A clinically relevant modification to existing inhaler therapy.

A modified formulation of inhaled salbutamol and a new inhaler device were studied in a group of 11 moderate-to-severe asthmatic patients. Changes in airway calibre (FEV1, Vmax30) were measured before and after inhalation of the new formulation, and compared with changes following inhalation of conventional salbutamol. A standard Rotahaler was used as a reference for the new inhaler. The study was conducted as a two-part randomized, double-blind cross-over trial. We found a significantly greater bronchodilatation of the larger airways using the modified drug in the Rotahaler. The new inhaler did not show any superiority over the Rotahaler, contrary to expectations from in vitro work. A slightly shorter model may better reflect the in vitro results. The study has implications for inhalation therapy in general.     

Telomere shortening during aging of human osteoblasts in vitro and leukocytes in vivo: lack of excessive telomere loss in osteoporotic patients

We have compared the telomere length, as assessed by Southern analysis, of telomere restriction fragments (TRFs) generated by RsaI/HinfI digestion of genomic DNA in: (i) in vitro cultured human trabecular osteoblasts undergoing cellular aging; and (ii) peripheral blood leukocytes (PBL) obtained from three groups of women: young (aged 20-26 years, n = 15), elderly (aged 48-85 years, n = 15) and osteoporotic (aged 52-81 years, n = 14). The mean TRF length in human osteoblasts undergoing aging in vitro decreased from an average of 9.32 kilobasepairs (kb) in middle-aged cells to an average of 7.80 kb in old cells. The rate of TRF shortening was about 100 bp per population doubling, which is similar to what has been reported for other cell types, such as human fibroblasts. Furthermore, there was a 30% decline in the total amount of telomeric DNA in senescent osteoblasts as compared with young cells. In the case of PBL, TRF length in the DNA extracted from young women was slightly longer (6.76 +/- 0.64 kb) than that from a group of elderly women (6.42 +/- 0.71 kb). A comparison of TRFs in the DNA extracted from the PBL from osteoporotic patients and from age-matched controls did not show any significant differences (6.47 +/- 0.94 versus 6.42 +/- 0.71 kb, respectively). Therefore, using TRF length as a marker for cellular aging in vitro and in vivo, our data comparing TRFs from osteoporotic patients and age-matched controls do not support the notion of the occurrence of a generalized premature cellular aging in osteoporotic patients.     

Genomic Regions That Underlie Soybean Seed Isoflavone Content

Soy products contain isoflavones (genistein, daidzein, andglycitein) that display biological effects when ingested byhumans and animals, these effects are species, dose and agedependent. Therefore, the content and quality of isoflavones insoybeans is a key to their biological effect. Our objective wasto identify loci that underlie isoflavone content in soybeanseeds. The study involved 100 recombinant inbred lines (RIL) fromthe cross of ‘Essex' by ‘Forrest,' two cultivars that contrastfor isoflavone content. Isoflavone content of seeds from each RILwas determined by high performance liquid chromatography (HPLC).The distribution of isoflavone content was continuous andunimodal. The heritability estimates on a line mean basis were79% for daidzein, 22% for genistein, and 88% for glycitein.Isoflavone content of soybean seeds was compared against 150polymorphic DNA markers in a one-way analysis of variance. Fourgenomic regions were found to be significantly associated withthe isoflavone content of soybean seeds across both locations andyears. Molecular linkage group B1 contained a major QTLunderlying glycitein content (P = 0.0001, R² = 50.2%), linkagegroup N contained a QTL for glycitein (P = 0.0033, R² = 11.1%)and a QTL for daidzein (P = 0.0023, R² = 10.3%) and linkagegroup A1 contained a QTL for daidzein (P = 0.0081, R² = 9.6%).Selection for these chromosomal regions in a marker assistedselection program will allow for the manipulation of amounts andprofiles of isoflavones (genistein, daidzein, and glycitein)content of soybean seeds. In addition, tightly linked markers canbe used in map based cloning of genes associated withisoflavone content.     

In vivo induction of tolerance by an Ig peptide is not affected by the deletion of FcR or a mutated IgG Fc fragment

To induce tolerance to a variety of epitopes, we have designed a gene therapy approach in which peptides or antigens are expressed in frame on a soluble IgG fusion protein scaffold and delivered via retroviral gene therapy in B cells in vivo. Initially, tolerance to the lambda repressor cI sequence p1-102 or its immunodominant epitopes (e.g. p12-26 or p73-88) was elicited in both T cells and B cells when lipopolysaccharide (LPS) blasts are transduced and injected into naive or even primed recipients. While a role of secreted Ig fusion protein in this process is not clear, we have previously demonstrated the importance of antigen presentation on MHC class II of B cell antigen-presenting cells (APC) for tolerance induction. To further examine the role of the Ig and especially of the Fc portion of the IgG in tolerogenesis, we transduced LPS blasts from FcR gamma II(-/-), Fc gamma RI(-/-), Fc gamma RIII(-/-), FcR(-/-) or naive mice with retroviral vectors expressing IgG1-102, Delta IgG1-102 (mutated construct on position 297 of the Fc portion) or IgG12-26. When these transduced LPS blasts from FcR knockout mice were injected into normal (or knockout) syngeneic recipient mice, they induced tolerance both to the immunodominant epitopes and the full-length protein in that the antibody responses to the immunodominant epitopes were reduced. In this paper, we show that this tolerance resides at both the T and B cell level. Moreover, mutation of residue 297, which affects IgG functions including FcR binding, did not alter the tolerogenicity of the construct. These results suggest that the Fc portion of the IgG molecules is not required for humoral nor for cellular tolerance induction using the IgG-antigen tolerogens.     

In Vitro Impact of Pro-Senescent Endothelial Microvesicles on Isolated Pancreatic Rat Islets Function

BackgroundIschemia-driven islet isolation procedure is one of the limiting causes of pancreatic islet transplantation. Ischemia-reperfusion process is associated with endothelium dysfunction and the release of pro-senescent microvesicles. We investigated whether pro-senescent endothelial microvesicles prompt islet senescence and dysfunction in vitro.Material and methodsPancreatic islets were isolated from male young rats. Replicative endothelial senescence was induced by serial passaging of primary porcine coronary artery endothelial cells, and microvesicles were isolated either from young passage 1 (P1) or senescent passage 3 (P3) endothelial cells. Islet viability was assessed by fluorescence microscopy, apoptosis by flow cytometry, and Western blot. Function was assessed by insulin secretion and islet senescence markers p53, p21, and p16 by Western blot. Microvesicles were stained by the PKH26 lipid fluorescent probe and their islet integration assessed by microscopy and flow cytometry.ResultsRegardless of the passage, half microvesicles were integrated in target islets after 24 hours incubation. Insulin secretion significantly decreased after treatment by senescent microvesicles (P3: 1.7 ± 0.2 vs untreated islet: 2.7 ± 0.2, P < .05) without altering the islet viability (89.47% ± 1.69 vs 93.15% ± 0.97) and with no significant apoptosis. Senescent microvesicles significantly doubled the expression of p53, p21, and p16 (P < .05), whereas young microvesicles had no significant effect.ConclusionPro-senescent endothelial microvesicles specifically accelerate the senescence of islets and alter their function. These data suggest that islet isolation contributes to endothelial driven islet senescence.     

Bone From Blood: Characteristics and Clinical Implications of Circulating Osteogenic Progenitor (COP) Cells

Circulating osteogenic progenitor (COP) cells are a population of cells in the peripheral blood with the capacity for bone formation, as well as broader differentiation into mesoderm-like cells in vitro. Although some of their biological characteristics are documented in vitro, their role in diseases of the musculoskeletal system remains yet to be fully evaluated. In this review, we provide an overview of the role of COP cells in a number of physiological and pathological conditions, as well as identify areas for future research. In addition, we suggest possible areas for clinical utilization in the management of musculoskeletal diseases. © 2020 American Society for Bone and Mineral Research (ASBMR).     

Discovery and Validation of a Urinary Exosome mRNA Signature for the Diagnosis of Human Kidney Transplant Rejection

BackgroundDeveloping a noninvasive clinical test to accurately diagnose kidney allograft rejection is critical to improve allograft outcomes. Urinary exosomes, tiny vesicles released into the urine that carry parent cells’ proteins and nucleic acids, reflect the biologic function of the parent cells within the kidney, including immune cells. Their stability in urine makes them a potentially powerful tool for liquid biopsy and a noninvasive diagnostic biomarker for kidney-transplant rejection.MethodsUsing 192 of 220 urine samples with matched biopsy samples from 175 patients who underwent a clinically indicated kidney-transplant biopsy, we isolated urinary exosomal mRNAs and developed rejection signatures on the basis of differential gene expression. We used crossvalidation to assess the performance of the signatures on multiple data subsets.ResultsAn exosomal mRNA signature discriminated between biopsy samples from patients with all-cause rejection and those with no rejection, yielding an area under the curve (AUC) of 0.93 (95% CI, 0.87 to 0.98), which is significantly better than the current standard of care (increase in eGFR AUC of 0.57; 95% CI, 0.49 to 0.65). The exosome-based signature’s negative predictive value was 93.3% and its positive predictive value was 86.2%. Using the same approach, we identified an additional gene signature that discriminated patients with T cell–mediated rejection from those with antibody-mediated rejection (with an AUC of 0.87; 95% CI, 0.76 to 0.97). This signature’s negative predictive value was 90.6% and its positive predictive value was 77.8%.ConclusionsOur findings show that mRNA signatures derived from urinary exosomes represent a powerful and noninvasive tool to screen for kidney allograft rejection. This finding has the potential to assist clinicians in therapeutic decision making.