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Lighting your way to treat blood sugar disease: Blue light-based therapy for diabetes (TIIDM): Intense blue light increases GLP1R and Caveolin-1 (CAV-1) expression, promotes glucose-induced insulin secretion, improves insulin sensitivity, increases energy utilization, promotes weight loss and protects from diet-induced obesity and TIIDM, via up regulation of its target gene, 29/April/2018, 7.29 am

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Introduction: What they say

A study from the Comprehensive Diabetes Center and Department of Medicine, Division of Endocrinology, Diabetes, and Metabolism, University of Alabama at Birmingham, Birmingham, AL shows that “miR-204 Controls Glucagon-Like Peptide 1 Receptor Expression and Agonist Function.” This research paper was published, in the 3 November 2017 issue of the journal “Diabetes” [One of the best research journals in diabetic research with an I.F of 10 plus], by Prof. Shalev A, Jo S and others.


What we say:

On the foundation of this interesting finding, Dr L Boominathan PhD, Director-cum-chief Scientist of GBMD, reports that: Lighting your way to treat blood sugar disease: Blue light-based therapy for diabetes (TIIDM): Intense blue light increases GLP1R and Caveolin-1 (CAV-1) expression, promotes glucose-induced insulin secretion, improves insulin sensitivity, increases energy utilization, promotes weight loss and protects from diet-induced obesity and TIIDM, via up regulation of its target gene

 


From significance of the study to public health relevance:

Given that: (1) more than 422 million people worldwide are affected by Diabetes mellitus (DM); (2) Diabetes is going to be one of the top 10 causes of death by 2030; (3) the life-long painful injection/drug treatment is required to treat DM; (4) the global economic cost spent for diabetes treatment in 2014 was little more than 600 billion US dollars, there is an urgent need to find: (i) a way to induce regeneration of adult ß-cells that were lost in DM; (ii) a cheaper alternative to the existing expensive weight-loss drugs; (iii) a side-effect-free natural product-based drug; and (iv) a way to cure, not just treat, diabetes.


What is known?

Prof. Shalev A’s research team has recently shown that:(1) MiRNA-204, the highly expressed miRNA in ß-cells, inhibits GLP1R expression; (2) deletion of miR-204: (a) increases cAMP production; (b) increases insulin secretion; (c) augments response to GLP1R activators or agonists; and (d) protects against diabetes; (3) deletion of thioredoxin-interacting protein, the upstream regulator of miR-204, (a) increases GLP1R expression; (b) ameliorates glucose intolerance; (c) improves cAMP production; (d) increases insulin secretion; and (e) protects against diabetes, suggesting that decreasing the expression of MiR-204 or its upstream regulator thioredoxin-interacting protein may promote insulin sensitivity, and alleviate TIIDM.


From Research findings to Therapeutic opportunity:

This study suggests, for the first time, an intense-blue light based therapy for Weight loss and TIIDM.

This study suggests, for the first time, that  Intense blue light, by increasing the expression of its target gene, it may increase the expression of GLP1R and Caveolin-1 (CAV-1). Thereby, it may: (1) increase pancreatic beta-cell proliferation; (2) increase expression of genes that promote insulin sensitivity and insulin secretion; (3) promote weight loss; (4) augment energy expenditure; (5) decrease metabolic stress; and (6) promote energy homeostasis (Fig.1). Thus,  intense blue light  may be used to treat TIIDM (Figure 2).


Figure 1. Mechanistic insights into how intense blue light functions as an antidiabetic agent. Intense blue light, by up regulating its target genes, it may: a) increase cAMP levels; b) increase insulin sensitivity; c) increase increase secretion; and d) attenuate hyperglycemia.

Figure 2. Intense blue light functions as an anti-diabetic agent. Intense blue light increases CAV1 and GLP-IR expression through up regulation of its target gene

Details of the research findings:

Idea Proposed/Formulated (with experimental evidence) by: Dr L Boominathan Ph.D.

Terms & Conditions apply http://genomediscovery.org/registration/terms-and-conditions/

Undisclosed information: How does intense blue light increase the expression of GLP1R and CAV-1?

Amount: $500#

# Research cooperation

For purchase and payment details, you may reach us at info@genomediscovery.org

* Research cooperation


References:

Web: http://genomediscovery.org  or http://newbioideas.com

Citation: Boominathan, L., Lighting your way to treat blood sugar disease: Blue light-based therapy for diabetes (TIIDM): Intense blue light increases GLP1R and Caveolin-1 (CAV-1) expression, promotes glucose-induced insulin secretion, improves insulin sensitivity, increases energy utilization, promotes weight loss and protects from diet-induced obesity and TIIDM, via up regulation of its target gene, 29/April/2018, 7.29 am, Genome-2-Bio-Medicine Discovery center (GBMD), http://genomediscovery.org

Courtesy: When you cite, drop us a line at info@genomediscovery.org

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