A GPI anchor explains the unique biological features of the common NKG2D-ligand allele MICA*008

Ashiru, Omodele; López‐Cobo, Sheila; Fernández-Messina, Lola; Pontes, Samuel; Pandolfi, Rachele; Reyburn, Hugh; Valés‐Gómez, Mar

doi:10.1042/bj20130194

Cited by 71 publications

(94 citation statements)

References 35 publications

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“…Our observations are in line with findings by Ashiru et al (31), who demonstrated that MICA*008 can be anchored to the plasma membrane via GPI and released in association with exosomes or secreted through a mechanism that is dependent on exocytosis. Thus, effective blockade of sMICA release and accumulation in patient sera might require different strategies, depending on the patient's MICA genotype.…”

Section: Discussionsupporting

confidence: 82%

“…The notion that different MIC alleles exhibit distinct molecular structures and different shedding modalities (14,31) prompted us to examine whether the chemotherapeutic agents could differentially affect the release of distinct MICA alleles. To this end, the MM cell line LP1, which does not express endogenous MICA and MICB, was stably transduced with cDNA encoding MICA*008 (carrying a truncated cytoplasmic tail and released by exosomes or through exocytosis), MICA*019 (which represents the prototype of the long form of MICA alleles), or MICB and exposed to DOX treatment.…”

Section: Drug Treatment Of MM Cells Selectively Affects the Release Omentioning

confidence: 99%

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Genotoxic Stress Induces Senescence-Associated ADAM10-Dependent Release of NKG2D MIC Ligands in Multiple Myeloma Cells

Zingoni

Cecere

Vulpis

et al. 2015

The Journal of Immunology

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Genotoxic stress can promote antitumor NK cell responses by upregulating the surface expression of activating ligands on cancer cells. Moreover, a number of studies suggested a role for soluble NK group 2D ligands in the impairment of NK cell tumor recognition and killing. We investigated whether genotoxic stress could promote the release of NK group 2D ligands (MHC class I-related chain [MIC]A and MICB), as well as the molecular mechanisms underlying this event in human multiple myeloma (MM) cells. Our results show that genotoxic agents used in the therapy of MM (i.e., doxorubicin and melphalan) selectively affect the shedding of MIC molecules that are sensitive to proteolytic cleavage, whereas the release of the short MICA*008 allele, which is frequent in the white population, is not perturbed. In addition, we found that a disintegrin and metalloproteinase 10 expression is upregulated upon chemotherapeutic treatment both in patient-derived CD138(+)/CD38(+) plasma cells and in several MM cell lines, and we demonstrate a crucial role for this sheddase in the proteolytic cleavage of MIC by means of silencing and pharmacological inhibition. Interestingly, the drug-induced upregulation of a disintegrin and metalloproteinase 10 on MM cells is associated with a senescent phenotype and requires generation of reactive oxygen species. Moreover, the combined use of chemotherapeutic drugs and metalloproteinase inhibitors enhances NK cell-mediated recognition of MM cells, preserving MIC molecules on the cell surface and suggesting that targeting of metalloproteinases in conjunction with chemotherapy could be exploited for NK cell-based immunotherapeutic approaches, thus contributing to avoid the escape of malignant cells from stress-elicited immune responses

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Section: Discussionsupporting

confidence: 82%

Section: Drug Treatment Of MM Cells Selectively Affects the Release Omentioning

confidence: 99%

Genotoxic Stress Induces Senescence-Associated ADAM10-Dependent Release of NKG2D MIC Ligands in Multiple Myeloma Cells

Zingoni

Cecere

Vulpis

et al. 2015

The Journal of Immunology

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“…EVs can provide a suitable membrane scaffold for membrane-bound proteins to exhibit their proper activity and membrane distribution. Bioactive membrane proteins can be naturally located to and expressed on EV surfaces [51], and membrane-associated proteins known to cluster into microdomains, such as GPI-anchored proteins, are selectively sorted in EV membranes [62,115–117]. Thus, it is expected that the biological activity of membrane (-associated) proteins will be maximized in the membrane environment offered by EVs.…”

Section: Therapeutic Applications Of Surface-modified Evsmentioning

confidence: 99%

Extracellular vesicles as a platform for membrane‐associated therapeutic protein delivery

Yang

Hong

Cho

et al. 2018

J of Extracellular Vesicle

186

148

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Membrane proteins are of great research interest, particularly because they are rich in targets for therapeutic application. The suitability of various membrane proteins as targets for therapeutic formulations, such as drugs or antibodies, has been studied in preclinical and clinical studies. For therapeutic application, however, a protein must be expressed and purified in as close to its native conformation as possible. This has proven difficult for membrane proteins, as their native conformation requires the association with an appropriate cellular membrane. One solution to this problem is to use extracellular vesicles as a display platform. Exosomes and microvesicles are membranous extracellular vesicles that are released from most cells. Their membranes may provide a favourable microenvironment for membrane proteins to take on their proper conformation, activity, and membrane distribution; moreover, membrane proteins can cluster into microdomains on the surface of extracellular vesicles following their biogenesis. In this review, we survey the state-of-the-art of extracellular vesicle (exosome and small-sized microvesicle)-based therapeutics, evaluate the current biological understanding of these formulations, and forecast the technical advances that will be needed to continue driving the development of membrane protein therapeutics.

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“…First, MICA*A5.1 is a truncated protein because a single nucleotide insertion in exon 5 leads to the appearance of a premature stop codon. It does not have a cytoplasmic tail and can be found in human cells in two forms: a surface protein attached to the membrane by glycosylphosphatidylinositol (GPI) anchor or soluble forms in intracellular compartments [17]. Secondly, MICA*A5.1 is located aberrantly on the apical surface of intestinal epithelial cells, instead of the basolateral surface where the interaction with intraepithelial T lymphocytes and NK cells takes place.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, the allele MICA*A5.1 consists of five GCT repetitions plus a guanine insertion in the second triplet [12], leading to the appearance of a premature stop codon and the expression of a truncated protein. MICA*A5.1 differs from the other MICA proteins in several aspects, as the cell location or the attachment to membrane [9,16,17]. A crystal structure of extracellular domains of MICA from the Protein Data Bank [18] and a diagram of the transmembrane region can be seen in Fig.…”

Section: Introductionmentioning

confidence: 99%

MICAA4 protects against ulcerative colitis, whereas MICAA5.1 is associated with abscess formation and age of onset

Martínez-Chamorro

Moreno

Gómez‐García

et al. 2016

Clinical and Experimental Immunology

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SummaryUlcerative colitis (UC) is one of the two major forms of inflammatory bowel disease, the aetiology of which remains unknown. Several studies have demonstrated the genetic basis of disease, identifying more than 130 susceptibility loci. The major histocompatibility complex class I chainrelated gene A (MICA) is a useful candidate to be involved in UC pathogenesis, because it could be important in recognizing the integrity of the epithelial cell and its response to stress. The aim of this study was to analyse the relationship between polymorphisms in the transmembrane domain of MICA and susceptibility to develop UC. A total of 340 patients with UC and 636 healthy controls were genotyped for MICA transmembrane polymorphism using a polymerase chain reaction (PCR) combined with fluorescent technology. Different MICA alleles were determined depending on the PCR product size. The allele MICA*A4 was less frequent in patients than in controls (P 5 0Á003; OR 5 0Á643), and this protective role is higher when it forms haplotype with B*27 (P 5 0Á002; OR 5 0Á294). The haplotype HLA-B*52/MICA*A6 was also associated with UC [P 5 0Á001; odds ratio (OR) 5 2Á914]. No other alleles, genotypes or haplotypes were related with UC risk. Moreover, MICA*A5.1 is associated independently with abscesses (P 5 0Á002; OR 5 3Á096) and its frequency is lower in patients diagnosed between ages 17 and 40 years (P 5 0Á007; OR 5 0Á633), meaning an extreme age on onset. No association with location, extra-intestinal manifestations or need for surgery was found.

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A GPI anchor explains the unique biological features of the common NKG2D-ligand allele MICA*008

Cited by 71 publications

References 35 publications

Genotoxic Stress Induces Senescence-Associated ADAM10-Dependent Release of NKG2D MIC Ligands in Multiple Myeloma Cells

Genotoxic Stress Induces Senescence-Associated ADAM10-Dependent Release of NKG2D MIC Ligands in Multiple Myeloma Cells

Extracellular vesicles as a platform for membrane‐associated therapeutic protein delivery

MICAA4 protects against ulcerative colitis, whereas MICAA5.1 is associated with abscess formation and age of onset

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A GPI anchor explains the unique biological features of the common NKG2D-ligand allele MICA*008

Cited by 71 publications

References 35 publications

Genotoxic Stress Induces Senescence-Associated ADAM10-Dependent Release of NKG2D MIC Ligands in Multiple Myeloma Cells

Genotoxic Stress Induces Senescence-Associated ADAM10-Dependent Release of NKG2D MIC Ligands in Multiple Myeloma Cells

Extracellular vesicles as a platform for membrane‐associated therapeutic protein delivery

MICA*A4 protects against ulcerative colitis, whereas MICA*A5.1 is associated with abscess formation and age of onset

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Product

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MICAA4 protects against ulcerative colitis, whereas MICAA5.1 is associated with abscess formation and age of onset