Wnt regulates amino acid transporter  Slc7a5  and so constrains the integrated stress response in mouse embryos

There is no author summary for this article yet. Authors can add summaries to their articles on ScienceOpen to make them more accessible to a non-specialist audience.

Abstract

Amino acids are essential for cellular metabolism, and it is important to understand how nutrient supply is coordinated with changing energy requirements during embryogenesis. Here, we show that the amino acid transporter Slc7a5/ Lat1 is highly expressed in tissues undergoing morphogenesis and that Slc7a5‐null mouse embryos have profound neural and limb bud outgrowth defects. Slc7a5‐null neural tissue exhibited aberrant mTORC1 activity and cell proliferation; transcriptomics, protein phosphorylation and apoptosis analyses further indicated induction of the integrated stress response as a potential cause of observed defects. The pattern of stress response gene expression induced in Slc7a5‐null embryos was also detected at low level in wild‐type embryos and identified stress vulnerability specifically in tissues undergoing morphogenesis. The Slc7a5‐null phenotype is reminiscent of Wnt pathway mutants, and we show that Wnt/β‐catenin loss inhibits Slc7a5 expression and induces this stress response. Wnt signalling therefore normally supports the metabolic demands of morphogenesis and constrains cellular stress. Moreover, operation in the embryo of the integrated stress response, which is triggered by pathogen‐mediated as well as metabolic stress, may provide a mechanistic explanation for a range of developmental defects.

Abstract

The amino acid transporter Slc7a5 sustains the metabolic demands of tissues undergoing morphogenesis during mouse embryogenesis and so constrains the activation of the integrated stress response.

Related collections

Most cited references 74

Record: found
Abstract: found
Article: not found

The integrated stress response.

Karolina Pakos-Zebrucka, Izabela Koryga, Katarzyna Mnich … (2016)

In response to diverse stress stimuli, eukaryotic cells activate a common adaptive pathway, termed the integrated stress response (ISR), to restore cellular homeostasis. The core event in this pathway is the phosphorylation of eukaryotic translation initiation factor 2 alpha (eIF2α) by one of four members of the eIF2α kinase family, which leads to a decrease in global protein synthesis and the induction of selected genes, including the transcription factor ATF4, that together promote cellular recovery. The gene expression program activated by the ISR optimizes the cellular response to stress and is dependent on the cellular context, as well as on the nature and intensity of the stress stimuli. Although the ISR is primarily a pro-survival, homeostatic program, exposure to severe stress can drive signaling toward cell death. Here, we review current understanding of the ISR signaling and how it regulates cell fate under diverse types of stress.

0 comments Cited 918 times – based on 0 reviews      Review now

Bookmark

Record: found
Abstract: found
Article: not found

Bidirectional transport of amino acids regulates mTOR and autophagy.

Paul Nicklin, Philip Bergman, Bailin Zhang … (2009)

Amino acids are required for activation of the mammalian target of rapamycin (mTOR) kinase which regulates protein translation, cell growth, and autophagy. Cell surface transporters that allow amino acids to enter the cell and signal to mTOR are unknown. We show that cellular uptake of L-glutamine and its subsequent rapid efflux in the presence of essential amino acids (EAA) is the rate-limiting step that activates mTOR. L-glutamine uptake is regulated by SLC1A5 and loss of SLC1A5 function inhibits cell growth and activates autophagy. The molecular basis for L-glutamine sensitivity is due to SLC7A5/SLC3A2, a bidirectional transporter that regulates the simultaneous efflux of L-glutamine out of cells and transport of L-leucine/EAA into cells. Certain tumor cell lines with high basal cellular levels of L-glutamine bypass the need for L-glutamine uptake and are primed for mTOR activation. Thus, L-glutamine flux regulates mTOR, translation and autophagy to coordinate cell growth and proliferation.

0 comments Cited 594 times – based on 0 reviews      Review now

Bookmark

Record: found
Abstract: found
Article: not found

TSC2 integrates Wnt and energy signals via a coordinated phosphorylation by AMPK and GSK3 to regulate cell growth.

Ken Inoki, Hongjiao Ouyang, Tianqing Zhu … (2006)

Mutation in the TSC2 tumor suppressor causes tuberous sclerosis complex, a disease characterized by hamartoma formation in multiple tissues. TSC2 inhibits cell growth by acting as a GTPase-activating protein toward Rheb, thereby inhibiting mTOR, a central controller of cell growth. Here, we show that Wnt activates mTOR via inhibiting GSK3 without involving beta-catenin-dependent transcription. GSK3 inhibits the mTOR pathway by phosphorylating TSC2 in a manner dependent on AMPK-priming phosphorylation. Inhibition of mTOR by rapamycin blocks Wnt-induced cell growth and tumor development, suggesting a potential therapeutic value of rapamycin for cancers with activated Wnt signaling. Our results show that, in addition to transcriptional activation, Wnt stimulates translation and cell growth by activating the TSC-mTOR pathway. Furthermore, the sequential phosphorylation of TSC2 by AMPK and GSK3 reveals a molecular mechanism of signal integration in cell growth regulation.

0 comments Cited 373 times – based on 0 reviews      Review now

Bookmark

All references

Author and article information

Contributors

Kate G Storey:

ORCID: https://orcid.org/0000-0003-3506-1287

k.g.storey@dundee.ac.uk

Journal

Journal ID (nlm-ta): EMBO Rep

Journal ID (iso-abbrev): EMBO Rep

Journal ID (doi): 10.1002/(ISSN)1469-3178

Journal ID (publisher-id): EMBR

Journal ID (hwp): embor

Title: EMBO Reports

Publisher: John Wiley and Sons Inc. (Hoboken )

ISSN (Print): 1469-221X

ISSN (Electronic): 1469-3178

Publication date (Electronic): 02 December 2019

Publication date (Print): 07 January 2020

Publication date PMC-release: 02 December 2019

Volume: 21

Issue: 1 ( doiID: 10.1002/embr.v21.1 )

Electronic Location Identifier: e48469

Affiliations

[ ¹ ] Division of Cell & Developmental Biology School of Life Sciences University of Dundee Dundee UK

[ ² ] Division of Cell Signalling and Immunology School of Life Sciences University of Dundee Dundee UK

[ ³ ] Division of Computational Biology School of Life Sciences University of Dundee Dundee UK

[ ⁴ ] Sequencing Facility School of Life Sciences University of Dundee Dundee UK

[ ⁵ ] Section on Molecular Morphogenesis NICHD, NIH Bethesda MD USA

[ ⁶ ] Cancer and Developmental Biology Laboratory Center for Cancer Research National Cancer Institute‐Frederick, NIH Frederick MD USA

[ ⁷ ]Present address: Institute of Physiology University of Zürich Zürich Switzerland

[ ⁸ ]Present address: Illumina Canada Victoria BC Canada

Author notes

[*] [* ]Corresponding author. Tel: +44 1382 385691; E‐mail: k.g.storey@ 123456dundee.ac.uk

Author information

Nadège Poncet https://orcid.org/0000-0002-0199-994X

Pamela A Halley https://orcid.org/0000-0002-6970-7835

Christopher Lipina https://orcid.org/0000-0001-7327-2857

Marek Gierliński https://orcid.org/0000-0001-9149-3514

Alwyn Dady https://orcid.org/0000-0002-5659-8801

Gail A Singer https://orcid.org/0000-0002-9927-5826

Yun‐Bo Shi https://orcid.org/0000-0002-6330-0639

Terry P Yamaguchi https://orcid.org/0000-0002-7452-4419

Peter M Taylor https://orcid.org/0000-0003-0572-4502

Kate G Storey https://orcid.org/0000-0003-3506-1287

Article

Publisher ID: EMBR201948469

DOI: 10.15252/embr.201948469

PMC ID: 6944906

PubMed ID: 31789450

SO-VID: 511d879b-a9fe-4747-b62e-c58b0cff04e7

License:

This is an open access article under the terms of the http://creativecommons.org/licenses/by/4.0/ License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

History

Date received : 13 May 2019

Date revision received : 18 October 2019

Date accepted : 25 October 2019

Page count

Figures: 12, Tables: 1, Pages: 20, Words: 14908

Funding

Funded by: Wellcome Trust (WT) , open-funder-registry 10.13039/100010269;

Award ID: WT094226

Award ID: WT204816/Z/16

Award ID: WT101468

Award ID: WT102817AIA

Funded by: NIH National Cancer Institute (NCI) , open-funder-registry 10.13039/100000002;

Award ID: 1ZIABC010345‐18

Custom metadata

source-schema-version-number 2.0

cover-date 07 January 2020

details-of-publishers-convertor Converter:WILEY_ML3GV2_TO_JATSPMC version:5.7.4 mode:remove_FC converted:07.01.2020

ScienceOpen disciplines: Molecular biology

Keywords: amino acid transport,integrated stress response,mouse embryo morphogenesis,slc7a5/lat1,wnt signalling,development & differentiation,membrane & intracellular transport,signal transduction

Data availability:

ScienceOpen disciplines: Molecular biology

Keywords: amino acid transport, integrated stress response, mouse embryo morphogenesis, slc7a5/lat1, wnt signalling, development & differentiation, membrane & intracellular transport, signal transduction

Wnt regulates amino acid transporter Slc7a5 and so constrains the integrated stress response in mouse embryos

Read this article at

Abstract

Abstract

Related collections

Stress signalling in stem cells

Most cited references 74

The integrated stress response.

Bidirectional transport of amino acids regulates mTOR and autophagy.

TSC2 integrates Wnt and energy signals via a coordinated phosphorylation by AMPK and GSK3 to regulate cell growth.

Author and article information

Contributors

Journal

Affiliations

Author notes

Author information

Article

History

Page count

Funding

Categories

Custom metadata

Comments

Comment on this article

Similar content 139

Cited by 16

Most referenced authors 1,815