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An interesting subclass of the SLs are Cers, the simplest SLs. Cers are assigned a special role within SLs because of their involvement in many cellular and biophysical processes.In literature Cers are describe to modulate many events in signaling including apoptosis. Besides its role as second messenger and therefore the involvement in many signal cascades, Cers are also known to be essential in physical modifications and structural alternations of membranes. Such regulatory functions on membrane formation are e.g. domain formation with other lipids (i.g. SM and Chol), phase separation with sterols (Chol), vesicular trafficking, fusion, membrane curvature fluidity and thickness and the induction of membrane leakiness. In contrast to phospholipids, Cers can move from one side of the membrane leaflet to the other, due to their strong hydrophobicity. This movement is called flip-flop or as transbilayer movement and is controversially discussed. Consequently, no exact value has been reported about the flip-flop property of Cers, which probably plays an important role during the transmission of an extra cellular signal through the membrane.In order to probe the biophysical properties of ceramides, a synthetic access to 1-thioceramides (1-SHCer) analogues with different N-acyl chain length has been developed in this study. With 1SHCer the flip-flop was investigated on pre-formed liposomes and the data indicated a very rapid flip-flop of Cers with a half time t1/2 <10s in raft- and non-raft like membrane models. Furthermore, the acyl chain length exhibited no measurable impact on the speed of the flip-flop. Utilizing the same probes the importance of hydrogen bond donor and acceptor properties of Cers upon interaction with sphingomyelin in the presence or absence of cholesterol (Chol) has been probed. Performed fluorescent quenching experiments (P.Slotte) proposed the following relative preference in interaction with pSM:pSM:DAGs > pSM:Cer > pSM:Chol > pSM: 1-pCerSH.Most strikingly, the importance of the 1-OH H-bond acceptor functionality to replace Chol around and above the melting temperature of pSM has been demonstrated. Recently, an unusual subclass of SLs, named 1-deoxysphingoids have come to the foreground, as biomarker for metabolic disorders. 1-doxSA is physiologically generated (10-40nM) due to substrate promiscuity of SPT and shown to be elevated in patients with metabolic disorders. In this study an organic synthetic access to fluorescent DSB derivatives was established, featuring a fluorescent moiety at the lipid tail, such as FITC 26. Comprehensive fluorescent studies of 26 revealed an unusual subcellular distribution. Exogenous 1-doxSA analogues, such as FB1 and 1-doxSA-FITC, enter via specific entry points. During the next few hours these lipids accumulate within the cytosol prior to N-acylation by CerS. Upon N-acylation, the newly formed 1-doxdhCer and its analogues insert into the ER membrane.The fluorescent probe and most likely FB1 analogues accumulate within the late endosomal and lysosomal system, probably via a direct connection with the ER. Analysis of the lipid metabolism of unlabeled 1-doxSA and FB1 revealed a strikingly similar behavior, pointing towards a common pharmacological effect. Complete consumption of TG within 24h in epithelia cells combined with GO analysis of 1-doxSA interacting lipids indicates significant modulation of fatty acid degradation, pointing towards regulation of the energy metabolism. This is in good agreement with the observed induction of autophagy. Together, this rapid and similar metabolic change of both 1-doxSA and FB1, points toward direct 1-doxSA head-group related lipid-protein interaction and less toward the influence of FB1 on CerS activity. This work suggests the biological significance of 1-doxSA as a primary nutrient sensor to maintain nutrient homeostasis and its role in the pathophysiology of metabolic diseases.
The term diabetes mellitus comprises a group of metabolic diseases all distinguished by their main characteristic hyperglycaemia. With a steadily increasing prevalence diabetes displays an enormous burden for patients and health systems and is therefore of special interest for research. The development of the two main types of diabetes, type 1 and type 2, is closely linked to the formation of reactive species, especially hydrogen peroxide, inside different compartments of pancreatic beta cells. However, these cells are especially vulnerable towards oxidative stress mediated by hydrogen peroxide due to a low expression of antioxidative enzymes.
The main aims of the present thesis were to analyse the intracellular generation and to enable the site-specific detection of hydrogen peroxide to evaluate its role in the delicate equilibrium between redox signalling and oxidative stress under certain pathophysiological conditions, and moreover to monitor its movement through compartments and subcellular membranes of insulin-producing cells. Additionally, a new methodology for an artificial site-specific generation of hydrogen peroxide inside living cells was developed.
Type 2 diabetes mellitus is one of the most challenging health problems for the next decades. The impact of type 2 diabetes mellitus on health care systems is largely driven by the increasing prevalence, the management of the disease and subsequent comorbidities, even in people with prediabetes or undiagnosed type 2 diabetes mellitus. An early detection of high risk groups is necessary to identify and modify risk factors such as obesity, physical inactivity or cigarette smoking which showed regional disparities in their distribution within a country. This leads to the assumption that there might be regional disparities regarding the prevalence and incidence of type 2 diabetes mellitus as well. For Germany as for other countries, comparable data on possible regional disparities in the prevalence and incidence of type 2 diabetes mellitus are missing. The aim of the present dissertation is to estimate the prevalence and incidence of type 2 diabetes mellitus on regional level within Germany, and to estimate the smoking prevalence as a modifiable risk factor in individuals with type 2 diabetes mellitus using data from the Diabetes Collaborative Research of Epidemiologic Studies consortium (DIAB CORE) within the Competence Net Diabetes in Germany. Well comparable data of five regional studies and one nationwide reference study are included: the Study of Health in Pomerania (SHIP); the Cardiovascular Disease, Living and Ageing in Halle Study (CARLA); the Dortmund Health Study (DHS); the Heinz Nixdorf Recall Study (HNR); the Cooperative Health Research in the Region of Augsburg Study (KORA); and the German National Health Interview and Examination Survey 1998 (GNHIES 98). First, the prevalence of type 2 diabetes mellitus was estimated. Data from five regional population-based studies and one nationwide study conducted between 1997 and 2006 with participants aged 45 to 74 years were analyzed. Type 2 diabetes mellitus prevalence estimates based on self-reports (standardized to the German population for the regional studies, reference date 2007/12/31) were compared. Of 11,688 participants of the regional studies, 1,008 had a known type 2 diabetes mellitus, corresponding to a prevalence of 8.6% (95% confidence interval [CI] 8.1% 9.1%). The standardized prevalence was highest in the East with 12.0% (95% CI 10.3% 13.7%) and lowest in the South of Germany with 5.8% (95% CI 4.9% 6.7%).Second, the incidence of type 2 diabetes mellitus was estimated. Data from participants (baseline age 45 to 74 years) from five regional population-based studies were included. The incidence rates per 1,000 person-years (95% CI) and the cumulative incidence (95% CI) from regional studies were directly standardized to the German population (reference date 2007/12/31) and weighted by inverse probability weights for losses to follow-up. Of 8,787 participants, 521 (5.9%) developed type 2 diabetes mellitus corresponding to an incidence rate of 11.8 per 1,000 person-years (95% CI 10.8 12.9). The incidence of known type 2 diabetes mellitus showed regional disparities within Germany. The incidence was highest in the East and lowest in the South of Germany with 16.9 (95% CI 13.3 21.8) vs. 9.0 (95% CI 7.4 11.1) per 1,000 person-years, respectively. Third, the smoking prevalence in participants aged 20 to 79 years with type 2 diabetes mellitus in the regional SHIP and the nationwide GNHIES 98 was estimated. Prevalence estimates of cigarette smoking were calculated using weights reflecting the European adult population (reference date 2005/12/31). The overall prevalence of current smoking was lower among participants with type 2 diabetes mellitus than among participants without type 2 diabetes mellitus (17.3% vs. 38.0% in SHIP and 24.7% vs. 32.1% in GNHIES 98). In both studies, the prevalence of current smoking was highest in men aged 20 to 39 years, in particular among men with type 2 diabetes mellitus. To conclude, considerable disparities in prevalence and incidence of type 2 diabetes mellitus indicate the need for interventions on the regional level within Germany. Former smoking was more prevalent among both men and women with type 2 diabetes mellitus in comparison to current and non-smoking. This finding probably reflects behavioural changes secondary to the disease onset and medical counselling. The finding that men aged 20 to 39 years with type 2 diabetes mellitus were more often current smokers than men without type 2 diabetes mellitus underpins the importance of smoking as one of the main modifiable risk factors for type 2 diabetes mellitus.
Pretransplant Tolerance Induction Reduces the Islet Mass Required to Reverse Diabetes in NOD Mice
(2007)
Islet transplantation can restore normoglycemia in diabetic patients. However, its application is limited by the high number of islets required to reverse diabetes. As the mass and potency of most human islet preparations are marginal, a large impact on the applicability of islet transplantation is expected from the implementation of strategies that improve engraftment of these islet preparations. The roles of adaptive immunity and immunosuppression on islet engraftment are not well studied. Therefore, the effects of currently used immunosuppression with antilymphocyte serum, tacrolimus and sirolimus on islet engraftment were separated from their impact on immunity and diabetes reversal rates were compared after islet allotransplantation in immunosuppressed and chimeric, non-immunosuppressed NOD mice. Both strategies prevented rejection of islet allografts and reduced the frequency of donor-specific, IFN-gamma-secreting T cells. However, in order to achieve stable diabetes reversal with a probability of about 80% after islet allotransplantation in diabetic NOD mice, a fourfold higher islet mass (400 islets) was required in immunosuppressed recipients, compared with non-immunosuppressed recipients made tolerant pretransplant by induction of mixed hematopoietic chimerism (100 islets). The failure of immunosuppressed mice to become normoglycemic after low-dose islet transplantation primarily resulted from the inhibitory effects of tacrolimus combined with sirolimus on islet engraftment and not from the inhibitory effects of this combination on islet graft function. These data suggest that immunotherapeutic strategies that control adaptive immunity without interfering with islet neovascularization or other processes critical to islet engraftment are likely to improve the success rate of marginal mass human islet allografts.
The insulin dependent type 1 diabetes mellitus (IDDM) and the metabolic syndrome are complex human diseases. Both diseases are heterogeneous, genetically inherited and do not follow a simple Mendelian single-locus pattern. The analysis of complex human diseases is complicated both by genetic heterogeneity and by environmental factors. One way to overcome the problem of genetic heterogeneity in humans may be to cluster patients by kinship. It was shown by analysis of maternal lines of type 1 diabetics using mitochondrial DNA that 89% of maternal lines are related to each other. Moreover, an alternative to the genetic differential analysis of complex mammalian diseases is the use of animal models. The availability of inbred animal models closely resembling the human disease is an essential component of genetic investigations in this field, as shown in the results of this work. These findings do not only underscore the utility of the congenic and subcongenic approach in differentially analyzing complex traits, but also show that candidate genes can be identified and that chromosomal exchange can variously influence the phenotype, leading to sub-phenotypes which may be representative for human beings. Furthermore, it will also be possible to locate the syntenic region in the human genome and congenic and subcongenic strains can also be used to study interactions between chromosomal regions and various selected environmental conditions. In this way, it may be possible to learn which region can be influenced by environmental factors and to which extent, an undertaking which will require prospective projects.
In the two present prospective cohort studies we conducted on population-based sample from the North-eastern adult Germans, the following main results were obtained. First, CP had a moderate effect on CVD and all-cause mortality [93]. In further analyses, we investigated the association of CP and mortality considering DM as a mediator in the CP-Mortality association. We did not, however, come up with enough evidence supporting this hypothesis. Furthermore, no substantial evidence was found on our hypothesis suggesting a joint effect of CP and DM on mortality [93]. Second, we studied the causal effect of CP on diabetes incidence or long-term change of Hba1c level using 11-years of follow-up data from SHIP. However, our data did not indicate any independent effect of CP on the incidence of diabetes mellitus after comprehensive confounder adjustment using DAGs. Models that consider baseline periodontal status effect on long term change of Hba1c revealed similar non-significant results [94].
Obesity and diabetes have reached epidemic proportions and have emerged as massive public health problems globally. The etiology of both obesity and diabetes are related, multifactorial, highly complex, and involves interplay of genetic, environmental, socio-economic and physiological factors, which calls for a more extensive research in understanding the risk factors and biological pathways. Hence, this dissertation contributed in part to understanding the role of iron markers in the development of type 2 diabetes mellitus and the role of intrauterine hyperglycemia in influencing the risk of offspring obesity along with investigating potential pathways.
In the first part of my dissertation, the associations of iron markers (ferritin and transferrin) with type 2 diabetes mellitus and metabolic syndrome were investigated using the population-based Study of Health in Pomerania. The present analyses were based on 3,232 participants aged 20-81 years with a follow-up time of nearly 11 years. The results suggest that serum ferritin concentrations were associated with a higher prevalence of type 2 diabetes mellitus and metabolic syndrome in the total population as well as in men. However, the effects of serum ferritin on incident type 2 diabetes mellitus were observed only in women, while the effects on incident metabolic syndrome were seen in the total population. Serum ferritin is also known to reflect systemic inflammation or hepatic dysfunction in addition to increased iron stores. Hence, upon further analyses, the associations were found to be attenuated after adjustment for hepatic enzymes but not after adjustment for inflammation. Transferrin was not associated with any of the outcomes. Thus, our study provides evidence for a link between the iron marker ferritin and type 2 diabetes mellitus and metabolic syndrome, although the association seemed to vary by sex. Moreover, hepatic dysfunction seems likely to be in the pathway between ferritin and type 2 diabetes mellitus and metabolic syndrome.
In the second part of my dissertation, the association between maternal hyperglycemia and the risk of offspring overweight and obesity were investigated using three different cohorts: TEDDY, TEENDIAB and BABYDIAB/BABYDIET. The present analyses were based on a total of 8,103 children who were followed until 6 years of age in TEDDY study and until 18 years of age in TEENDIAB and BABYDIAB/BABYDIET studies. The dissertation revealed that maternal hyperglycemia in general may be associated with increased risk for childhood overweight and obesity, and that the association gets stronger as children grow older, with the risk being clearly evident at late childhood and adolescence. Moreover, this dissertation adds that this association can be driven by different pathways based on the type of maternal diabetes to which the offspring was exposed. The association of maternal gestational diabetes mellitus with offspring overweight can be largely explained by the confounding influence of maternal BMI, whereas the association of maternal type 1 diabetes mellitus with offspring overweight can be substantially explained by birthweight in all three studies. In our attempt to understand biological pathways at a cellular level, we found that the offspring metabolome was unlikely to be in the causal pathway between maternal type 1 diabetes mellitus and overweight, because this association could not be explained by any of the potentially relevant metabolites.
To conclude, this dissertation acknowledges the fact that prevention and early intervention of obesity and diabetes is of paramount importance to lessen the impact of these public health problems. Thus, our findings of the role of ferritin in increasing the risk of type 2 diabetes mellitus/ metabolic syndrome and the role of intrauterine hyperglycemia in increasing the risk of offspring overweight helped to identify particular risk groups who may need closer attention with respect to prevention of obesity and diabetes.
Introduction: Patients who are overweight or obese have an increased risk of developing type 2 diabetes mellitus (T2DM). Weight loss can have a positive effect on glycemic control. Objective: We aimed to investigate glycemic control in patients with T2DM and overweight or obesity during a structured weight-loss program. Methods: This was a prospective, interventional study. We recruited 36 patients (14 men and 22 women) with a median age of 58.5 years and median body mass index (BMI) of 34.1, to a 15-week structured weight-loss program with a low-calorie (800 kcal) formula diet for 6 weeks. The primary end point, HbA<sub>1c</sub> level, and secondary end points, anthropometric data, medication, and safety, were assessed weekly. Laboratory values and quality of life were assessed at baseline and after 15 weeks. Results: HbA<sub>1c</sub> decreased from 7.3% at baseline to 6.5% at 15 weeks (p < 0.001), median body weight by 11.9 kg (p < 0.001), median BMI by 4.3 (p < 0.001) and median waist circumference by 11.0 cm (p < 0.001). Two participants discontinued insulin therapy, 4 could reduce their dosage of oral antidiabetic agents, and 6 completely discontinued their antidiabetic medication. Insulin dose decreased from 0.63 (0.38–0.89) to 0.39 (0.15–0.70) units/kg body weight (p < 0.001). No patient experienced hypoglycemic episodes or hospital emergency visits. Triglycerides and total cholesterol decreased as well as surrogate markers of liver function. However, the levels of high-density and low-density lipoprotein cholesterol (HDL-C and LDL-C) as well as uric acid remain unchanged. Regarding quality of life, the median physical health score increased from 44.5 (39.7–51.4) at baseline to 48.0 (43.1–55.3; p = 0.007), and the median mental health score decreased from 42.1 (36.1–46.7) to 37.4 (30.3–43.7; p = 0.004). Conclusions: A structured weight-loss program is effective in the short term in reducing HbA<sub>1c</sub>, weight, and antidiabetic medication in patients with T2DM who are overweight or obese. Levels of HDL-C and LDL-C were not affected by short-term weight loss. The decline in mental health and the long-term effects of improved glycemic control require further trials.
The development of the two main types of diabetes mellitus, type 1 and type 2 (T1D, T2D), is closely associated with the formation of reactive oxygen species (ROS) and reactive nitrogen species (RNS) in insulin-secreting pancreatic β-cells. In T1D, β-cell death
is triggered by proinflammatory cytokines, which mainly lead to the formation of ROS
in mitochondria and RNS in the cytosol. Pancreatic β-cells are extraordinarily sensitive
to oxidative stress due to their low glutathione peroxidase and catalase expression.
Thus, hydrogen peroxide (H2O2) cannot be detoxified, neither sufficiently, nor rapidly.
H2O2 itself is a rather weakly reactive ROS but can react in the Fenton reaction to form
highly reactive hydroxyl radicals (●OH), that can damage cells in a variety of ways and
induce cell death. The cell and its organelles are bounded by biological membranes
that differ in their permeability to H2O2. Aquaporins (AQPs) are water-transporting
transmembrane proteins, and some isoforms have been shown to facilitate a bidirectional transport of H2O2 across cellular membranes in addition to water. The role of
AQP8 was investigated in an insulin-producing cell model by stably overexpressing
AQP8 (AQP8↑) and by a CRISPR/Cas9-mediated AQP8 knockout. However, AQP8
proved to be an essential protein for the viability of the insulin-producing RINm5F cells, and so we established a tet-on-regulated AQP8 knockdown (AQP8 KD). Our results highlight that AQP8 is involved in H2O2 transport across the plasma and mitochondrial membranes, and that AQP8 expression gets upregulated by proinflammatory cytokines (in vitro) and in an acutely diabetic rat model (in vivo). Furthermore, it was shown that the increased proinflammatory cytokine toxicity is due to enhanced mitochondrial oxidative stress, because H2O2 cannot be efficiently transported in AQP8 KD cells and ●OH
are increasingly generated. Caspase activity then raises, and apoptosis is increasingly
induced coupled with a proportion of ferroptosis-mediated cell death because of a concomitant decrease in nitric oxide (NO●) concentration. In conclusion, AQP8 is localized in the plasma and mitochondrial membrane of insulin-producing RINm5F cells, where it is involved in H2O2 transport. In T1D, AQP8 plays an important role in the transport of H2O2 from the mitochondrial matrix to the cytosol so that the concentration is lowered in the mitochondria. This wider distribution of H2O2 may ease the inactivation of H2O2.