in TA protein binding.…”

Section: Get3 Homologs In the Different Domains Of Lifementioning

confidence: 99%

“…Extensive biochemical and structural studies performed over the last decade have characterized the targeting of TA proteins utilizing the yeast GET pathway (as reviewed in). Initially, a pre‐targeting complex, consisting of a small glutamine‐rich tetratricopeptide repeat containing protein Sgt2, and Get4 and Get5 in yeast, or Bag6, SGTA, TRC35 and UBL4A in mammals, captures the TA protein following its release from the ribosome, then transfers it to the ATPase Get3 in budding yeast, or TRC40 in mammals . The TA‐bound Get3/TRC40 protects and delivers the TA protein to the ER membrane, where its receptor complex comprised of Get1 and Get2 in yeast or WRB and CAML in mammals stimulates its subsequent release into the membrane …”

Section: Introductionmentioning

confidence: 99%

The natural history of Get3‐like chaperones

Farkas

Laurentiis

Schwappach

2019

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Get3 in yeast or TRC40 in mammals is an ATPase that, in eukaryotes, is a central element of the GET or TRC pathway involved in the targeting of tail‐anchored proteins. Get3 has also been shown to possess chaperone holdase activity. A bioinformatic assessment was performed across all domains of life on functionally important regions of Get3 including the TRC40‐insert and the hydrophobic groove essential for tail‐anchored protein binding. We find that such a hydrophobic groove is much more common in bacterial Get3 homologs than previously appreciated based on a directed comparison of bacterial ArsA and yeast Get3. Furthermore, our analysis shows that the region containing the TRC40‐insert varies in length and methionine content to an unexpected extent within eukaryotes and also between different phylogenetic groups. In fact, since the TRC40‐insert is present in all domains of life, we suggest that its presence does not automatically predict a tail‐anchored protein targeting function. This opens up a new perspective on the function of organellar Get3 homologs in plants which feature the TRC40‐insert but have not been demonstrated to function in tail‐anchored protein targeting. Our analysis also highlights a large diversity of the ways Get3 homologs dimerize. Thus, based on the structural features of Get3 homologs, these proteins may have an unexplored functional diversity in all domains of life.

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What's in the BAGs? Intrinsic disorder angle of the multifunctionality of the members of a family of chaperone regulators

Marzullo

Turco

Uversky

2021

J of Cellular Biochemistry

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In humans, the family of Bcl‐2 associated athanogene (BAG) proteins includes six members characterized by exceptional multifunctionality and engagement in the pathogenesis of various diseases. All of them are capable of interacting with a multitude of often unrelated binding partners. Such binding promiscuity and related functional and pathological multifacetedness cannot be explained or understood within the frames of the classical “one protein–one structure–one function” model, which also fails to explain the presence of multiple isoforms generated for BAG proteins by alternative splicing or alternative translation initiation and their extensive posttranslational modifications. However, all these mysteries can be solved by taking into account the intrinsic disorder phenomenon. In fact, high binding promiscuity and potential to participate in a broad spectrum of interactions with multiple binding partners, as well as a capability to be multifunctional and multipathogenic, are some of the characteristic features of intrinsically disordered proteins and intrinsically disordered protein regions. Such functional proteins or protein regions lacking unique tertiary structures constitute a cornerstone of the protein structure‐function continuum concept. The aim of this paper is to provide an overview of the functional roles of human BAG proteins from the perspective of protein intrinsic disorder which will provide a means for understanding their binding promiscuity, multifunctionality, and relation to the pathogenesis of various diseases.

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Structural basis for regulation of the nucleo-cytoplasmic distribution of Bag6 by TRC35

Cited by 18 publications

References 57 publications

The roles of cytosolic quality control proteins, SGTA and the BAG6 complex, in disease

The roles of cytosolic quality control proteins, SGTA and the BAG6 complex, in disease

The natural history of Get3‐like chaperones

What's in the BAGs? Intrinsic disorder angle of the multifunctionality of the members of a family of chaperone regulators

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