The C‐terminal cytosolic domain of the human zinc transporter ZnT8 and its diabetes risk variant

Parsons, D.; Högstrand, Christer; Maret, Wolfgang

doi:10.1111/febs.14402

Cited by 39 publications

(62 citation statements)

References 49 publications

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“…This enables ZnT, in contrast to YiiP, to discriminate between Zn 2+ and the toxic ion Cd 2+ [81]. Other studies point to the cytoplasmic domain as important for transporter activity as described for ZnT8 [60], as well as in ZnT10 where a L349P missense mutation in the CTD affects transporter activity, and a synonymous mutation (M250P) in the prokaryotic CDF protein, MamM, was found to be critical for the CTD fold illustrating the importance of the CTD [82]. The identification of a CDF superfamily lacking the CTD, however, points to additional strategies for zinc transport by ZnT transporters [43].…”

Section: Znt Transportersmentioning

confidence: 95%

“…It is expressed in pancreatic beta cells and functions as target autoantigen in patients with type 1 diabetes [59]. A common W325R variant in the ZnT8 large C-terminal domain (CTD) has been associated with changed autoantibody specificity in type 1 diabetes as well as increased risk of developing type 2 diabetes [60]. ZIP14 and ZIP4 were also found to be involved in diabetes as altered zinc trafficking in Zip14 −/− mice resulted in a phenotype with defects in glucose homeostasis [45], and in the murine pancreatic beta cell line MIN6, overexpression of ZIP4 leads to increased granular zinc content and glucose-stimulated insulin secretion [50].…”

Section: Diabetesmentioning

confidence: 99%

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Why and how to investigate the role of protein phosphorylation in ZIP and ZnT zinc transporter activity and regulation

Thingholm

Rönnstrand

Rosenberg

2020

Cell. Mol. Life Sci.

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Zinc is required for the regulation of proliferation, metabolism, and cell signaling. It is an intracellular second messenger, and the cellular level of ionic, mobile zinc is strictly controlled by zinc transporters. In mammals, zinc homeostasis is primarily regulated by ZIP and ZnT zinc transporters. The importance of these transporters is underscored by the list of diseases resulting from changes in transporter expression and activity. However, despite numerous structural studies of the transporters revealing both zinc binding sites and motifs important for transporter function, the exact molecular mechanisms regulating ZIP and ZnT activities are still not clear. For example, protein phosphorylation was found to regulate ZIP7 activity resulting in the release of Zn 2+ from intracellular stores leading to phosphorylation of tyrosine kinases and activation of signaling pathways. In addition, sequence analyses predict all 24 human zinc transporters to be phosphorylated suggesting that protein phosphorylation is important for regulation of transporter function. This review describes how zinc transporters are implicated in a number of important human diseases. It summarizes the current knowledge regarding ZIP and ZnT transporter structures and points to how protein phosphorylation seems to be important for the regulation of zinc transporter activity. The review addresses the need to investigate the role of protein phosphorylation in zinc transporter function and regulation, and argues for a pressing need to introduce quantitative phosphoproteomics to specifically target zinc transporters and proteins involved in zinc signaling. Finally, different quantitative phosphoproteomic strategies are suggested.

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Section: Znt Transportersmentioning

confidence: 95%

Section: Diabetesmentioning

confidence: 99%

Why and how to investigate the role of protein phosphorylation in ZIP and ZnT zinc transporter activity and regulation

Thingholm

Rönnstrand

Rosenberg

2020

Cell. Mol. Life Sci.

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“…A recent (>44K) exome sequencing study reported >30 alleles in SLC30A8 reducing the risk of T2D, confirming it as a robust target for T2D protection 4 . Further, the SLC30A8 gene also harbors a common variant (rs13266634, c.973T>A) p.Trp325Arg in the C-terminal domain 5 . While the major p.Arg325 allele (>70% of the population) confers increased risk for T2D, the minor p.Trp325 allele is protective 6 .…”

Section: Introductionmentioning

confidence: 99%

Loss of ZnT8 function protects against diabetes by enhanced insulin secretion

Dwivedi

Lehtovirta

Hastoy

et al. 2018

Preprint

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69A rare loss-of-function variant p.Arg138* in SLC30A8 encoding the zinc transporter 8 (ZnT8) 70 enriched in Western Finland protects against type 2 diabetes (T2D). We recruited relatives of the 71 identified carriers and showed that protection was associated with better insulin secretion due to 72 enhanced glucose responsiveness and proinsulin conversion, especially compared with individuals 73 matched for the genotype of a common T2D risk variant in SLC30A8, p.Arg325. In genome-edited 74 human IPS-derived β-like cells, we establish that the p.Arg138* variant results in reduced SLC30A8 75 expression due to haploinsufficiency. In human β-cells loss of SLC30A8 leads to increased glucose 76 responsiveness and reduced K ATP channel function, which was also seen in isolated islets from 77 carriers of the T2D-protective allele p.Trp325. These data position ZnT8 as an appealing target for 78 treatment aiming at maintaining insulin secretion capacity in T2D. 79 80 106 Results 107 Recruitment by genotype 108Given the enrichment of the p.Arg138*-SLC30A8 variant in Western Finland, we genotyped

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“…We also reported a protective frameshift allele p.Lys34Serfs50* conferring 83% protection against T2D in Iceland 3 . Further, the SLC30A8 gene harbors a common variant (rs13266634, c.973C>T) p.Trp325Arg in the C-terminal domain 4 . Whilst the major p.Arg325 allele (>70% of the population) confers increased risk for T2D, the minor p.Trp325 allele is protective 5 .…”

mentioning

confidence: 99%

Loss of ZnT8 function protects against diabetes by enhanced insulin secretion

et al. 2019

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Data Availability Individual level data for the human study can only be obtained via the Biobank of The Institute of Health and Welfare in Finland (https://thl.fi/en/web/thl-biobank). Next-generation sequencing data have been deposited in the SRA data base (PRJNA563975) and its processed counts data could be found in the Supplementary Dataset 1. The individual processed data from cell lines (Fig. 4 and 5), mice studies (Fig. 6) and human islet work (Fig. 7) are available in the Source Data files. Additional data supporting the findings of this study are available on request from the corresponding author.

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The C‐terminal cytosolic domain of the human zinc transporter ZnT8 and its diabetes risk variant

Cited by 39 publications

References 49 publications

Why and how to investigate the role of protein phosphorylation in ZIP and ZnT zinc transporter activity and regulation

Why and how to investigate the role of protein phosphorylation in ZIP and ZnT zinc transporter activity and regulation

Loss of ZnT8 function protects against diabetes by enhanced insulin secretion

Loss of ZnT8 function protects against diabetes by enhanced insulin secretion

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