There is a growing interest in cell-based therapies in T2DM as β-cell failure is progressive and inexorable with the advancing duration of disease. This prospective, randomized, single-blinded placebo-controlled study evaluates the efficacy and safety of autologous bone marrow-derived stem cell transplantation (ABMSCT) in T2DM. Twenty-one patients with triple oral antidiabetic drug failure and requiring insulin ≥0.4 IU per kg per day with HbA1c <7.5% were randomly assigned to an intervention (n = 11) and control group (n = 10) and followed for 12 months. Patients in the intervention group received ABMSCT through a targeted approach, and after 12 weeks, a second dose of stem cells was administered through the antecubital vein after mobilization with G-CSF, while the control group underwent a sham procedure. The primary end point was a reduction in insulin requirement by ≥50% from baseline while maintaining HbA1c <7%. Nine out of the 11 (82%) patients in the intervention group achieved the primary end point, whereas none of the patients in the control group did over the study period (p = 0.002). The insulin requirement decreased by 66.7% in the intervention group from 42.0 (31.0‐64.0) IU per day to 14.0 (0.0‐30.0) IU per day (p = 0.011), while in controls it decreased by 32.1% from 40.5 (31.8‐44.3) IU per day to 27.5 (23.5‐33.3) IU per day (p = 0.008) at 12 months. The reduction in insulin requirement was significantly more in the intervention group compared to controls at both 6 (p = 0.001) and 12 months (p = 0.004). There was a modest but nonsignificant increase in HbA1c (%) in cases from 6.9% (6.4‐7.2%) to 7.1% (6.6‐7.5%) as well as in controls from 6.9% (6.2‐7.0%) to 7.0% (6.9‐7.5%). Ten out of 11 (91%) patients could maintain HbA1c <7% in the intervention group, whereas 6 out of 10 did (60%) in the control group (p = 0.167). The glucagon-stimulated C-peptide significantly increased in treated cases compared to controls (p = 0.036). The decrease in insulin requirement positively correlated with stimulated C-peptide (r = 0.8, p = 0.001). In conclusion, ABMSCT results in a significant decrease in the insulin dose requirement along with an improvement in the stimulated C-peptide levels in T2DM. However, a greater number of patients with a longer duration of follow-up are required to substantiate these observations.
Cellular processes do not follow deterministic rules; even in identical environments genetically identical cells can make random choices leading to different phenotypes. This randomness originates from fluctuations present in the biomolecular interaction networks. Most previous work has been focused on the intrinsic noise (IN) of these networks. Yet, especially for high-copy-number biomolecules, extrinsic or environmental noise (EN) has been experimentally shown to dominate the variation. Here, we develop an analytical formalism that allows for calculation of the effect of EN on gene-expression motifs. We introduce a method for modeling bounded EN as an auxiliary species in the master equation. The method is fully generic and is not limited to systems with small EN magnitudes. We focus our study on motifs that can be viewed as the building blocks of genetic switches: a nonregulated gene, a self-inhibiting gene, and a self-promoting gene. The role of the EN properties (magnitude, correlation time, and distribution) on the statistics of interest are systematically investigated, and the effect of fluctuations in different reaction rates is compared. Due to its analytical nature, our formalism can be used to quantify the effect of EN on the dynamics of biochemical networks and can also be used to improve the interpretation of data from single-cell gene-expression experiments.
The invasion cascade exhibited by placental trophoblasts and cancerous cells bears many similarities, and it is attributed to extracellular matrix degradation mediated by matrix metalloproteinases (MMPs). Although proper and controlled invasion by trophoblasts into the maternal uterus is an essential requirement for maintenance of normal pregnancy, any abnormality in this phenomenon results in the development of invasion-related disorders such as gestational trophoblastic diseases (GTDs) and preeclampsia. We studied the epigenetic basis of differential expression of two placental MMPs (MMP2 and MMP9) and tissue inhibitors of metalloproteinases (TIMP2 and TIMP1) during normal gestation and invasion-related disorders, i.e., preeclampsia and GTDs. Our study suggests the association of H3K9/27me3 with differential expression of these MMPs and their inhibitors, which regulate the placental invasion during normal pregnancy, whereas no role of CpG methylation was observed in the differential expression of MMPs/TIMPs. Further, development of GTDs was associated with abnormally higher expression of these MMPs and lower levels of their inhibitors, whereas the reverse trends were observed for MMPs and their TIMPs in case of preeclampsia, in association with abnormal changes in H3K9/27me3. These results suggest the involvement of higher levels of MMPs in an aggressive invasive behavior depicted by GTDs, whereas lower levels of these MMPs in shallow and poor invasive phenotype associated with preeclampsia. Thus, our study shows the significance of a proper balance regulated by histone trimethylation between differential expression of MMPs and their TIMPs for maintaining normal pregnancy and its deregulation as a contributing factor for pathogenesis of invasive disorders during pregnancy.
Background There is limited data on the community prevalence of non‐alcoholic fatty liver disease (NAFLD). The present study evaluated the prevalence of NAFLD in a large number of healthy male blood donors of urban north India. Methodology In a prospective study performed over 18 months, voluntary blood donors fulfilling the requisite blood donation criteria and consenting to participate in the study were evaluated. The study received the approval of the institute's ethics committee. Diagnosis of NAFLD was made by excluding significant alcohol intake, ultrasound showing hepatic steatosis, and exclusion of transfusion associated infections. Subjects were also evaluated for various metabolic risk factors and the presence of metabolic syndrome. Results Of 1388 subjects who consented for participation, 386 did not come for evaluation. Three females, nine (0.9%) HBsAg‐positive, and four (0.4%) anti‐HCV positive subjects were excluded. Of the 986 males evaluated with hepatobiliary ultrasound, 543(55.1%) had fatty liver on ultrasonography [15 (1.5%) alcoholic fatty liver and 528 (53.5%) NAFLD]. Among those with NAFLD, 469 (88.8%), 54 (10.2%), and 5 (0.9%) had mild, moderate, and severe hepatic steatosis, respectively. Subjects with NAFLD, when compared to those without NAFLD, had significantly higher age, BMI, waist circumference, blood pressure, total cholesterol and triglycerides, low‐density lipoprotein, and fasting plasma glucose. Multivariate regression analysis demonstrated age, BMI, waist circumference, systolic blood pressure, total cholesterol, and number of metabolic syndrome criteria as independent predictors of NAFLD. Conclusions Urban Indian healthy male blood donors have a high prevalence of NAFLD.
The rheological properties of polymer melts and other complex macromolecular fluids are often successfully modeled by phenomenological constitutive equations containing fractional differential operators. We suggest a molecular basis for such fractional equations in terms of the generalized Langevin equation (GLE) that underlies the renormalized Rouse model developed by Schweizer [J. Chem. Phys. 91, 5802 (1989)]. The GLE describes the dynamics of the segments of a tagged chain under the action of random forces originating in the fast fluctuations of the surrounding polymer matrix. By representing these random forces as fractional Gaussian noise, and transforming the GLE into an equivalent diffusion equation for the density of the tagged chain segments, we obtain an analytical expression for the dynamic shear relaxation modulus G(t) , which we then show decays as a power law in time. This power-law relaxation is the root of fractional viscoelastic behavior.
Tissue inhibitor of metalloproteinases-1 (TIMP-1) is important in maintaining the extracellular proteolytic balance during tissue remodeling processes. To allow homeostatic tissue turnover, the murine Timp-1 gene is expressed by most cells at a low basal level, and during acute remodeling its transcription is activated by a variety of stimuli. A non-consensus AP-1-binding site (5-TGAGTAA-3) that is conserved in mammalian timp-1 genes is a critical element in basal and serum-stimulated transcription. We show here that each strand of this unusual AP-1 site binds a distinct single-stranded DNA-binding protein, although neither strand from a perfect consensus AP-1 site from the human collagenase gene shows similar binding. One of the single-strand binding factors, which we term ssT1, binds to a second upstream Timp-1 region between nucleotides ؊115 and ؊100. Deletion analysis demonstrated that this region is important in basal but not serum-inducible transcription. The ssT1 factor was 52-54 kDa by UV cross-linking of electrophoretic mobility shift assays and Southwestern blot analysis. Its binding to DNA shows sequence selectivity rather than specificity, with 5-CT/ATTN (4 -6)ATC-3 as a favored motif. Multiple ssT1-like activities were found in nuclear extracts from mouse fibroblasts and rat liver and testis, suggesting that these factors may regulate basal Timp-1 transcription in a tissue-specific fashion.Extracellular matrix turnover is highly regulated at multiple levels, a critical one being the balance between the levels of matrix metalloproteinases (MMPs) 1 and their specific inhibitors, the TIMPs (tissue inhibitors of metalloproteinases (1, 2)).
The Na+pump, Na+-K+-ATPase, along with the Na+ channel is essential for the removal of alveolar solute and fluid perinatally. Because Na+-pump mRNA and activity increase before birth and maternal glucocorticoids (GCs) influence Na+-K+-ATPase mRNA expression in fetal rat lung, we hypothesized that GCs increased Na+-K+-ATPase gene expression in a fetal lung epithelial cell line. After 24 h of exposure, dexamethasone increased the steady-state levels of Na+-K+-ATPase α1 and β1 mRNA in a fetal rat lung epithelial cell line in a dose-dependent fashion (10−7 to 10−5 M). The maximal increase in mRNA levels was 3.8-fold for α1 and 2.8-fold for β1. The increase in mRNA was detected as early as 6 h for the β1-subunit and 18 h for the α1-subunit, and both peaked at 24 h. This gene upregulation was not due to increased mRNA stability based on mRNA half-life determination after actinomycin D inhibition. Transfection experiments with α1and β1 promoter-reporter constructs demonstrated 3.2 ± 0.5- and 2.6 ± 0.4-fold increases, respectively, in promoter activity, consistent with transcriptional activation of the promoter-reporter construct. These findings, increased promoter activity with no change in stability, indicate that GCs increased Na+-K+-ATPase transcription in a fetal lung epithelial cell line.
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