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The nuclear erythroid 2-related factor 2 signaling pathway, best known as Nrf2, is a protective mechanism which functions as a “master regulator” of the human body’s antioxidant response. Nrf2 senses the levels of oxidative stress within the cells and triggers protective antioxidant mechanisms. While Nrf2 activation can have many benefits, Nrf2 “overexpression” can have several risks. It appears that a balanced degree of NRF2 is essential towards preventing the overall development of a variety of diseases in addition to the general improvement of these health issues. However, NRF2 can also cause complications. The main cause behind NRF2 “overexpression” is due to a genetic mutation or a continuing chronic exposure to a chemical or oxidative stress, among others. Below, we will discuss the downsides of Nrf2 overexpression and demonstrate its mechanisms of action within the human body.
Research studies found that mice that don’t express NRF2 are more inclined to develop cancer in response to physical and chemical stimulation. Similar research studies, however, showed that NRF2 over-activation, or even KEAP1 inactivation, can result in the exacerbation of certain cancers, particularly if those pathways have been interrupted. Overactive NRF2 can occur through smoking, where continuous NRF2 activation is believed to be the cause of lung cancer in smokers. Nrf2 overexpression might cause cancerous cells not to self-destruct, while intermittent NRF2 activation can prevent cancerous cells from triggering toxin induction. Additionally, because NRF2 overexpression increases the human body’s antioxidant ability to function beyond redox homeostasis, this boosts cell division and generates an unnatural pattern of DNA and histone methylation. This can ultimately make chemotherapy and radiotherapy less effective against cancer. Therefore, limiting NRF2 activation with substances like DIM, Luteolin, Zi Cao, or salinomycin could be ideal for patients with cancer although Nrf2 overactivation should not be considered to be the only cause for cancer. Nutrient deficiencies can affect genes, including NRF2. This might be one way as to how deficiencies contribute to tumors.
The overactivation of Nrf2, can also affect the function of specific organs in the human body. NRF2 overexpression can ultimately block the production of the insulin-like growth factor 1, or IGF-1, from the liver, which is essential for the regeneration of the liver.
While the acute overexpression of Nrf2 may have its benefits, continuous overexpression of NRF2 may cause long-term harmful effects on the heart, such as cardiomyopathy. NRF2 expression can be increased through high levels of cholesterol, or the activation of HO-1. This is believed to be the reason why chronic elevated levels of cholesterol might cause cardiovascular health issues.
NRF2 overexpression has also been demonstrated to inhibit the capability to repigment in vitiligo as it might obstruct Tyrosinase, or TYR, action which is essential for repigmentation through melaninogenesis. Research studies have demonstrated that this process may be one of the primary reasons as to why people with vitiligo don’t seem to activate Nrf2 as efficiently as people without vitiligo.
Why NRF2 May Not Function Properly
NRF2 has to be hormetically activated in order to be able to take advantage of its benefits. In other words, Nrf2 shouldn’t trigger every minute or every day, therefore, it’s a great idea to take breaks from it, by way of instance, 5 days on 5 days off or every other day. NRF2 must also accomplish a specific threshold to trigger its hormetic response, where a small stressor may not be enough to trigger it.
Protein deglycase DJ-1, or just DJ-1, also called the Parkinson’s disease protein, or PARK7, is a master regulator and detector of the redox status in the human body. DJ-1 is essential towards regulating how long NRF2 can perform its function and produce an antioxidant response. In the case that DJ-1 becomes overoxidized, the cells will make the DJ-1 protein less accessible. This process induces NRF2 activation to expire too fast since DJ-1 is paramount for maintaining balanced levels of NRF2 and preventing them from being broken down in the cell. In case the DJ-1 protein is non-existent or overoxidized, NRF2 expression will probably be minimal, even using DIM or alternative NRF2 activators. DJ-1 expression is imperative to restore impaired NRF2 action.
If you have a chronic illness, including CIRS, chronic infections/dysbiosis/SIBO, or heavy metal build up, such as mercury and/or that from root canals, these can obstruct the systems of NRF2 and phase two detoxification. Rather than oxidative stress turning NRF2 into an antioxidant, NRF2 will not trigger and oxidative stress can remain in the cell and cause damage, meaning, there is no antioxidant response. This is a significant reason why many people with CIRS have several sensitivities and reach to numerous factors. Some people believe they may be having a herx response, however, this reaction may only be damaging the cells farther. Treating chronic illness, however, will permit the liver to discharge toxins into the bile, gradually developing the hormetic response of NRF2 activation. If the bile remains toxic and it’s not excreted from the human body, it will reactivate NRF2’s oxidative stress and cause you to feel worse once it’s reabsorbed from the gastrointestinal, or GI, tract. For example, ochratoxin A may block NRF2. Aside from treating the problem, histone deacetylase inhibitors can block the oxidative reaction from a number of the factors which trigger NRF2 activation but it might also prevent NRF2 from triggerring normally, which might ultimately fail to serve its purpose.
Fish Oil Dysregulation
Cholinergics are substances which boost acetylcholine, or ACh, and choline in the brain through the increase of ACh, particularly when inhibiting the breakdown of ACh. Patients with CIRS often have problems with the dysregulation of acetylcholine levels in the human body, especially in the brain. Fish oil triggers NRF2, activating its protective antioxidant mechanism within the cells. People with chronic illnesses might have problems with cognitive stress and acetylcholine excitotoxicity, from organophosphate accumulation, which might cause fish oil to create inflammation within the human body. Choline deficiency additionally induces NRF2 activation. Including choline into your diet, (polyphenols, eggs, etc.) can help enhance the effects of cholinergic dysregulation.
What Decreases NRF2?
Decreasing NRF2 overexpression is best for people that have cancer, although it may be beneficial for a variety of other health issues.
Diet, Supplements, and Common Medicines:
Apigenin (higher doses)
EGCG (high doses increase NRF2)
Hiba (Hinokitiol / β-thujaplicin)
High Salt Diet
Luteolin (Celery, green pepper, parsley, perilla leaf, and chamomile tea – higher doses may increase NRF2 – 40 mg/kg luteolin three times per week )
Metformin (chronic intake)
N-Acetyl-L-Cysteine (NAC, by blocking the oxidative response, esp at high doses)
Orange Peel (have polymethoxylated flavonoids)
Quercetin (higher doses may increase NRF2 – 50 mg/kg/d quercetin)
Retinol (all-trans retinoic acid)
Vitamin C when combined with Quercetin
Zi Cao (Purple Gromwel has Shikonin/Alkannin)
Pathways and Other:
Glucocorticoid Receptor signaling (Dexamethasone and Betamethasone as well)
GSK-3β (regulatory feedback)
Homocysteine (ALCAR can reverse this homocysteine induce low levels of NRF2)
Ochratoxin A(aspergillus and pencicllium species)
Promyelocytic leukemia protein
Retinoic acid receptor alpha
STAT3 inhibition (such as Cryptotanshinone)
Testosterone (and Testosterone propionate, although TP intranasally may increase NRF2)
Trx1 (via reduction of Cys151 in Keap1 or of Cys506 in the NLS region of Nrf2)
Zinc Deficiency (makes it worse in the brain)
Nrf2 Mechanism Of Action
Oxidative stress triggers through CUL3 where NRF2 from KEAP1, a negative inhibitor, subsequently enters the nucleus of these cells, stimulating the transcription of the AREs, turning sulfides into disulfides, and turning them into more antioxidant genes, leading to the upregulation of antioxidants, such as GSH, GPX, GST, SOD, etc.. The rest of these can be seen in the list below:
Increases Notch 1
Encoded from the NFE2L2 gene, NRF2, or nuclear erythroid 2-related factor 2, is a transcription factor in the basic leucine zipper, or bZIP, superfamily which utilizes a Cap’n’Collar, or CNC structure.
It promotes nitric enzymes, biotransformation enzymes, and xenobiotic efflux transporters.
It is an essential regulator at the induction of the phase II antioxidant and detoxification enzyme genes, which protect cells from damage caused by oxidative stress and electrophilic attacks.
During homeostatic conditions, Nrf2 is sequestered in the cytosol through bodily attachment of the N-terminal domain of Nrf2, or the Kelch-like ECH-associated protein or Keap1, also referred to as INrf2 or Inhibitor of Nrf2, inhibiting Nrf2 activation.
It may also be controlled by mammalian selenoprotein thioredoxin reductase 1, or TrxR1, which functions as a negative regulator.
Upon vulnerability to electrophilic stressors, Nrf2 dissociates from Keap1, translocating into the nucleus, where it then heterodimerizes with a range of transcriptional regulatory protein.
Frequent interactions comprise with those of transcription authorities Jun and Fos, which can be members of the activator protein family of transcription factors.
After dimerization, these complexes then bind to antioxidant/electrophile responsive components ARE/EpRE and activate transcription, as is true with the Jun-Nrf2 complex, or suppress transcription, much like the Fos-Nrf2 complex.
The positioning of the ARE, which is triggered or inhibited, will determine which genes are transcriptionally controlled by these variables.
When ARE is triggered:
Activation of the synthesis of antioxidants is capable of detoxifying ROS like catalase, superoxide-dismutase, or SOD, GSH-peroxidases, GSH-reductase, GSH-transferase, NADPH-quinone oxidoreductase, or NQO1, Cytochrome P450 monooxygenase system, thioredoxin, thioredoxin reductase, and HSP70.
Activation of this GSH synthase permits a noticeable growth of the GSH intracellular degree, which is quite protective.
The augmentation of this synthesis and degrees of phase II enzymes like UDP-glucuronosyltransferase, N-acetyltransferases, and sulfotransferases.
The upregulation of HO-1, which is a really protective receptor with a potential growth of CO that in conjunction with NO allows vasodilation of ischemic cells.
Reduction of iron overload through elevated ferritin and bilirubin as a lipophilic antioxidant. Both the phase II proteins along with the antioxidants are able to fix the chronic oxidative stress and also to revive a normal redox system.
GSK3β under the management of AKT and PI3K, phosphorylates Fyn resulting in Fyn nuclear localization, which Fyn phosphorylates Nrf2Y568 leading to nuclear export and degradation of Nrf2.
NRF2 also dampens the TH1/TH17 response and enriches the TH2 response.
HDAC inhibitors triggered the Nrf2 signaling pathway and up-regulated that the Nrf2 downstream targets HO-1, NQO1, and glutamate-cysteine ligase catalytic subunit, or GCLC, by curbing Keap1 and encouraging dissociation of Keap1 from Nrf2, Nrf2 nuclear translocation, and Nrf2-ARE binding.
Nrf2 includes a half-life of about 20 minutes under basal conditions.
Diminishing the IKKβ pool through Keap1 binding reduces IκBα degradation and might be the elusive mechanism by which Nrf2 activation is proven to inhibit NFκB activation.
Keap1 does not always have to be downregulated to get NRF2 to operate, such as chlorophyllin, blueberry, ellagic acid, astaxanthin, and tea polyphenols may boost NRF2 and KEAP1 at 400 percent.
Nrf2 regulates negatively through the term of stearoyl CoA desaturase, or SCD, and citrate lyase, or CL.
C allele – showed a significant risk for and a protective effect against drug resistant epilepsy (DRE)
rs11085735 (I’m AC)
associated with rate of decline of lung function in the LHS
T allele – protective allele for Parkinsonian disorders – had stronger NRF2/sMAF binding and was associated with the higher MAPT mRNA levels in 3 different regions in brain, including cerebellar cortex (CRBL), temporal cortex (TCTX), intralobular white matter (WHMT)
rs10183914 (I’m CT)
T allele – increased levels of Nrf2 protein and delayed age of onset of Parkinson’s by four years
rs16865105 (I’m AC)
C allele – had higher risk of Parkinson’s Disease
rs1806649 (I’m CT)
C allele – has been identified and may be relevant for breast cancer etiology.
associated with increased risk of hospital admissions during periods of high PM10 levels
rs1962142 (I’m GG)
T allele – was associated with a low level of cytoplasmic NRF2 expression (P = 0.036) and negative sulfiredoxin expression (P = 0.042)
A allele – protected from forearm blood flow (FEV) decline (forced expiratory volume in one second) in relation to cigarette smoking status (p = 0.004)
rs2001350 (I’m TT)
T allele – protected from FEV decline (forced expiratory volume in one second) in relation to cigarette smoking status (p = 0.004)
rs2364722 (I’m AA)
A allele – protected from FEV decline (forced expiratory volume in one second) in relation to cigarette smoking status (p = 0.004)
C allele – associated with significantly reduced FEV in Japanese smokers with lung cancer
G allele – showed a significant risk for and a protective effect against drug resistant epilepsy (DRE)
AA alleles – showed significantly reduced KEAP1 expression
AA alleles – was associated with an increased risk of breast cancer (P = 0.011)
rs2886161 (I’m TT)
T allele – associated with Parkinson’s Disease
A allele – was associated with low NRF2 expression (P = 0.011; OR, 1.988; CI, 1.162–3.400) and the AA genotype was associated with a worse survival (P = 0.032; HR, 1.687; CI, 1.047–2.748)
rs35652124 (I’m TT)
A allele – associated with higher associated with age at onset for Parkinson’s Disease vs G allele
C allele – had increase NRF2 protein
T allele – had less NRF2 protein and greater risk of heart disease and blood pressure
rs6706649 (I’m CC)
C allele – had lower NRF2 protein and increase risk for Parkinson’s Disease
rs6721961 (I’m GG)
T allele – had lower NRF2 protein
TT alleles – association between cigarette smoking in heavy smokers and a decrease in semen quality
TT allele – was associated with increased risk of breast cancer [P = 0.008; OR, 4.656; confidence interval (CI), 1.350–16.063] and the T allele was associated with a low extent of NRF2 protein expression (P = 0.0003; OR, 2.420; CI, 1.491–3.926) and negative SRXN1 expression (P = 0.047; OR, 1.867; CI = 1.002–3.478)
T allele – allele was also nominally associated with ALI-related 28-day mortality following systemic inflammatory response syndrome
T allele – protected from FEV decline (forced expiratory volume in one second) in relation to cigarette smoking status (p = 0.004)
G allele – associated with increased risk of ALI following major trauma in European and African-Americans (odds ratio, OR 6.44; 95% confidence interval
AA alleles – associated with infection-induced asthma
AA alleles – exhibited significantly diminished NRF2 gene expression and, consequently, an increased risk of lung cancer, especially those who had ever smoked
AA alleles – had a significantly higher risk for developing T2DM (OR 1.77; 95% CI 1.26, 2.49; p = 0.011) relative to those with the CC genotype
AA alleles – strong association between wound repair and late toxicities of radiation (associated with a significantly higher risk for developing late effects in African-Americans with a trend in Caucasians)
associated with oral estrogen therapy and risk of venous thromboembolism in postmenopausal women
rs6726395 (I’m AG)
A allele – protected from FEV1 decline (forced expiratory volume in one second) in relation to cigarette smoking status (p = 0.004)
A allele – associated with significantly reduced FEV1 in Japanese smokers with lung cancer
GG alleles – had higher NRF2 levels and decreased risk of macular degeneration
GG alleles – had higher survival with Cholangiocarcinoma
rs7557529 (I’m CT)
C allele – associated with Parkinson’s Disease
Oxidative stress and other stressors can cause cell damage which may eventually lead to a variety of health issues. Research studies have demonstrated that Nrf2 activation can promote the human body’s protective antioxidant mechanism, however, researchers have discussed that Nrf2 overexpression can have tremendous risks towards overall health and wellness. Various types of cancer can also occur with Nrf2 overactivation. Dr. Alex Jimenez D.C., C.C.S.T. Insight
Sulforaphane and Its Effects on Cancer, Mortality, Aging, Brain and Behavior, Heart Disease & More
Isothiocyanates are some of the most important plant compounds you can get in your diet. In this video I make the most comprehensive case for them that has ever been made. Short attention span? Skip to your favorite topic by clicking one of the time points below. Full timeline below. Key sections:
00:01:14 – Cancer and mortality
00:19:04 – Aging
00:26:30 – Brain and behavior
00:38:06 – Final recap
00:40:27 – Dose
00:00:34 – Introduction of sulforaphane, a major focus of the video.
00:01:14 – Cruciferous vegetable consumption and reductions in all-cause mortality.
00:02:12 – Prostate cancer risk.
00:02:23 – Bladder cancer risk.
00:02:34 – Lung cancer in smokers risk.
00:02:48 – Breast cancer risk.
00:03:13 – Hypothetical: what if you already have cancer? (interventional)
00:03:35 – Plausible mechanism driving the cancer and mortality associative data.
00:04:38 – Sulforaphane and cancer.
00:05:32 – Animal evidence showing strong effect of broccoli sprout extract on bladder tumor development in rats.
00:06:06 – Effect of direct supplementation of sulforaphane in prostate cancer patients.
00:07:09 – Bioaccumulation of isothiocyanate metabolites in actual breast tissue.
00:08:32 – Inhibition of breast cancer stem cells.
00:08:53 – History lesson: brassicas were established as having health properties even in ancient Rome.
00:09:16 – Sulforaphane’s ability to enhance carcinogen excretion (benzene, acrolein).
00:09:51 – NRF2 as a genetic switch via antioxidant response elements.
00:10:10 – How NRF2 activation enhances carcinogen excretion via glutathione-S-conjugates.
00:10:34 – Brussels sprouts increase glutathione-S-transferase and reduce DNA damage.
00:11:20 – Broccoli sprout drink increases benzene excretion by 61%.
00:13:31 – Broccoli sprout homogenate increases antioxidant enzymes in the upper airway.
00:15:45 – Cruciferous vegetable consumption and heart disease mortality.
00:16:55 – Broccoli sprout powder improves blood lipids and overall heart disease risk in type 2 diabetics.
00:19:04 – Beginning of aging section.
00:19:21 – Sulforaphane-enriched diet enhances lifespan of beetles from 15 to 30% (in certain conditions).
00:20:34 – Importance of low inflammation for longevity.
00:22:05 – Cruciferous vegetables and broccoli sprout powder seem to reduce a wide variety of inflammatory markers in humans.
00:36:32 – Sulforaphane improves learning in model of type II diabetes in mice.
00:37:19 – Sulforaphane and duchenne muscular dystrophy.
00:37:44 – Myostatin inhibition in muscle satellite cells (in vitro).
00:38:06 – Late-video recap: mortality and cancer, DNA damage, oxidative stress and inflammation, benzene excretion, cardiovascular disease, type II diabetes, effects on the brain (depression, autism, schizophrenia, neurodegeneration), NRF2 pathway.
00:40:27 – Thoughts on figuring out a dose of broccoli sprouts or sulforaphane.
00:41:01 – Anecdotes on sprouting at home.
00:43:14 – On cooking temperatures and sulforaphane activity.
00:43:45 – Gut bacteria conversion of sulforaphane from glucoraphanin.
00:44:24 – Supplements work better when combined with active myrosinase from vegetables.
00:44:56 – Cooking techniques and cruciferous vegetables.
00:46:06 – Isothiocyanates as goitrogens.
According to research studies, Nrf2, is a fundamental transcription factor which activates the cells’ protective antioxidant mechanisms to detoxify the human body. The overexpression of Nrf2, however, can cause health issues. The scope of our information is limited to chiropractic and spinal health issues. To discuss the subject matter, please feel free to ask Dr. Jimenez or contact us at 915-850-0900 . Curated by Dr. Alex Jimenez
Additional Topic Discussion: Acute Back Pain
Back pain is one of the most prevalent causes of disability and missed days at work worldwide. Back pain attributes to the second most common reason for doctor office visits, outnumbered only by upper-respiratory infections. Approximately 80 percent of the population will experience back pain at least once throughout their life. The spine is a complex structure made up of bones, joints, ligaments, and muscles, among other soft tissues. Injuries and/or aggravated conditions, such as herniated discs, can eventually lead to symptoms of back pain. Sports injuries or automobile accident injuries are often the most frequent cause of back pain, however, sometimes the simplest of movements can have painful results. Fortunately, alternative treatment options, such as chiropractic care, can help ease back pain through the use of spinal adjustments and manual manipulations, ultimately improving pain relief.
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