SNP

New Marker Additions to GPL-SNP1000 DNA Sequencing Profile

BY: MATTHEW PRATT-HYATT, PHD

The number one goal for The Great Plains Laboratory is to provide the best quality results to our clients.  Our GPL-SNP1000 DNA Sequencing Profile has proven to be a great tool in helping provide personalized healthcare to our clients.  The nine pathways we analyze include: methylation, mental health, oxalate metabolism, drug and environmental metabolism/detoxification, gluten sensitivity, cholesterol metabolism, autism risk genes, and transporter gene.  These are crucial biological pathways, which are at the root of many chronic health conditions.  We are now announcing the addition of nine new markers to our already incredibly comprehensive genetic test:

Dopamine Beta Hydroxylase (DBH)
This is an enzyme that catalyzes the oxidation hydroxylation of dopamine to norepinephrine.  DBH can be inhibited by phenolic compounds including those produced by Clostridium species as well as certain organophosphate herbicides and pesticides.  There are two SNPs that can cause decreased activity of DBH.  These are rs2007153 and rs2283123.  These polymorphisms can lead to an increase in dopamine levels and a deficiency in norepinephrine.  Mental health disorders can result because of the imbalance of dopamine and norepinephrine.  Common symptoms can include depression and anxiety.

Paroxonase 1 (PON1)
This is an important enzyme in the metabolism and elimination of many organophosphorus insecticides (PMID: 13032041) and is located mainly in the liver.  PON1 is important in the reduction of atherosclerosis because of its involvement in the protection of high and low density lipoproteins from oxidation.  Individuals with polymorphisms to PON1 are more susceptible to heart disease (PMID: 8675673).  There are two known polymorphisms that can decrease the activity of PON1 and make the individual more susceptible to pesticide exposure, which are Q192R (rs662) and L55M (rs854560).

Hemochromatosis Protein (HFE)
The hemochromatosis gene HFE (high iron) codes for the HFE protein.   This protein is important for regulating the uptake of circulating iron.  This is done by regulating the interaction between transferrin receptor with transferrin.  SNPs to this gene can cause hemochromatosis, a disorder in which the body loads excess iron, which is autosomal recessive.  This means the patient normally needs two bad copies of the gene in order to exhibit symptoms.  There are three SNPs that can lead to hemochromatosis, rs1800562, rs1800730, and rs1799945.  Patients that are homozygous positive for this SNP should have their iron level measured. 

Vitamin K Epoxide Reductase Complex Subunit 1(VKORC1)
This is an enzyme that is necessary for the reduction of vitamin K 2,3-epoxide to its active form, which is important for clotting.  This enzyme is the primary target for the drug warfarin (Coumadin).  The three SNPs that are associated with warfarin sensitivity are rs9923231 (VKORC1*2), rs9934438, and rs8050894.  These polymorphisms can be used in conjuncture with the genotype of Cyp2C9 in order to accurately dose warfarin.

Tryptophan Hydroxylase 2 (TPH2)
This enzyme catalyzes the first and rate-limiting step in the biosynthesis of serotonin. Mutations to this enzyme have been associated with numerous psychiatric diseases including depression, OCD, bipolar disorder, and suicidal behavior.

Major Histocompatibility Complex DQA1 and DQA8
Patients with SNPs to HLA DQA1 and DQA8 have a higher risk of celiac disease.   The HLA-DQA1 and DQA8 are human leukocyte antigen serotype (also called major histocompatibility complex II). The role of this peptide is to present proteins on the surface of cells for identification purposes. This particular serotype presents proteins belonging to a foreign invader on the cells the macrophages, B cells, and dendritic cells in order to activate the helper T cells of the immune system. Proper presentation is critical for immune system activation against pathogens and may possibly be a mediator of autoimmunity.

UDP Glucosyltransferase 1A1 and 1A8 (UGT1A1 and UGT1A8)
These enzymes are important members of the glucuronidation phase II detoxification pathway.  These enzymes catalyze the addition of a glycosyl group from a nucleotide sugar to a small hydrophobic molecule.  The addition of glycosyl groups results in these molecules becoming more water-soluble and easier to excrete. Some of the target molecules for these enzymes include bilirubin, drugs, hormones, and steroids.

The Importance of Genetic Testing for Mental Health

Two weeks ago I talked about how we are starting to move into the age of personalized medicine.  Our goal at The Great Plains Laboratory is to determine what factors lead to chronic illnesses and what treatments may help.  Previously I discussed how the Organic Acids Test (OAT) and the GPL-SNP1000 DNA Sequencing Profile work well together to determine both the risk for and causes of many chronic illnesses and how useful these two tests are in helping practitioners develop individualized treatments.  Last week I specifically discussed the DNA methylation pathway, of the GPL-SNP1000.  This week I am going to go over the mental health pathway of the this same test.  I will talk about what genes are most important, some specific polymorphisms to be aware of, how the OAT can help diagnosis these disorders, and what treatments seem to work best. 

The two most important genes in this pathway are MAO-A (monoamine oxidase A) and COMT (catechol-o-methyltransferase) (Please see Figure 1). Both enzymes are required for metabolizing neurotransmitters critical to mental health. Mutations to either one can have serious consequences relating to how we think, feel, and interpret the world around us.

Figure 1

MAO-A
Monoamine oxidase A is important for the metabolism (breakdown) of biogenic amines such as the neurotransmitters dopamine, norepinephrine, and serotonin (figure 2).  Mutations to this gene have also been linked to depression, borderline personality disorder, and bipolar disorder. 

 

Figure 2

 

There are two different types of polymorphisms involved with MAO-A.  The first type, which is characterized by rs6323 , causes an increase in activity of the enzyme. Rapid metabolism resulting from this mutation causes depletion in the neurotransmitter. This depletion is directly related to the extent of the enzyme activity which can be determined on the Organic Acid test (OAT) by measuring the production of Homovanillic acid (HVA) and Vanillylmandelic acid (VMA) which are the end products of dopamine and epinephrine metabolism (see figure 1).  Patients who are rapid metabolizers will show an increase of HVA of VMA (Figure 3).  Such patients will have a depletion of these neurotransmitters which leads to multiple neurological diseases including depression. Treatment for these polymorphisms includes supporting the methylation pathway which helps to promote the cofactor required for neurotransmitter synthesis and providing neurotransmitter precursors such as tyrosine, B6 and 5-HTP.

Figure 3

A second type of polymorphism to MAO-A is one that decreases activity (rs72554632,  Gln296X), whichcauses a premature stop codon in the gene..  This polymorphismwill lead to a buildup of neurotransmitters, which can lead to the development of Brunner syndrome.  Brunner syndrome is characterized by a decrease of mental capabilities, increased impulsivity, mood swings, and sleep disorders. These individuals will have a decrease of HVA and VMA metabolites on the OAT. Without the benefit of genetic testing, these results could lead a practitioner to treat with neurotransmitter precursors. Increasing neurotransmitters for individuals with this type of mutation would actually exacerbate the condition. Treatments include decreasing the amine containing foods such as fish, cheese, and fruit, taking progesterone to increase MAO; taking inositol(which reduces 5HT2A serotonin receptor), taking riboflavin (increases MAO activity), or taking ginkgo, which has been shown to decrease aggressiveness in MAO-A deficient patients.

COMT
Catechol-O-methltransferase (COMT) is present in the body in two different forms.  The short form is called soluble catechol-O-methyltransferase (S-COMT).  The longer form is called membrane-bound catechol-O-methyltransferase (MB-COMT).   MB-COMT is mainly present in the nerves of the brain, while S-COMT is located in the liver, kidney, and blood.  In the brain, MB-COMT is responsible for degrading neurotransmitters called catecholamines, which include dopamine, epinephrine, and norepinephrine. Therefore the membrane bound form is believed to have a greater affect on mental health, though both forms may be implicated in disease since both are capable of metabolizing catecholamines.

GPL-SNP1000 analyzes six different SNPs for COMT.   Of these, the most extensively studied is a mutation to rs4680 (Val158Met). Despite the many studies available about this mutation, the scientific community is still at odds about the degree to which this mutation causes disease. What is known is that individuals with this mutation have lower activity of the enzyme.  Mutations to COMT will lead to dopamine and epinephrine not being broken down properly, which can be detected by a decrease in the HVA metabolite in the Organic Acids Test.

Figure 4

Interestingly, some individuals may benefit from increased dopamine while others may benefit from less. Dopamine functions differently depending on the area of the brain it is produced in and there are likely other mutation to this gene may also influence its function and expression. These interactions are still being investigated and are why GPL is looking beyond the most common mutation to help inform results.  Conditions associated with these mutations include OCD, depression, and schizophrenia.  Symptomatic patients may benefit from treatment aimed at promoting the enzyme function so that dopamine and epinephrine can be metabolized. This is a SAM dependant enzyme and methylation support can be helpful in patients with this mutation.

APOE
Apolipoprotein E (APOE) combines with lipids in the body to form lipoproteins.  Lipoproteins are responsible for packaging cholesterol and other lipids and carrying them through the bloodstream.  Like so many genes in the human body, this is not its only function. The ApoE protein is involved with more than was originally thought. In this case, it has a role in immune expression, cognitive function, and telomere regulation.  There are four different gene versions of APOE called e1 (the double mutant), e2 (rs7412), e3, and e4 (rs429358).  The most common version is e3, the most detrimental is e4

 Mutations to APOE can lead to an increased risk of developing Alzheimer’s disease. People who inherit even one copy of the APOE e4 allele have an increased risk of developing the disease. Certain mutations to this protein impair the ability of the body to phosphorylate NMDA (glutamate) receptors causing a reduction in activity (Glutamate receptors have been implicated in a number of neuropsychiatric disorders including depression, biopolar disorder, schizophrenia, and Autism (PMID: 12404584, 21315104). While this gene is being extensively studied for its role in Alzheimer’s disease, vulnerable patients may also be predisposed to other psychiatric disorders. (PMID: 25751510, 15557508). Patients with certain ApoE mutations may develop cognitive symptoms well before onset of Alzheimer’s disease (http://psycnet.apa.org/journals/neu/16/2/254/).  Patients with these polymorphisms should look for early signs of the development of Alzheimer’s disease.  Treatment with estrogen has demonstrated some encouraging results.

DAOA
The D-amino acid oxidase activator (DAOA) protein (also known as G72) is a 153 amino acid protein that localizes in the brain, spinal cord, and testis.  This protein is located in the endoplasmic reticulum and the mitochondria cellular compartments.   DAOA is a modulator of D-amino acid oxidase (DAO) activity.  If DAO is hyper activated it can result in a decrease in the D-serine level and hypo function of the NMDA receptor.  Overexpression of DAOA has been found in schizophrenics and those suffering from bipolar disorder.  Mutations to DAOA have been linked to a higher incidence of schizophrenia and bipolar disorder. 

It is important to remember that our genes influence our mental health and well being but do not necessarily determine the eventual outcome. There are countless factors that play an equal role in how we perceive the world including diet and lifestyle.   I believe that understanding the most common mutations and their function is very helpful in diagnosing, treating, and preventing different neurological disorders.  Using the GPL-SNP1000 test in combination with the OAT can further help determine the extent to which our genes are being expressed metabolically. The combination of these two tests can help bring about the best chance to achieve emotional health and physical well being.

Email gplblog@gpl4u.com if you have any questions about this blog post.

 

DNA Methylation Pathway

In my post last week I briefly talked about the methylation pathway, also called the MTHFR cycle and how disruptions in this pathway may appear on an Organic Acid Test (OAT).  Today, I will go more in-depth into this pathway. Since most practitioners have at least some knowledge of this its function, I’ve decided to focus on the more important polymorphisms (SNPs) common to these genes and on the treatments that work the best for these mutations.  Patients should talk to their healthcare practitioner before starting any treatment. 

The important role of methylation is gaining in popularity among functional medicine groups these days because mutations are quite common and lead to many different chronic conditions. Practitioners interested in treating the root cause of illness are especially interested in learning about this pathway because nucleotide synthesis, neurotransmitter function, detoxification, and numerous other processes are greatly improved once these mutations have been compensated for, leading to much better patient outcomes.

If you’re not already familiar, the methylation pathway is a process by which carbons are added onto folic acid from amino acids and redistributed onto other compounds throughout the body.  This process is responsible for the formation of methionine, S-Adenosyl methionine (SAM), and thymidylate monophosphate (dTMP).  Mutations in this pathway usually lead to the reduction of methionine which leads to the absence of S-adenosyl methionine (SAM). This compound facilitates virtually every methylation reaction in the body. These reactions include the promotion of several neurologically important agents, histamine breakdown, CoQ10 synthesis, and tissue-specific gene expression. The accumulation of homocysteine, which is caused by mutations in this pathway, has been directly linked to oxidative stress which influences multiple factors of disease.      

When we designed the GPL-SNP1000 test, we knew that most other genetic tests were only reporting about 35 SNPs of the common methylation pathway enzymes. When we did our literature research, we found 105 different methylation SNPs that could potentially cause health conditions and included all of these to provide a more useful tool for practitioners.

MTHFR

Methylenetetrahydrofolate reductase (MTHFR) is an enzyme that converts 5,10-methylenetetrahydrofolate to 5,methyltetrahydrofolate, which is the active form of folate.  Mutations in this gene cause the accumulation of homocysteine and a lack of available folate for cellular functions. Both of these factors have been linked to oxidative stress, vascular disease (including cardiovascular), neural tube defects, neurological disorders (including schizophrenia and bipolar disorder), cancer, preeclampsia, hypotonia, and seizures.  Common mutations are rs1801133 (C677T), rs1801131 (A1298C), and rs2274976 (G1793A).  The C677T polymorphism is present in about 39% of caucasians as heterozygotes and 17% as homozygotes.  Table 1 provides data on how much activity your MTHFR enzyme would possess with different combinations of the C677T and the A1298C.

 TABLE 1

TABLE 1

Patients with polymorphisms in MTHFR may consider supplementing with methyl-B12 (also called methylcobalamin) and methyl-folate.  We recommended starting at a very low doses and building up.

MTR

Methionine synthase (MTR) is also known as 5-methyltetrahydrofolate-homocysteine methyltransferase.  This enzyme facilitates the transfer of a methyl group from 5-methyltetrahydrofolate to homocysteine using cobalamin (B12) and MTRR enzyme as a catalyst. The end products of this reaction are the amino acid methionine and the vitamin tetrahydrofolate.  Mutations in this gene lead to a lack of methionine and the accumulation of homocysteine in the body (hyperhomocysteinemia).  The pathological consequence of the gene mutation depends on how profoundly these methylation pathways are affected and the degree of homocysteine accumulation in the body.  The most common polymorphism is rs1805087 (A2756G), which most genetic tests do analyze.  However, we decided to look at seven different SNPs including the rs121913581 (R52Q) polymorphism.  This is a rare polymorphism; however it could dramatically affect the activity of patients with MTR polymorphisms, who should also consider methyl-B12, as well as S-adenosyl methionine (SAM) supplementation.  ).

MTRR

Methionine synthase reductase (MTRR) is also known as 5-methyltetrahydrofolate-homocysteine methyltransferase reductase.   MTRR is important for the methylation of cobalamin and subsequent activation of methionine synthase (MTR).  Mutations in this gene lead to a lack of methionine and the accumulation of homocysteine in the body (hyperhomocysteinemia). Some common mutations in this pathway are RS1801394 and RS10380.  Patients who are heterozygous for MTHFR mutations and concomitant mutations to MTRR have a greater loss of function and increased levels of homocysteine. Patients with MTRR polymorphisms should consider methyl-B12 and SAMe supplementation. 

AHCY

Adenosylhomocysteinase (AHCY) is also known as S-adenosylhomocysteine hydrolase.  AHCY is an enzyme involved in the degradation of the amino acid methionine.  AHCY converts the methionine substrate S-adenosylhomocysteine (SAH) to adenosine and homocysteine. This reaction is an important part of the regulation of methyl groups which are added to DNA, RNA, proteins, and lipids (fats).  Methyl groups help regulate what parts of the genome are active and control protein activity.  Mutations to the AHCY gene can cause methionine to accumulate in the blood, which is called hypermethioninemia (MET).  Two common mutations are Trp112X which causes tryptophan to be replaced with a premature stop signal and Tyr143Cys.  MET  can manifest in neurological problems, delays in motor skills, muscle weakness, and liver problems.  Patients with MET should consult with a dietician to avoid the amino acid methionine.

BHMT

Betaine-homocysteine methyltransferase (BHMT) and BHMT2 are the only enzymes that can metabolize betaine.  This reaction is considered the alternate or short route for methylation.  BHMT uses zinc as a co-factor to catalyze the transfer of a methyl group from betaine to homocysteine.  There are several mutations in the human population that decrease the activity of this enzyme.  BHMT mutations can result in fatty liver and hepatocellular (liver) carcinomas.  BHMT mutations in mothers increase the risk of Down syndrome for their children.  Patients with BHMT polymorphisms are recommended to take betaine and zinc.

CBS

Cystathione beta-synthase (CBS) is a pyridoxal-5’-phosphate (vitamin B6) dependent enzyme that converts L-serine and L-homocysteine into L-cystathionine.   L-cystathionine is later converted into the amino acid cysteine.  Mutations to the CBS gene are the most common cause of hereditary hyperhomocysteinemia.   The adverse effects of homocysteine accumulation in the body are related to the substitution of homocysteine for methionine in protein synthesis. The resulting complications include an increase in immune response, increase in cell death, and protein damage. The degree of homocysteinemia is relative to the mutation.  Hyperhomocysteinemia has been linked to multiple mutations to the CBS gene.  The most common of these are the Ile278Thr and the Gly307Ser, which cause homocysteine to build up in the blood.  Complications of hyperhomocysteinemia include mental retardation, seizures, and vascular disease. One of the most common causes of death for patients with homocystinuria (CBS deficiency) is heart attack.   Patients with CBS polymorphisms are recommended to take glutathione and B6.  There are reports that the CBS polymorphisms A360A (rs1801181) and N212N (rs2298758) can lead to an increase in CBS activity.  Some claim that these mutations lead to a buildup of ammonia and decrease in glutathione. Since ammonia is a very unstable compound that must be measured STAT for accurate results, the better marker for increased ammonia is orotic acid which is very stable and accumulates when excessive amines are filtered through the urea cycle. I recommend that patients with this mutation do an Organic Acid test (OAT) and look at marker 60 (orotic acid) for ammonia and markers 58-59 (Pyroglutamic and 2-hydroxybutyric acid) for glutathione synthesis and cysteine accumulation respectively.

SHMT1

Serine hydroxymethyltransferase (SHMT1) is important for linked reactions.  The first is the conversion of tetrahydrofolate to 5,10-methylenetetrahydrofolate.  The second is the conversion of L-serine to glycine.  It also has a role in mediating the synthesis of dTMP and SAM. It preferentially selects for dTMP biosynthesis which is the precursor to the nucleic acid thiamine. Mutations in this enzyme may cause elevations in uracil which can build up when dTMP synthesis in impaired.  Uracil is marker 40 in the OAT.  

SUOX

Sulfite oxidase (SUOX) is an enzyme that is located in the mitochondria of cells.  The enzyme oxidizes sulfite to sulfate.  The physiological damage that occurs as a result of enzyme deficiency may be due to the accumulation of toxic levels of sulfite, from the absence of sulfate, or both. Sulfite is a reactive product of cysteine metabolism found in high concentrations in the brain. Its toxicity is exacerbated by glutathione depletion. Sulfate plays an important role in detoxification and deactivation of toxic compounds. Sulfate deficiency has been linked to autism, Parkinson’s disease, and Alzheimer’s disease.  Individuals with SUOX genetic mutations may benefit from a reduction in dietary methionine and cysteine.

VDR

Vitamin D receptor (VDR) is a nuclear hormone receptor for vitamin D3.  Vitamin D3 interacts with this receptor to influence multiple biological activities by regulating gene transcription.  Vitamin D3 is associated with maintenance of calcium distribution. More recently, it has been implicated in inflammatory processes, vascular integrity, and collagen formation. Mutations in VDR have been linked to metabolic syndrome.  Individuals with VDR mutations have greater propensity for insulin insensitivity, higher triglycerides, and lower HDL levels.  Vitamin D receptor mutations can also lead to vitamin-D-dependent rickets type 2.  Patients with VDR polymorphisms are recommended to take 1000 units/day for children or 5000 units/day for adults. 

I hope this information is helpful.  I know many of these pathways can be very intimidating, but hopefully we can work together to produce useful treatment plans for everyone.  Next week I plan on talking about the mental health genes MAO and COMT.

Email gplblog@gpl4u.com if you have any questions about this blog post.

Genetic Testing and Organic Acids Testing: A Dynamic Duo of Diagnostics

Today I have two words for you:  Personalized medicine.  What does this phrase mean to you?  When I think of personalized medicine I think of treatments that are custom designed for each individual patient, and I believe this is the ultimate goal for all of us in the field of functional medicine.  To make this happen, we will have to work together as a team - the healthcare practitioner, the lab, and the patient.  If we do so effectively, the result should be better health and improved lives of our patients.  The only way to get there is to design a treatment plan that addresses the underlying cause(s) of our patient’s ailments and not try to just suppress the symptoms. 

When I talk to both practitioners and patients, they often ask “Where do we start?” or “What is your most important test?”, and until recently I would have always said that the Organic Acids Test (OAT) is the obvious place to start.  The reason for this is that the OAT provides more information than any other test.  The OAT gives us a metabolic snapshot of multiple pathways in the body, offering insight into possible underlying causes of symptoms, as well as what kind of nutritional support is needed.  However, now the OAT by itself is no longer the obvious choice.  I am now recommending the OAT + GPL-SNP1000 combo because these two tests, one metabolic and one genetic, work so well together.   Today I would like to share some of the markers in each of these tests that work really well in tandem.    The primary pathways where we see overlap between the two tests are methylation, mental health, detoxification, and oxalate metabolism. 

The first pathway that GPL-SNP1000 covers is the DNA methylation pathway, also called the MTHFR pathway.  This pathway is a process by which carbons are added onto folic acid from amino acid and redistributed onto other compounds throughout the body.  This process is responsible for the formation of methionine, S-Adenosyl methionine (SAMe), and thymidylate monophosphate (dTMP).  These compounds are then used in neurotransmitter metabolism, detoxification, nucleotide synthesis, and multiple other processes.  I can’t say enough about how important neurotransmitter metabolism and detoxification of chemicals are to everyone’s health.  We have so many patients for whom the majority of their symptoms result from the upset of these two processes.  Since the methylation pathway is so important we decided to make it a high priority in our new genetic test.   GPL-SNP1000 looks at 105 different methylation SNPs (single-nucleotide polymorphisms).   Next week I plan on going more in-depth on the methylation pathway and how GPL-SNP1000 can be useful.

So what markers in the OAT are important for patients with MTHFR mutations?  The first one we have is vitamin B12.  We evaluate B12 levels by measuring the amount of methylmalonic acid (see Figure 1).  B12 is an important cofactor for many of these methylation enzymes.  The second important marker is pyridoxic acid, which is a form of vitamin B6. I have counted over 50 enzymes that require B6 in the body.  It is an important cofactor in the methylation pathway.  It is directly involved with the function of CBS enzyme and indirectly involved with MTHFR, BHMT, and SHMT.  Another marker involved with the MTHFR pathway is uracil.  Having an elevated uracil level can be indicative of folate pathway malfunction.

The next pathway that is helpful to analyze in both the OAT and GPL-SNP1000 is the mental health pathway, which involves the synthesis and breakdown of neurotransmitters in the brain.  The combination of measuring the neurotransmitter metabolites and knowing if the enzymes involved are functional will help guide us to the best treatment options.  GPL-SNP 1000 covers 14 different mental health genes, which I will cover next week (I’m trying not to make these blog posts too long).  Three of the best markers in the OAT for measuring neurotransmitter metabolism are homovanillic acid (a dopamine metabolite), vanilymandelic acid (epinephrine/norepinephrine), and 5-HIAA (serotonin, marker).  These markers are the metabolites of the neurotransmitters by the enzymes MAOA and COMT (see Figure 2), the genes for which are analyzed in GPL-SNP1000.  Deficiencies in these enzymes due to faulty SNPs  may cause low neurotransmitter levels, which may also be caused by low amounts of precursors, cofactors, or increased inhibitors which is why information from both the OAT and GPL-SNP1000 is so incredibly useful.   

The third pathway that I will briefly touch on today is the detoxification pathway, and specifically for glutathione (GSH).  Detoxification is so important in today’s industrial, polluted, and toxic world.  Every day we are inundated by hundreds of chemicals.  We are exposed to many through the environment and some by choice (like medications).  Our bodies have to process these chemicals in some way.  GPL-SNP1000 looks at dozens of genes that are important for detoxification.  A good marker in the OAT for how well the body is detoxifying is pyroglutamic acid.  Elevated values of pyroglutamic acid are indicative of glutathione deficiency due to excessive toxic exposure or a genetic issue. 

The final pathway I’m going to discuss today is oxalate metabolism.  Oxalates are crystalline molecules that we absorb from our diet (high oxalate foods) or are produced by an infection, like yeast/fungal overgrowth.  These oxalates can accumulate in the body and cause inflammation.  The symptoms of oxalate accumulation include pain, nephrolithiasis, and neurological symptoms. Oxalates are known to cause/create kidney stones.  Children with autism who exhibit eye-poking behavior have been shown to have a build-up of oxalates behind their eyes, causing tremendous pain, and thus the eye-poking.  GPL-SNP1000 covers five different genes involved with the production and elimination of oxalates.  The OAT has three oxalate markers:  glyceric, glycolic, and oxalic acids. (Figure 3)  In addition, low B6 and increased yeast or fungal markers are associated with increased oxalates. 

I think that is all I’ll cover today.  In the future I will cover the methylation pathway and the neurotransmitter pathway a little more in-depth.  If there is another pathway you want me to cover in greater detail, please let me know.  I want to be a part of your healthcare team as we all work together for the better well-being of our patients.

Email gplblog@gpl4u.com if you have any questions about this blog post.