Inherited Variation in Vitamin D Genes and Type 1 Diabetes Predisposition
Genes 2017, 8(4), 125; doi:10.3390/genes8040125 (registering DOI)
- Vitamin D tests do not detect poor Vitamin D Receptor and 4 other classes of vitamin D genes.
- Thus, you can have a good blood level of vitamin D but get T1 Diabetes and many other health problems because genes limit the amount of vitamin D getting to the cells
- Health problems that run in families are often associated with low vitamin D - and genes decreasing Vitamin D getting to cells
- Type 1 Diabetes prevention with Vitamin D and Omega-3 – Symposium April 2019
Pages listed in BOTH of the categories Diabetes and Vitamin D Receptor
- T2 Diabetes might be fought by Vitamin D plus Vitamin D Receptor activators – April 2023
- Diabetes 3X more likely if had COVID ICU (VDR was deactivated) - April 2023
- T2 diabetes complications increased 35-52 percent if low vitamin D – Sept 2022
- T2 Diabetes 30 percent more likely if poor Vitamin D Receptor – meta-analysis of 47 studies – July 2021
- Gestational Diabetes – increased risk if poor Vitamin D Receptor – 2 Meta-Analyses 2021
- Type 1 Diabetes (Autoimmune) and Vitamin D, Vitamin D Receptor and Cathelicidin - Dec 2020
- Diabetes decreased by activating Vitamin D Receptor (transgenic mice) – Feb 2020
- Gestational Diabetes 2.4X more likely if poor Vitamin D Receptor (region in China) – June 2019
- Gestational Diabetes 3 X more likely if poor Vitamin D receptor (Turkey) – May 2019
- Resveratrol prevented bone loss associated with T2DM (probably via VDR) – RCT Sept 2018
- Diabetic nephropathy deactivates the Vitamin D Receptor, reducing tissue Vit D – Feb 2019
- Resveratrol improves health (Vitamin D receptor, etc.) - many studies
- Inflammation and immune responses to Vitamin D (perhaps need to measure active vitamin D) – July 2017
- Type 1 Diabetes 14 percent more likely with 2 Vitamin D Receptor mutations – Oct 2017
- Gestational Diabetes Mellitus associated with 4 Vitamin D genes – Oct 2015
- Diabetic nephropathy (Kidney problem) 1.8 X more likely if poor Vitamin D Receptor – meta-analysis July 2017
- Type 1 Diabetes association with poor Vitamin D Receptor: 39 studies – April 2017
- Type 1 diabetes 1.6 times more likely if a Vitamin D Receptor problem – Feb 2017
- Diabetic Retinopathy 2 X more likely if poor Vitamin D Receptor – meta-analysis Nov 2016
- Diabetic foot ulcer 1.7 times more likely if poor Vitamin D Receptor – Jan 2017
- Vitamin D activates the hypothalamus (in rodents) to reduce weight and diabetes– May 2016
- Diabetes (T2) 16 percent more likely if Vitamin D receptor problem – Oct 2015
- Type 1 diabetes associated with faulty Vitamin D receptor genes – May 2013
- Vitamin D receptor gene associated with 50 percent more type 2 Diabetes – meta-analyses 2013, 2016
Vitamin D Receptor category has the following
Vitamin D tests cannot detect Vitamin D Receptor (VDR) problems
A poor VDR restricts Vitamin D from getting in the cells
It appears that 30% of the population have a poor VDR (40% of the Obese )
Several diseases protect themselves by deactivating the Vitamin D receptor. Example: Breast Cancer
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The Vitamin D Receptor is associated with many health problems
Some health problems, such as Breast Cancer, Diabetes, and COVID protect themselves by reducing VDR activation
55 health problems associated with poor VDR
A poor VDR is associated with the risk of 55 health problems click here for details
The risk of 48 diseases at least double with poor VDR as of Jan 2023 click here for details
Some health problem, such as Breast Cancer reduce the VDR
VDR at-home test $29 - results not easily understood in 2016
There are hints that you may have inherited a poor VDR
How to increase VDR activation
Compensate for poor VDR by increasing one or more:
| Increasing | Increases |
| 1) Vitamin D supplement Sun Ultraviolet -B | Vitamin D in the blood and thus in the cells |
| 2) Magnesium | Vitamin D in the blood AND in the cells |
| 3) Omega-3 | Vitamin D in the cells |
| 4) Resveratrol | Vitamin D Receptor |
| 5) Intense exercise | Vitamin D Receptor |
| 6) Get prescription for VDR activator paricalcitol, maxacalcitol? | Vitamin D Receptor |
| 7) Quercetin (flavonoid) | Vitamin D Receptor |
| 8) Zinc is in the VDR | Vitamin D Receptor |
| 9) Boron | Vitamin D Receptor ?, etc |
| 10) Essential oils e.g. ginger, curcumin | Vitamin D Receptor |
| 11) Progesterone | Vitamin D Receptor |
| 12) Infrequent high concentration Vitamin D Increases the concentration gradient | Vitamin D Receptor |
| 13) Sulfroaphane and perhaps sulfur | Vitamin D Receptor |
| 14) Butyrate especially gut | Vitamin D Receptor |
| 15) Berberine | Vitamin D Receptor |
Note: If you are not feeling enough benefit from Vitamin D, you might try increasing VDR activation. You might feel the benefit within days of adding one or more of the above
Far healthier and stronger at age 72 due to supplements Includes 6 supplements that help the VDR
Increased risk of diseases if poor VDR
Increased risk associated with a poor Vitamin D Receptor
Note: Some diseases reduce VDR activation
those with a * are known to decrease activation
Download the PDF from VitaminDWiki
Marissa Penna-Martinez and Klaus Badenhoop
Division of Endocrinology, Diabetes and Metabolism, Department of Medicine 1, University Hospital Frankfurt, Theodor-Stern-Kai 7, D-60590 Frankfurt am Main, Germany
(This article belongs to the Special Issue Genetics and Functional Genomics of Diabetes Mellitus)
The etiology and pathophysiology of type 1 diabetes remain largely elusive with no established concepts for a causal therapy. Efforts to clarify genetic susceptibility and screening for environmental factors have identified the vitamin D system as a contributory pathway that is potentially correctable. This review aims at compiling all genetic studies addressing the vitamin D system in type 1 diabetes. Herein, association studies with case control cohorts are presented as well as family investigations with transmission tests, meta-analyses and intervention trials. Additionally, rare examples of inborn errors of vitamin D metabolism manifesting with type 1 diabetes and their immune status are discussed.
We find a majority of association studies confirming a predisposing role for vitamin D receptor (VDR) polymorphisms and those of the vitamin D metabolism, particularly the CYP27B1 gene encoding the main enzyme for vitamin D activation. Associations, however, are tenuous in relation to the ethnic background of the studied populations. Intervention trials identify the specific requirements of adequate vitamin D doses to achieve vitamin D sufficiency. Preliminary evidence suggests that doses may need to be individualized in order to achieve target effects due to pharmacogenomic variation.
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