Ingrid Perez-Alvarez scite author profile

Exenatide is an analog of the incretin hormone glucagon-like peptide (GLP-1) that is used for the treatment of T2D for their metabolic effects. In addition to its insulinotropic effects, exenatide increases functional islet mass and improves their survival. Improved outcomes have been reported in recent clinical islet transplantation trials for the treatment of type 1 diabetes. The purpose of this study was to investigate whether exenatide has anti-inflammatory properties in human islets. Exenatide treatment improved islet function, significantly reduced content of inflammation-related molecules (tissue factor, IFN-γ, IL-17, IL-1β, and IL-2) and caspase 3 activation, whereas increased phosphorylation of ERK1/2, STAT3, and Akt in vitro. Immunostaining showed expression of GLP-1R in β-cells but not in α-cells. IL-1β colocalized with GLP-1R in β-cells. Induction of serine proteinase inhibitor 9 (PI-9) was detected after exposure of human islets to exenatide in vitro and after transplantation into immunodeficient mice. GLP-1 induced PI-9 expression in vitro but to a lower extent than exenatide. This effect was partially blocked by the antagonist exendin-9 in vitro. As assessed by immunostaining PI-9 is mostly expressed in β-cells but not in α-cells. In conclusion, we describe anti-inflammatory and cytoprotective properties of exenatide in human islets. Exenatide-mediated PI-9 expression, the only known granzyme B inhibitor, unveils potential immunoregulatory properties.

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A Double Fail-Safe Approach to Prevent Tumorigenesis and Select Pancreatic β Cells from Human Embryonic Stem Cells

Qadir

Álvarez-Cubela

Belle

et al. 2019

Stem Cell Reports

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SummaryThe transplantation of human embryonic stem cell (hESC)-derived insulin-producing β cells for the treatment of diabetes is finally approaching the clinical stage. However, even with state-of-the-art differentiation protocols, a significant percentage of undefined non-endocrine cell types are still generated. Most importantly, there is the potential for carry-over of non-differentiated cell types that may produce teratomas. We sought to modify hESCs so that their differentiated progeny could be selectively devoid of tumorigenic cells and enriched for cells of the desired phenotype (in this case, β cells). Here we report the generation of a modified hESC line harboring two suicide gene cassettes, whose expression results in cell death in the presence of specific pro-drugs. We show the efficacy of this system at enriching for β cells and eliminating tumorigenic ones both in vitro and in vivo. Our approach is innovative inasmuch as it allows for the preservation of the desired cells while eliminating those with the potential to develop teratomas.

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RHD genotyping of serologic RhD‐negative blood donors in a hospital‐based blood donor center

et al. 2019

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BACKGROUND: Serologic RhD-negative blood donors are tested by a method known to detect weak D antigen expression. Serology does not detect all red blood cells with RhD expression and RHD genotyping has been used to identify variant RHD alleles, which may lead to some RhD expression. The aim of this study was to determine the frequency of RHD variant alleles in serologic RhD-negative blood donors at a hospital-based donor center in Los Angeles.STUDY DESIGN AND METHODS: RHD genotyping of serologic RhD-negative blood donors over a 20-month period was performed using the Immucor RHD BeadChip assay. DNA sequencing was performed when the RHD BeadChip assay failed to assign a genotype. For RHD variants known or suspected to result in RhD expression, recipients of previous blood donations were investigated for alloimmunization. RESULTS: RHD genotyping was performed in 1174RhD-negative blood donors, and 1122 were genotyped for RHCE variants. Eleven donors (0.94%) harbored mutations predicted to yield RhD expression. The predicted phenotypes were, in decreasing frequency, DEL, partial, and weak D phenotypes. Anti-D was not detected in 16 patients who had received blood from these donors after an average follow up of 182 days. CONCLUSION:Genotyping can be used to identify donors with the potential to sensitize RhD-negative recipients. In this limited study, 0.94% of serologic RhD-negative blood donors were found to have variant RHD alleles that might cause alloimmunization in RhD-negative recipients. To our knowledge, a study of this nature has not been reported in the United States.From the

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Safety analysis of apixaban versus warfarin in patients with advanced kidney disease

Bowie

Valencia

Perez-Alvarez

et al. 2018

J Thromb Thrombolysis

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Anticoagulation in patients with advanced kidney disease, defined as those with an eGFR < 25 mL/min, including patients with end-stage renal disease on hemodialysis, remains an area of controversy and debate. Due to safety concerns regarding the increased risk for bleeding in this population, these patients have been excluded from all large-scale, randomized controlled trials to date. Warfarin and apixaban are both FDA-approved for use in this population and although warfarin remains the anticoagulant of choice, apixaban use is steadily increasing. This review combines relevant literature to better understand the risk versus benefit of anticoagulation in patients with severe kidney disease as well as the safety of apixaban versus warfarin in this population. High rates of bleed were found among both anticoagulants in those with severe kidney disease, suggesting that the risk for bleed associated with anticoagulation may not outweigh the benefit of treatment. Apixaban was found to be superior in rates of major bleed in those with ESRD on HD and may be superior to warfarin in those with an eGFR < 25 mL/min. However, large-scale, randomized clinical trials are needed to validate these results. With the continued development of novel agents there may be superior alternatives to apixaban and warfarin in those with severe kidney disease in the future.

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Protection of Human Pancreatic Islets Using a Lentiviral Vector Expressing Two Genes: cFLIP and GFP

et al. 2008

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Pancreatic islet transplantation can provide insulin independence to diabetic patients. However, apoptosis of islets often leads to early graft failure. Genetic engineering with protective gene(s) can improve the viability of these cells. Here we show successful transduction of human islets with a feline immunodeficiency virus (FIV) vector expressing both a cytoprotective (cFLIP) gene and the green fluorescent protein (GFP). Despite using low virus titers to maximize safety, transduced islets expressed both genes, resulting in improved β-cell metabolic activity and viability. Although only ϳ10% of total islet cells were transduced, the significant viability advantages suggest a "barrier" effect in which protecting the periphery of the islet shields the core. These results provide the first demonstration that a lentiviral vector can express two genes in islets. Furthermore, the engineered islets are resistant to a variety of apoptotic stimuli, suggesting the potential of this approach in enhancing the viability of transplanted cells.

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