bims-proarb Biomed News
on Proteostasis in aging and regenerative biology
Issue of 2021‒12‒26
fifteen papers selected by
Rich Giadone
Harvard University
  1. Protein Aggregation in the ER: Calm behind the Storm.
  2. Identifying new molecular players in extracellular proteostasis.
  3. The function of the co-chaperone ERdj4 in diverse (patho-)physiological conditions.
  4. Advances in Proteasome Enhancement by Small Molecules.
  5. Structure of Hsp90-Hsp70-Hop-GR reveals the Hsp90 client-loading mechanism.
  6. Transcriptomic Changes Highly Similar to Alzheimer's Disease Are Observed in a Subpopulation of Individuals During Normal Brain Aging.
  7. Autophagy modulates cell fate decisions during lineage commitment.
  8. Cellular Response to Unfolded Proteins in Depression.
  9. New lessons on TDP-43 from old N. furzeri killifish.
  10. Mitophagy in neurological disorders.
  11. Protocol for cell type-specific labeling, enrichment, and proteomic profiling of plasma proteins in mice.
  12. SESN2/NRF2 signaling activates as a direct downstream regulator of the PERK pathway against endoplasmic reticulum stress to improve the in vitro maturation of porcine oocytes.
  13. Understanding circadian regulation of mammalian cell function, protein homeostasis, and metabolism.
  14. Structure of Hsp90-p23-GR reveals the Hsp90 client-remodelling mechanism.
  15. Single-Cell Transcriptomics Links Loss of Human Pancreatic β-Cell Identity to ER Stress.
  1. Cells. 2021 Nov 28. pii: 3337. [Epub ahead of print]10(12):
    Protein Aggregation in the ER: Calm behind the Storm.
    Haisen Li, Shengyi Sun.
      As one of the largest organelles in eukaryotic cells, the endoplasmic reticulum (ER) plays a vital role in the synthesis, folding, and assembly of secretory and membrane proteins. To maintain its homeostasis, the ER is equipped with an elaborate network of protein folding chaperones and multiple quality control pathways whose cooperative actions safeguard the fidelity of protein biogenesis. However, due to genetic abnormalities, the error-prone nature of protein folding and assembly, and/or defects or limited capacities of the protein quality control systems, nascent proteins may become misfolded and fail to exit the ER. If not cleared efficiently, the progressive accumulation of misfolded proteins within the ER may result in the formation of toxic protein aggregates, leading to the so-called "ER storage diseases". In this review, we first summarize our current understanding of the protein folding and quality control networks in the ER, including chaperones, unfolded protein response (UPR), ER-associated protein degradation (ERAD), and ER-selective autophagy (ER-phagy). We then survey recent research progress on a few ER storage diseases, with a focus on the role of ER quality control in the disease etiology, followed by a discussion on outstanding questions and emerging concepts in the field.
    Keywords:  ER; ER storage disease; ER-associated protein degradation; ER-phagy; chaperone; protein aggregate; unfolded protein response
    DOI:  https://doi.org/10.3390/cells10123337
  2. Biochem Soc Trans. 2021 Dec 23. pii: BST20210369. [Epub ahead of print]
    Identifying new molecular players in extracellular proteostasis.
    Sandeep Satapathy, Mark R Wilson.
      Proteostasis refers to a delicately tuned balance between the processes of protein synthesis, folding, localization, and the degradation of proteins found inside and outside cells. Our understanding of extracellular proteostasis is rather limited and largely restricted to knowledge of 11 currently established extracellular chaperones (ECs). This review will briefly outline what is known of the established ECs, before moving on to discuss experimental strategies used to identify new members of this growing family, and an examination of a group of putative new ECs identified using one of these approaches. An observation that emerges from an analysis of the expanding number of ECs is that all of these proteins are multifunctional. Strikingly, the armory of activities each possess uniquely suit them as a group to act together at sites of tissue damage, infection, and inflammation to restore homeostasis. Lastly, we highlight outstanding questions to guide future research in this field.
    Keywords:  extracellular chaperones; extracellular proteostasis; protein conformation; protein misfolding
    DOI:  https://doi.org/10.1042/BST20210369
  3. Cell Mol Life Sci. 2021 Dec 24. 79(1): 9
    The function of the co-chaperone ERdj4 in diverse (patho-)physiological conditions.
    Lea Daverkausen-Fischer, Felicitas Pröls.
      Accumulation of misfolded proteins in the endoplasmic reticulum (ER) induces a well-orchestrated cellular response to reduce the protein burden within the ER. This unfolded protein response (UPR) is controlled primarily by three transmembrane proteins, IRE1α, ATF6, and PERK, the activity of which is controlled by BiP, the ER-resident Hsp70 protein. Binding of BiP to co-chaperones via their highly conserved J-domains stimulates the intrinsic ATPase activity of BiP, thereby providing the energy necessary for (re-)folding of proteins, or for targeting of misfolded proteins to the degradation pathway, processes specified and controlled by the respective co-chaperone. In this review, our aim is to elucidate the function of the co-chaperone ERDJ4, also known as MDG1, MDJ7, or DNAJB9. Knockout and knockin experiments clearly point to the central role of ERDJ4 in controlling lipogenesis and protein synthesis by promoting degradation of SREBP1c and the assembly of the protein complex mTORC2. Accumulating data reveal that ERDJ4 controls epithelial-to-mesenchymal transition, a central process during embryogenesis, in wound healing, and tumor development. Overexpression of ERdj4 has been shown to improve engraftment of transplanted human stem cells, possibly due to its ability to promote cellular survival in stressed cells. High ERDJ4-plasma levels are specific for fibrillary glomerulonephritis and serve as a diagnostic marker. As outlined in this review, the functions of ERDJ4 are manifold, depending on the cellular (patho-) physiological state, the cellular protein repertoire, and the subcellular localization of ERDJ4.
    Keywords:  BiP/GRP78; Cell differentiation; Diabetes; ERAD; HSP70; UPR
    DOI:  https://doi.org/10.1007/s00018-021-04082-4
  4. Biomolecules. 2021 Nov 30. pii: 1789. [Epub ahead of print]11(12):
    Advances in Proteasome Enhancement by Small Molecules.
    Dare E George, Jetze J Tepe.
      The proteasome system is a large and complex molecular machinery responsible for the degradation of misfolded, damaged, and redundant cellular proteins. When proteasome function is impaired, unwanted proteins accumulate, which can lead to several diseases including age-related and neurodegenerative diseases. Enhancing proteasome-mediated substrate degradation with small molecules may therefore be a valuable strategy for the treatment of various neurodegenerative diseases such as Parkinson's, Alzheimer's, and Huntington's diseases. In this review, we discuss the structure of proteasome and how proteasome's proteolytic activity is associated with aging and various neurodegenerative diseases. We also summarize various classes of compounds that are capable of enhancing, directly or indirectly, proteasome-mediated protein degradation.
    Keywords:  20S; 26S; cancer; degradation; disordered; misfolded; neurodegeneration; proteasome; protein; ubiquitin
    DOI:  https://doi.org/10.3390/biom11121789
  5. Nature. 2021 Dec 22.
    Structure of Hsp90-Hsp70-Hop-GR reveals the Hsp90 client-loading mechanism.
    Ray Yu-Ruei Wang, Chari M Noddings, Elaine Kirschke, Alexander G Myasnikov, Jill L Johnson, David A Agard.
      Maintaining a healthy proteome is fundamental for the survival of all organisms1. Integral to this are Hsp90 and Hsp70, molecular chaperones that together facilitate the folding, remodelling and maturation of the many 'client proteins' of Hsp902. The glucocorticoid receptor (GR) is a model client protein that is strictly dependent on Hsp90 and Hsp70 for activity3-7. Chaperoning GR involves a cycle of inactivation by Hsp70; formation of an inactive GR-Hsp90-Hsp70-Hop 'loading' complex; conversion to an active GR-Hsp90-p23 'maturation' complex; and subsequent GR release8. However, to our knowledge, a molecular understanding of this intricate chaperone cycle is lacking for any client protein. Here we report the cryo-electron microscopy structure of the GR-loading complex, in which Hsp70 loads GR onto Hsp90, uncovering the molecular basis of direct coordination by Hsp90 and Hsp70. The structure reveals two Hsp70 proteins, one of which delivers GR and the other scaffolds the Hop cochaperone. Hop interacts with all components of the complex, including GR, and poises Hsp90 for subsequent ATP hydrolysis. GR is partially unfolded and recognized through an extended binding pocket composed of Hsp90, Hsp70 and Hop, revealing the mechanism of GR loading and inactivation. Together with the GR-maturation complex structure9, we present a complete molecular mechanism of chaperone-dependent client remodelling, and establish general principles of client recognition, inhibition, transfer and activation.
    DOI:  https://doi.org/10.1038/s41586-021-04252-1
  6. Front Aging Neurosci. 2021 ;13 711524
    Transcriptomic Changes Highly Similar to Alzheimer's Disease Are Observed in a Subpopulation of Individuals During Normal Brain Aging.
    Shouneng Peng, Lu Zeng, Jean-Vianney Haure-Mirande, Minghui Wang, Derek M Huffman, Vahram Haroutunian, Michelle E Ehrlich, Bin Zhang, Zhidong Tu.
      Aging is a major risk factor for late-onset Alzheimer's disease (LOAD). How aging contributes to the development of LOAD remains elusive. In this study, we examined multiple large-scale transcriptomic datasets from both normal aging and LOAD brains to understand the molecular interconnection between aging and LOAD. We found that shared gene expression changes between aging and LOAD are mostly seen in the hippocampal and several cortical regions. In the hippocampus, the expression of phosphoprotein, alternative splicing and cytoskeleton genes are commonly changed in both aging and AD, while synapse, ion transport, and synaptic vesicle genes are commonly down-regulated. Aging-specific changes are associated with acetylation and methylation, while LOAD-specific changes are more related to glycoprotein (both up- and down-regulations), inflammatory response (up-regulation), myelin sheath and lipoprotein (down-regulation). We also found that normal aging brain transcriptomes from relatively young donors (45-70 years old) clustered into several subgroups and some subgroups showed gene expression changes highly similar to those seen in LOAD brains. Using brain transcriptomic datasets from another cohort of older individuals (>70 years), we found that samples from cognitively normal older individuals clustered with the "healthy aging" subgroup while AD samples mainly clustered with the "AD similar" subgroups. This may imply that individuals in the healthy aging subgroup will likely remain cognitively normal when they become older and vice versa. In summary, our results suggest that on the transcriptome level, aging and LOAD have strong interconnections in some brain regions in a subpopulation of cognitively normal aging individuals. This supports the theory that the initiation of LOAD occurs decades earlier than the manifestation of clinical phenotype and it may be essential to closely study the "normal brain aging" to identify the very early molecular events that may lead to LOAD development.
    Keywords:  RNAseq; aging brain; brain aging subgroups; brain regions; hippocampus; human brain transcriptome; late-onset Alzheimer’s disease; meta-analysis
    DOI:  https://doi.org/10.3389/fnagi.2021.711524
  7. Autophagy. 2021 Dec 19. 1-17
    Autophagy modulates cell fate decisions during lineage commitment.
    Kulbhushan Sharma, Nagham T Asp, Sean P Harrison, Richard Siller, Saphira F Baumgarten, Swapnil Gupta, Maria E Chollet, Elisabeth Andersen, Gareth J Sullivan, Anne Simonsen.
      Early events during development leading to exit from a pluripotent state and commitment toward a specific germ layer still need in depth understanding. Autophagy has been shown to play a crucial role in both development and differentiation. This study employs human embryonic and induced pluripotent stem cells to understand the early events of lineage commitment with respect to the role of autophagy in this process. Our data indicate that a dip in autophagy facilitates exit from pluripotency. Upon exit, we demonstrate that the modulation of autophagy affects SOX2 levels and lineage commitment, with induction of autophagy promoting SOX2 degradation and mesendoderm formation, whereas inhibition of autophagy causes SOX2 accumulation and neuroectoderm formation. Thus, our results indicate that autophagy-mediated SOX2 turnover is a determining factor for lineage commitment. These findings will deepen our understanding of development and lead to improved methods to derive different lineages and cell types.Abbreviations: ACTB: Actin, beta; ATG: Autophagy-related; BafA1: Bafilomycin A1; CAS9: CRISPR associated protein 9; CQ: Chloroquine; DE: Definitive endoderm; hESCs: Human Embryonic Stem Cells; hiPSCs: Human Induced Pluripotent Stem Cells; LAMP1: Lysosomal Associated Membrane Protein 1; MAP1LC3: Microtubule-Associated Protein 1 Light Chain 3; MTOR: Mechanistic Target Of Rapamycin Kinase; NANOG: Nanog Homeobox; PAX6: Paired Box 6; PE: Phosphatidylethanolamine; POU5F1: POU class 5 Homeobox 1; PRKAA2: Protein Kinase AMP-Activated Catalytic Subunit Alpha 2; SOX2: SRY-box Transcription Factor 2; SQSTM1: Sequestosome 1; ULK1: unc-51 like Autophagy Activating Kinase 1; WDFY3: WD Repeat and FYVE Domain Containing 3.
    Keywords:  Autophagosome; SOX2; differentiation; ectoderm; endoderm; mesoderm; pluripotent stem cells
    DOI:  https://doi.org/10.1080/15548627.2021.2008691
  8. Life (Basel). 2021 Dec 10. pii: 1376. [Epub ahead of print]11(12):
    Cellular Response to Unfolded Proteins in Depression.
    Mateusz Kowalczyk, Edward Kowalczyk, Paweł Kwiatkowski, Łukasz Łopusiewicz, Monika Talarowska, Monika Sienkiewicz.
      Despite many scientific studies on depression, there is no clear conception explaining the causes and mechanisms of depression development. Research conducted in recent years has shown that there is a strong relationship between depression and the endoplasmic reticulum (ER) stress. In order to restore ER homeostasis, the adaptive unfolded protein response (UPR) mechanism is activated. Research suggests that ER stress response pathways are continuously activated in patients with major depressive disorders (MDD). Therefore, it seems that the recommended drugs should reduce ER stress. A search is currently underway for drugs that will be both effective in reducing ER stress and relieving symptoms of depression.
    Keywords:  depression; endoplasmic reticulum stress; inflammation; unfolded protein response
    DOI:  https://doi.org/10.3390/life11121376
  9. Aging Cell. 2021 Dec 23. e13517
    New lessons on TDP-43 from old N. furzeri killifish.
    Alexandra Louka, Sara Bagnoli, Jakob Rupert, Benjamin Esapa, Gian Gaetano Tartaglia, Alessandro Cellerino, Annalisa Pastore, Eva Terzibasi Tozzini.
      Frontotemporal dementia and amyotrophic lateral sclerosis are fatal and incurable neurodegenerative diseases linked to the pathological aggregation of the TDP-43 protein. This is an essential DNA/RNA-binding protein involved in transcription regulation, pre-RNA processing, and RNA transport. Having suitable animal models to study the mechanisms of TDP-43 aggregation is crucial to develop treatments against disease. We have previously demonstrated that the killifish Nothobranchius furzeri offers the advantage of being the shortest-lived vertebrate with a clear aging phenotype. Here, we show that the two N. furzeri paralogs of TDP-43 share high sequence homology with the human protein and recapitulate its cellular and biophysical behavior. During aging, N. furzeri TDP-43 spontaneously forms insoluble intracellular aggregates with amyloid characteristics and colocalizes with stress granules. Our results propose this organism as a valuable new model of TDP-43-related pathologies making it a powerful tool for the study of disease mechanism.
    Keywords:  amyotrophic lateral sclerosis; animal models; frontotemporal dementia; killifish; neurodegeneration; protein aggregation
    DOI:  https://doi.org/10.1111/acel.13517
  10. J Neuroinflammation. 2021 Dec 22. 18(1): 297
    Mitophagy in neurological disorders.
    Lijun Zhang, Lei Dai, Deyuan Li.
      Selective autophagy is an evolutionarily conserved mechanism that removes excess protein aggregates and damaged intracellular components. Most eukaryotic cells, including neurons, rely on proficient mitophagy responses to fine-tune the mitochondrial number and preserve energy metabolism. In some circumstances (such as the presence of pathogenic protein oligopolymers and protein mutations), dysfunctional mitophagy leads to nerve degeneration, with age-dependent intracellular accumulation of protein aggregates and dysfunctional organelles, leading to neurodegenerative disease. However, when pathogenic protein oligopolymers, protein mutations, stress, or injury are present, mitophagy prevents the accumulation of damaged mitochondria. Accordingly, mitophagy mediates neuroprotective effects in some forms of neurodegenerative disease (e.g., Alzheimer's disease, Parkinson's disease, Huntington's disease, and Amyotrophic lateral sclerosis) and acute brain damage (e.g., stroke, hypoxic-ischemic brain injury, epilepsy, and traumatic brain injury). The complex interplay between mitophagy and neurological disorders suggests that targeting mitophagy might be applicable for the treatment of neurodegenerative diseases and acute brain injury. However, due to the complexity of the mitophagy mechanism, mitophagy can be both harmful and beneficial, and future efforts should focus on maximizing its benefits. Here, we discuss the impact of mitophagy on neurological disorders, emphasizing the contrast between the positive and negative effects of mitophagy.
    Keywords:  Alzheimer's disease; Autophagy; Huntington's disease; Mitophagy; Neurological diseases; Stroke
    DOI:  https://doi.org/10.1186/s12974-021-02334-5
  11. STAR Protoc. 2021 Dec 17. 2(4): 101014
    Protocol for cell type-specific labeling, enrichment, and proteomic profiling of plasma proteins in mice.
    Wei Wei, Nicholas M Riley, Xuchao Lyu, Carolyn R Bertozzi, Jonathan Z Long.
      Secreted polypeptides represent a fundamental axis of intercellular communication. Here, we present a protocol for the cell type-specific biotinylation, enrichment, and proteomic profiling of secreted plasma proteins directly in mice. This protocol uses conditional "turn-on" adeno-associated viruses expressing an endoplasmic reticulum-targeted biotin ligase to globally biotinylate proteins of the secretory pathway in a cell type-specific manner. Biotinylated secreted proteins can be directly purified from blood plasma and analyzed by SDS-PAGE gel or shotgun proteomics. For complete information on the generation and use of this protocol, please refer to Wei et al. (2021).
    Keywords:  Biotechnology and bioengineering; Cell Biology; Mass Spectrometry; Model Organisms; Protein Biochemistry; Proteomics; Systems biology
    DOI:  https://doi.org/10.1016/j.xpro.2021.101014
  12. Free Radic Biol Med. 2021 Dec 17. pii: S0891-5849(21)01110-2. [Epub ahead of print]178 413-427
    SESN2/NRF2 signaling activates as a direct downstream regulator of the PERK pathway against endoplasmic reticulum stress to improve the in vitro maturation of porcine oocytes.
    Hyo-Jin Park, Seul-Gi Yang, Deog-Bon Koo.
      Nuclear erythroid 2-related factor 2 (NRF2) is a critical regulator of oxidative stress in mammalian oocytes. Our previous study described the protective effects of Sestrin-2 (SESN2) as a stress regulator against endoplasmic reticulum (ER) stress in porcine oocytes during in vitro maturation (IVM). However, their roles in unfolded protein response-related signaling pathways in porcine oocyte maturation capacity remain unknown. The purpose of this study was to evaluate the role of SESN2/NRF2 signaling in H2O2-induced oxidative stress and ER stress via protein kinase-like ER kinase (PERK) downstream factor during porcine oocyte maturation. Here, we found that the p-NRF2(Ser40) activation in the nucleus of porcine oocytes was accompanied by PERK signaling downregulation using western blot and immunofluorescence staining at 44 h after IVM. The total and nuclear NRF2 protein expression was also induced in porcine oocytes following H2O2 and tunicamycin (Tm) exposure. Notably, the upregulation of PERK signaling significantly increased the SESN2 and NRF2 signaling in H2O2-and Tm-exposed porcine cumulus oocyte complexes. Interestingly, inducing the knockdown of the SESN2 gene expression by siRNA interrupted the NRF2 signaling activation of porcine oocyte maturation, whereas NRF2 expression blockade by ochratoxin A, an NRF2 inhibitor, did not affect the expression level of the SESN2 protein. Moreover, a defect in SESN2 completely blocked the activity of nuclear NRF2 on spindle assembly in porcine oocytes. These findings suggest that the PERK/SESN2/NRF2 signaling pathway may play an important role against ER stress during meiotic maturation and oocyte maturation capacity.
    Keywords:  (Nuclear erythroid 2-related factor 2) NRF2; Endoplasmic reticulum stress (ER stress); In vitro maturation (IVM); Porcine oocyte; Protein kinase-like ER kinase (PERK) signal; Sestrin-2 (SESN2)
    DOI:  https://doi.org/10.1016/j.freeradbiomed.2021.12.258
  13. Curr Opin Syst Biol. 2021 Dec;28 None
    Understanding circadian regulation of mammalian cell function, protein homeostasis, and metabolism.
    Alessandra Stangherlin, Estere Seinkmane, John S O'Neill.
      Circadian rhythms are ∼24 h cycles of organismal and cellular activity ubiquitous to mammalian physiology. A prevailing paradigm suggests that timing information flows linearly from rhythmic transcription via protein abundance changes to drive circadian regulation of cellular function. Challenging this view, recent evidence indicates daily variation in many cellular functions arises through rhythmic post-translational regulation of protein activity. We suggest cellular circadian timing primarily functions to maintain proteome homeostasis rather than perturb it. Indeed, although relevant to timekeeping mechanism, daily rhythms of clock protein abundance may be the exception, not the rule. Informed by insights from yeast and mammalian models, we propose that optimal bioenergetic efficiency results from coupled rhythms in mammalian target of rapamycin complex activity, protein synthesis/turnover, ion transport and protein sequestration, which drive facilitatory rhythms in metabolic flux and substrate utilisation. Such daily consolidation of proteome renewal would account for many aspects of circadian cell biology whilst maintaining osmotic homeostasis.
    Keywords:  Biological clock; Cellular function; Circadian rhythm; Homeostasis; Ion transport; Macromolecular crowding; Metabolic cycle; Metabolism; Osmostasis; Protein synthesis; Protein turnover; Respiratory oscillation; TORC
    DOI:  https://doi.org/10.1016/j.coisb.2021.100391
  14. Nature. 2021 Dec 22.
    Structure of Hsp90-p23-GR reveals the Hsp90 client-remodelling mechanism.
    Chari M Noddings, Ray Yu-Ruei Wang, Jill L Johnson, David A Agard.
      Hsp90 is a conserved and essential molecular chaperone responsible for the folding and activation of hundreds of 'client' proteins1-3. The glucocorticoid receptor (GR) is a model client that constantly depends on Hsp90 for activity4-9. GR ligand binding was previously shown to nr inhibited by Hsp70 and restored by Hsp90, aided by the co-chaperone p2310. However, a molecular understanding of the chaperone-mediated remodelling that occurs between the inactive Hsp70-Hsp90 'client-loading complex' and an activated Hsp90-p23 'client-maturation complex' is lacking for any client, including GR. Here we present a cryo-electron microscopy (cryo-EM) structure of the human GR-maturation complex (GR-Hsp90-p23), revealing that the GR ligand-binding domain is restored to a folded, ligand-bound conformation, while being simultaneously threaded through the Hsp90 lumen. In addition, p23 directly stabilizes native GR using a C-terminal helix, resulting in enhanced ligand binding. This structure of a client bound to Hsp90 in a native conformation contrasts sharply with the unfolded kinase-Hsp90 structure11. Thus, aided by direct co-chaperone-client interactions, Hsp90 can directly dictate client-specific folding outcomes. Together with the GR-loading complex structure12, we present the molecular mechanism of chaperone-mediated GR remodelling, establishing the first, to our knowledge, complete chaperone cycle for any Hsp90 client.
    DOI:  https://doi.org/10.1038/s41586-021-04236-1
  15. Cells. 2021 Dec 19. pii: 3585. [Epub ahead of print]10(12):
    Single-Cell Transcriptomics Links Loss of Human Pancreatic β-Cell Identity to ER Stress.
    Nathalie Groen, Floris Leenders, Ahmed Mahfouz, Amadeo Munoz-Garcia, Mauro J Muraro, Natascha de Graaf, Ton J Rabelink, Rob Hoeben, Alexander van Oudenaarden, Arnaud Zaldumbide, Marcel J T Reinders, Eelco J P de Koning, Françoise Carlotti.
      The maintenance of pancreatic islet architecture is crucial for proper β-cell function. We previously reported that disruption of human islet integrity could result in altered β-cell identity. Here we combine β-cell lineage tracing and single-cell transcriptomics to investigate the mechanisms underlying this process in primary human islet cells. Using drug-induced ER stress and cytoskeleton modification models, we demonstrate that altering the islet structure triggers an unfolding protein response that causes the downregulation of β-cell maturity genes. Collectively, our findings illustrate the close relationship between endoplasmic reticulum homeostasis and β-cell phenotype, and strengthen the concept of altered β-cell identity as a mechanism underlying the loss of functional β-cell mass.
    Keywords:  ER stress; human pancreatic islets; islet integrity; single-cell RNAseq; type 2 diabetes; β-cells
    DOI:  https://doi.org/10.3390/cells10123585
This page is being maintained by Thomas Krichel. It was last updated on 2021‒12‒27 at 16:14:38.