Pancreatic ß-cell imaging in humans: fiction or option?

Diabetes mellitus is a growing worldwide epidemic disease, currently affecting 1 in 12 adults. Treatment of disease complications typically consumes ∼10% of healthcare budgets in developed societies. Whilst immune-mediated destruction of insulin-secreting pancreatic ß cells is responsible for Type 1 diabetes, both the loss and dysfunction of these cells underly the more prevalent Type 2 diabetes. The establishment of robust drug development programmes aimed at ß-cell restoration is still hampered by the absence of means to measure ß-cell mass prospectively in vivo, an approach which would provide new opportunities for understanding disease mechanisms and ultimately assigning personalized treatments. In the present review, we describe the progress towards this goal achieved by the Innovative Medicines Initiative in Diabetes, a collaborative public-private consortium supported by the European Commission and by dedicated resources of pharmaceutical companies. We compare several of the available imaging methods and molecular targets and provide suggestions as to the likeliest to lead to tractable approaches. Furthermore, we discuss the simultaneous development of animal models that can be used to measure subtle changes in ß-cell mass, a prerequisite for validating the clinical potential of the different imaging tracers.

Patient-level meta-analysis of the EDITION 1, 2 and 3 studies: glycaemic control and hypoglycaemia with new insulin glargine 300 U/ml versus glargine 100 U/ml in people with type 2 diabetes.

AIMS: To conduct a patient-level meta-analysis of the EDITION 1, 2 and 3 studies, which compared the efficacy and safety of new insulin glargine 300 U/ml (Gla-300) with insulin glargine 100 U/ml (Gla-100) in people with type 2 diabetes (T2DM) on basal and mealtime insulin, basal insulin and oral antihyperglycaemic drugs, or no prior insulin, respectively. METHODS: The EDITION studies were multicentre, randomized, open-label, parallel-group, phase IIIa studies, with similar designs and endpoints. A patient-level meta-analysis of the studies enabled these endpoints to be examined over 6 months in a large population with T2DM (Gla-300, n = 1247; Gla-100, n = 1249). RESULTS: No significant study-by-treatment interactions across studies were found, enabling them to be pooled. The mean change in glycated haemoglobin was comparable for Gla-300 and Gla-100 [each -1.02 (standard error 0.03)%; least squares (LS) mean difference 0.00 (95% confidence interval (CI) -0.08 to 0.07)%]. Annualized rates of confirmed (≤3.9 mmol/l) or severe hypoglycaemia were lower with Gla-300 than with Gla-100 during the night (31% difference in rate ratio over 6 months) and at any time (24 h, 14% difference). Consistent reductions were observed in percentage of participants with ≥1 hypoglycaemic event. Severe hypoglycaemia at any time (24 h) was rare (Gla-300: 2.3%; Gla-100: 2.6%). Weight gain was low (<1 kg) in both groups, with less gain with Gla-300 [LS mean difference -0.28 kg (95% CI -0.55 to -0.01); p = 0.039]. Both treatments were well tolerated, with similar rates of adverse events. CONCLUSION: Gla-300 provides comparable glycaemic control to Gla-100 in a large population with a broad clinical spectrum of T2DM, with consistently less hypoglycaemia at any time of day and less nocturnal hypoglycaemia.

Evidence that the neuronal nitric oxide synthase inhibitor 7-nitroindazole inhibits monoamine oxidase in the rat: in vivo effects on extracellular striatal dopamine and 3,4-dihydroxyphenylacetic acid.

The present study investigated in vivo the kinetic of the changes in rat striatal extracellular concentrations of dopamine (DA), and its monoamine oxidase (MAO)-derived metabolite 3,4-dihydroxyphenylacetic acid (DOPAC), following administration either of nitric oxide (NO) synthase (NOS) inhibitors 7-nitroindazole (7-NI) and Nomega-nitro-l-arginine methyl ester (L-NAME) or of the widely used MAO inhibitor pargyline. DA and DOPAC concentrations were determined every 4 min by microdialysis combined with capillary zone electrophoresis coupled with laser-induced fluorescence detection (CZE-LIFD) and by differential normal pulse voltammetry (DNPV), respectively. Administration of 7-NI, both systemic (30 mg/kg, intraperitoneally, i.p.) or intrastriatal (1 mM through the microdialysis probe), as well as administration of pargyline (75 mg/kg, i.p.), induced simultaneously in the striatum a significant increase in extracellular DA and a significant decrease in extracellular DOPAC. However, administration of L-NAME (200 mg/kg, i.p.) produced a significant increase in striatal extracellular DA without changes in extracellular DOPAC. These data suggest a possible MAO inhibitory effect of 7-NI which seems to be restricted to this NOS inhibitor. These results may be of special interest for the studies on functional role of NO in the brain, particularly in dopaminergic transmission.

Involvement of oxidative reactions and extracellular protein chaperones in the rescue of misassembled thyroglobulin in the follicular lumen.

Reactive oxygen species (ROS) are involved in many pathological processes through modifications of structure and activity of proteins. ROS also participate in physiological pathways such as thyroid hormone biosynthesis, which proceeds through oxidation of the prothyroid hormone (thyroglobulin, Tg) and iodide. Regarding the colloidal insoluble multimerized Tg (m-Tg), which bears dityrosine bridges and is present in the follicular lumen, a mild oxidative system generated different soluble forms of Tg, more or less compacted by hydrophobic associations, and linked with Grp78 and Grp94. In vitro, the combined action of ROS and PDI, in the presence of free glutathione (reduced/oxidized), increased the solubility of this misassembled Tg and partially restored the ability of Tg to synthesize hormones. Our results show that protein chaperones escape from the ER and are involved with ROS in thyroid hormone synthesis. Therefore, we propose a model of roles of m-Tg in the follicular lumen.

Evidence that the neuronal nitric oxide synthase inhibitor 7-nitroindazole inhibits monoamine oxidase in the rat: in vivo effects on extracellular striatal dopamine and 3,4-dihydroxyphenylacetic acid.

The present study investigated in vivo the kinetics of the changes in rat striatal extracellular concentrations of dopamine (DA), and its monoamine oxidase (MAO)-derived metabolite 3,4-dihydroxyphenylacetic acid (DOPAC), following administration either of nitric oxide (NO) synthase inhibitors 7-nitroindazole (7-NI) and N(omega)-nitro-L-arginine methyl ester (L-NAME) or of the widely used MAO inhibitor pargyline. DA and DOPAC concentrations were determined every 4 min by microdialysis combined with capillary zone electrophoresis coupled with laser-induced fluorescence detection (CZE-LIFD) and by differential normal pulse voltammetry (DNPV), respectively. Administration of 7-NI, both systemic (30 mg/kg, i.p.) or intrastriatal (1 mM through the microdialysis probe), as well as administration of pargyline (75 mg/kg, i.p.), induced simultaneously in the striatum a significant increase in extracellular DA and a significant decrease in extracellular DOPAC. On the other hand, administration of L-NAME (200 mg/kg, i.p.) produced a significant increase in striatal extracellular DA without changes in extracellular DOPAC. These data suggest a possible MAO inhibitory effect of 7-NI which seems to be restricted to this NOS inhibitor. These results may be of special interest for the studies on the functional role of NO in the brain, particularly in dopaminergic transmission.

A conformational B-cell epitope on the C-terminal end of the extracellular part of human thyroid peroxidase.

To investigate the B-cell autoimmune epitopes on human thyroid peroxidase (TPO), we generated proteolytic peptides by enzymatic hydrolysis of TPO in nondenaturing and nonreducing conditions. The hydrolysate was chromatographed on a reverse phase column. We eluted a material immunoreactive with both a TPO monoclonal antibody recognizing a linear epitope (mAb47, amino acid 713-721) and TPO autoantibodies (aAb) from patients. The aAb immunoreactivity, but not that of mAb47, was lost after reduction. Western blots after electrophoresis without reduction showed that the aAb and mAb47 were immunoreactive with a 66-kDa band and that aAb identified a doublet at 20 kDa. For electrophoresis under reducing conditions, the 66-kDa band resolved into two peptides of 40 and 26 kDa, whereas the doublet at 20 kDa remained unchanged. None of these reduced peptides was immunoreactive with aAb, whereas the 40-kDa peptide was immunoreactive with mAb47. The 40-kDa peptide extends from amino acid 549 to 933 of TPO, and its last 192 amino acids overlap the autoimmune 20-kDa peptide. After iodine labeling, the 20-kDa peptide lost its immunoreactivity. We conclude that the C-terminal end of the extracellular part of TPO, which includes all the tyrosine residues of the 20-kDa peptide, contains at least one conformational B-cell epitope involved in autoimmune thyroid diseases.

Role of multimerized porcine thyroglobulin in iodine storage.

Thyroglobulin (Tg), the prothyroid hormone, is stored in the lumen of the thyroid follicles as soluble dimers and tetramers and insoluble multimers, Soluble Tg is well characterized with regards to structure and role, but insoluble Tg (i-Tg) is not. Here we show that i-Tg, multimerized through formation of disulfide and dityrosine bonds, has a higher iodine content than soluble Tg and no thyroid hormones. Furthermore, the size and the resistance of i-Tg to proteolytic enzymes implied a new mechanism by which thyrocytes may degrade this form of Tg. Using peroxidase and H2O2 generating system, we found that about 80% of i-Tg was degraded and 24% of its iodine content was released. Our data point to a role for i-Tg in iodine storage and the involvement of TPO in i-Tg degradation and iodide release.

A micromethod for quantitative determination of iodoamino acids in thyroglobulin.

We describe a new method for quantification of iodoamino acids after enzymatic hydrolysis of thyroglobulin. The procedure involves separation of monoiodotyrosine (MIT), di-iodotyrosine, tri-iodothyronine and thyroxine by reverse phase HPLC with a Vydac C18 stationary phase and a mobile phase of water-acetonitrile-acetic acid. The separation is monitored by sensitive spectrophotometric detection through a 96-well microplate system based on the catalytic Sandell-Kolthoff reaction of iodide on the oxidation of arsenic(III) by cerium(IV). This new microassay is particularly convenient because of its high sensitivity and its rapidity (less than 2 h). It can detect 1 pmol MIT and 0.5 pmol of the other three iodoamino acids with a recovery higher than 96%. Moreover, the 96-well microplate system allows many samples to be tested simultaneously and avoids the use of radiolabeled iodine.

Dityrosine bridge formation and thyroid hormone synthesis are tightly linked and are both dependent on N-glycans.

Formation of dityrosine bridges is a ubiquitous process mainly attributed to oxidative stress leading to protein degradation and cellular damages. Here we show that dityrosine formation is involved in a physiological process, thyroid hormone synthesis, and is strictly dependent on structural characteristics, namely N-glycans, presented by the protein acting as the prothyroid hormone. We used two isoforms of the N-terminal thyroid hormone forming domain (NTD) of human thyroglobulin: one without N-glycan (19 kDa isoform) and the other with high mannose type structures (25 kDa isoform). Both isoforms were able to form iodotyrosines after in vitro iodination. However, iodotyrosine coupling to form thyroxine did not occur with the unglycosylated 19 kDa NTD. In contrast, the 25 kDa isoform formed thyroxine. Strikingly, thyroxine synthesis was accompanied by dimerization of the 25 kDa isoform and formation of a dityrosine bridge; none of this was observed with the 19 kDa isoform. Taken as a whole, our results indicate that dimerization through dityrosine bridging accompanies and could have a role in thyroid hormone synthesis.

Hormone formation in the isolated fragment 1-171 of human thyroglobulin involves the couple tyrosine 5 and tyrosine 130.

The 22 kDa fragment (Asn1-Met171) purified from iodine-poor human thyroglobulin (hTg) is capable by itself to synthesize thyroxine at Tyr5, the preferential hormonogenic acceptor site of the protein, after iodination in vitro. To identify the corresponding donor site in this model we studied the fate of the six Tyr residues present in the 22 kDa peptide after in vitro hormone synthesis. Structural studies of the tyrosyl peptides showed that Tyr5 was the only thyroxine-forming site, the other tyrosines (29, 89, 97 and 107) were noniodinated and Tyr130 was recovered in alanine form after CNBH4 treatment of the Tyr130-containing peptide. Taking into account that alanine could arise from aminoreduced pyruvate species, these results showed that in the 22 kDa fragment (1) hormone formation involves the couple Tyr5 (acceptor)-Tyr130 (donor), and (2) dehydroalanine, the resultant product of donor tyrosine after hormone synthesis, has evolved in pyruvoyl form. To test whether Tyr130 could also act as donor in hTg hormone synthesis, the 22 kDa peptide was isolated from hTg iodinated under conditions leading to iodotyrosine formation followed or not by hormone formation and the tyrosyl peptides were analyzed. After hTg iodination and before coupling (i.e. hormone synthesis) only Tyr5 and Tyr130 were recovered in iodotyrosine form; after coupling thyroxine was found at Tyr5 whereas Tyr130 disappeared. Taken together these results, correlated with the previously reported cleavage of hTg chain at Tyr130 occurring during in vivo hormone synthesis, support the theory that the couple Tyr5 (acceptor)-Tyr130 (donor) would be the preferential hormonogenic site in human Tg.

Hormone synthesis in human thyroglobulin: possible cleavage of the polypeptide chain at the tyrosine donor site.

At moderate iodination levels (20 iodine atoms/mol) human thyroglobulin (hTg) produces after reduction a hormone-rich peptide of 26 kDa which contains the preferential hormonogenic 'acceptor' tyrosine (Tyr 5) of the protein. The site of cleavage of the hTg chain was demonstrated by analysis of the 26 kDa tryptic hydrolysis products. It consistently yielded the peptide Gln-82-Val-129 which consequently made it possible to localize the hTg chain cleavage at tyrosine residue 130. Evidence for tyrosine involvement in hTg cleavage during thyroid hormone formation supports the hypothesis that peptide bond cleavage would occur at the 'donor' tyrosine residue and suggests that tyrosine 130 would be the donor site reacting with the major hormone-forming acceptor site (Tyr 5) of hTg.