Gene Silencers and Enhancers in Autism; plus Epicatechin, MOCOS, Ferritin and Oxidative Stress (GR, GPx, GCL, GCLM)

The original idea of this blog was to try to keep complicated things as simple as possible, so at times things may get over-simplified.  

This post starts out simple and then gets rather involved in oxidative stress.

When people think about genes, they are nearly always thinking about the “blueprints” that are encoded on your DNA.  As it turns out only about 5% of your DNA is dedicated to this function; this 5% is contained in the exome.

Much autism research is dedicated to finding faulty “blueprints” that might account for autism.  There are now several hundred so called “autism genes”, where an error in the “blueprints”, means that the associated protein is not produced to its intended specification.

We also have seen that genetic defects just lead to a possibility of something going wrong.  A “faulty gene” creates the possibility of a specific dysfunction happening, it does not mean 100% that it will happen. 

Partial dysfunctions and partial deficiency

We also saw that even when a single gene dysfunction, like for fragile-X, occurs it does not always cause a catastrophic failure, rather it produces a spectrum from mild to severe.

This point is important since it seems in autism there can often be “partial dysfunctions” leading to “partial deficiencies”.  This is just a less severe form of the “rare” total dysfunctions.  The growing list of examples includes partial biotinidase deficiency, partial glutathione reductase deficiency and partial glutathione peroxidase deficiency.  Today we will also encounter ferritin (iron storage) partial deficiencies.  In a future post we will look the vitamin B12 partial dysfunction that occurs in about a quarter of schizophrenia and autism cases.

This then leads us to the subject of gene expression, which means how much, where, when and how often a gene is turned “on”.  This is actually what really matters, since even perfectly good genes, when over-expressed, can do great damage.  We saw that in the case of Down Syndrome there is about 50% over expression in up to 300 genes.  In the case of Down Syndrome the reason for this overexpression lies in the exome.  In effect there is a double set of blueprints for those 300 genes.

Within the remaining 95% of your DNA are so-called enhancers and silencers.  Their job is to determine which genes are turned on (enhancers) or turned off (silencers) in which part of the body.  So a gene might encode a calcium channel, but that calcium channel should only be in certain parts of the body and only to a certain degree.  We need the correct clean blueprint and we need it applied in the right part of the body and only to the desired extent.

I was very pleased to see that some scientists have started to look at the role of enhancers in autism.  I have already noticed that some substances that are known to affect gene expression are particularly effective in autism.  This suggests to me that in some types of autism, the problem may actually be simply in gene expression rather than any faulty genetic “blueprint”.

Now the science of enhancers and particularly silencers is still at the emerging stage, but the research showed that in at least 100 locations, there were significant anomalies in those with autism.

Gene  function in the human brain could help reveal basis of autism

This is an easy to read summary of the research paper below.

Coexpression networks identify brain region–specific enhancer RNAs in the human brain

Abstract

Despite major progress in identifying enhancer regions on a genome-wide scale, the majority of available data are limited to model organisms and human transformed cell lines. We have identified a robust set of enhancer RNAs (eRNAs) expressed in the human brain and constructed networks assessing eRNA-gene coexpression interactions across human fetal brain and multiple adult brain regions. Our data identify brain region-specific eRNAs and show that enhancer regions expressing eRNAs are enriched for genetic variants associated with autism spectrum disorders.

We also have the removable markers on the 5% of DNA that cause epigenetic changes.  This is another way of turning on or off specific genes.  These markers can be caused by environment factors like smoking, or even stress, these markers are potentially both removable and inheritable.     

The emerging science of Proteomics is the study of gene expression itself, so it is measuring all the proteins that the genes actually produced.

Limits of Genetic Testing

So while in some cases genetic testing of the 5% of DNA usually examined may indeed be useful, if your problem was in the other 95% of DNA it will not help.

To be useful in autism you would need to measure gene expression in the brain or the local activity of the enhancers/silencers, since it varies throughout the body.  In the Australian study above they measured the enhancer activity in the brain, by looking for the special enhancer molecules the enhancers produce.

This is all way beyond the scope of this blog.

However when I see “safe” substances like Sulforaphane, Epicatechin and even statins that are known to affect the expression of multiple genes, I take note. 

Steroids also affect gene expression, but great care has to be taken with steroids.

Statins have numerous interesting effects in the brain and in cancer cells.  In autism they have an effect on PTEN and BCL2 for example.

Chronic Administration of Statins Alters Multiple Gene Expression Patterns in Mouse Cerebral Cortex

Statins down regulate myeloperoxidase gene expression in macrophages

Statins cause profound effects on gene expression in human cancer cellsin vitro: the role of membrane microdomains.

The observed impact of pravastatin on gene expression may explain the pleiotropic effects of statins when they are used as adjuvants in chemotherapy and suggests impact on gene expression as a possible cause of side effects from statin use.

As pointed out in the last paper, changing gene expression can be bad as well as good.  It all depends where you are starting from and what genes you want to enhance/silence.

Other therapies to modify gene expression

Today’s scientific knowledge does not always allow us to target the expression of specific genes, this very much remains future science.

However, the remarkable effects of some substances, in some people, does suggest some options.  As is often the case this takes us back to oxidative stress, which does seem to affect many conditions and is quite well studied. There is no shortage of anecdotal evidence.

We know from the research that oxidative stress is ever-present in autism and that people with autism are particularly sensitive to it.

One substance previously mentioned in this blog, epicatechin, is known to change the expression of many genes including STAT1, MAPKK1, MRP1, and FTH1, which are involved in the cellular response to oxidative stress.

Ferritin

Rather off subject the FTH1 gene encodes the heavy subunit of ferritin, the major intracellular iron storage protein.

Relationship of serum ferritin levels to sleep fragmentation and periodic limb movements of sleep on polysomnography in autism spectrum disorders.

Children with autism spectrum disorders had significantly lower ferritin levels compared with controls

Within the autism spectrum disorders population, median ferritin levels were significantly lower in patients with poor sleep efficiency (7 ng/mL) versus those with normal sleep efficiency (29 ng/mL) (P = 0.01).

Low ferritin would indicate an iron storage problem and likely anemia/anaemia. 

Low ferritin has many effects, including surprisingly, poor sleeping patterns.

  

Is it such a surprise that a cup of cocoa (epicatechin) before bed used to be given to ensure a good night’s sleep?  (all via FTH1, I presume)

Perhaps poor sleep in autism is just another consequence of oxidative stress?

MOCOS

In the recent paper on MOCOS:-

Olfactory stem cells reveal MOCOS as a new player in autism spectrum disorders

I noted that:-

Furthermore, we found that MOCOS misexpression induces increased oxidative-stress sensitivity.

MOlybdenum COfactor Sulfurase (MOCOS), is an enzyme involved in purine metabolism and a newly identified player in ASD. MOCOS appears to be downregulated in autism and this has multiple effects, one being increased sensitivity to oxidative stress.

Seemingly unknown to the French MOCOS researchers, there already is a therapy:-

Rescue of lethal molybdenum cofactor deficiency by a biosynthetic precursor from Escherichiacoli

Since I do not have any of the above biosynthetic precursor at hand, but I do have high flavanol cocoa in the kitchen, it is time to look again at epicatechin.

Epicatechin

There are two very similar substances catechin and epicatechin; both are flavonoids.  Both affect gene expression and both seem to have numerous good properties.

Epicatechin is found in large quantities in mildly processed cocoa, which catechin in found in large quantities in certain types of Chinese tea.

We saw in an earlier post that Mars, the chocolate company, has invested substantially in the science of cocoa and its flavonoids.  They have just signed a 5 year research contract with Harvard.

Catechin affects the fat metabolism and is therefore a potential therapy for obesity.  Oolong tea has been shown to have this effect, but you do need to drink a great deal of it.

Beneficial effects of oolong tea consumption on diet-induced overweight and obese subjects

CONCLUSIONS:

Oolong tea could decrease body fat content and reduce body weight through improving lipid metabolism. Chronic consumption of oolong tea may prevent against obesity.

  

The cocoa flavanol (-)-epicatechin protects the cortisol response

ABSTRACT Various health benefits of the cocoa flavanol (-)-epicatechin (EC) have been attributed to its antioxidant and anti-inflammatory potency. In the present study we investigated whether EC is able to prevent deterioration of the anti-inflammatory effect of the glucocorticoid (GC) cortisol in the presence of oxidative stress. It was found that cortisol reduces inflammation in differentiated monocytes. Oxidative stress extinguishes the anti-inflammatory effect of cortisol, leading to cortisol resistance. EC reduces intracellular oxidative stress as well as the development of cortisol resistance. This further deciphers the enigmatic mechanism of EC by which it exerts its anti-inflammatory and antioxidant action. The observed effect of the cocoa flavanol EC will especially be of relevance in pathophysiological conditions with increased oxidative stress and consequential GC resistance and provides a fundament for the rational use of dietary antioxidants

Flavanol-rich cocoa induces nitric-oxide-dependent vasodilation in healthy humans

  

Abstract

Background: Consumption of flavonoid-rich beverages, including tea and red wine, has been associated with a reduction in coronary events, but the physiological mechanism remains obscure. Cocoa can contain extraordinary concentrations of flavanols, a flavonoid subclass shown to activate nitric oxide synthase in vitro.

Objective: To test the hypothesis that flavanol-rich cocoa induces nitric-oxide-dependent vasodilation in humans.

Design: The study prospectively assessed the effects of Flavanol-rich cocoa, using both time and beverage controls. Participants were blinded to intervention; the endpoint was objective and blinded.

Methods: Pulse wave amplitude was measured on the finger in 27 healthy people with a volume-sensitive validated calibrated plethysmograph, before and after 5 days of consumption of Flavanol-rich cocoa [821 mg of flavanols/day, quantitated as (−)-epicatechin, (+)-catechin, and related procyanidin oligomers]. The specific nitric oxide synthase inhibitor, N^G-nitro-l-arginine methyl ester (l-NAME) was infused intravenously on day 1, before cocoa, and on day 5, after an acute ingestion of cocoa.

Results: Four days of flavanol-rich cocoa induced consistent and striking peripheral vasodilation (P = 0.009). On day 5, pulse wave amplitude exhibited a large additional acute response to cocoa (P = 0.01). l-NAME completely reversed this vasodilation (P = 0.004). In addition, intake of flavanol-rich cocoa augmented the vasodilator response to ischemia. Flavanol-poor cocoa induced much smaller responses (P = 0.005), and none was induced in the time-control study. Flavanol-rich cocoa also amplified the systemic pressor effects of l-NAME (P = 0.005).

Conclusion: In healthy humans, flavanol-rich cocoa induced vasodilation via activation of the nitric oxide system, providing a plausible mechanism for the protection that flavanol-rich foods induce against coronary events.

Cocoa Flavanols and Brain Perfusion

Flavanols, the Kuna, cocoa consumption, and nitric oxide

Abstract

The Kuna Indians, who reside in an archipelago on the Caribbean Coast of Panama, have very low blood pressure (BP) levels, live longer than other Panamanians, and have a reduced frequency of myocardial infarction, stroke, diabetes mellitus, and cancer—at least on their death certificates. One outstanding feature of their diet includes a very high intake of flavanol-rich cocoa. Flavonoids in cocoa activate nitric oxide synthesis in healthy humans. The possibility that the high flavanol intake protects the Kuna against high BP, ischemic heart disease, stroke, diabetes mellitus, and cancer is sufficiently intriguing and sufficiently important that large, randomized controlled clinical trials should be pursued.

Glutathione reductase (GR) and (partial) Glutathione reductase deficiency

Glutathione reductase (GR) catalyzes the reduction of glutathione disulfide (GSSG) to the sulfhydryl form glutathione (GSH), which is a critical molecule in resisting oxidative stress and maintaining the reducing environment of the cell.

Glutathione reductase reduces one mole of GSSG to two moles of GSH.

Glutathione reductase deficiency is a “rare” disorder in which the glutathione reductase activity is absent from erythrocytes, leukocytes or both. In one study this disorder was observed in only two cases in 15,000 tests for glutathione reductase deficiency performed over the course of 30 years. In the same study, glutathione reductase deficiency was associated with cataracts and favism in one patient and their family, and with severe unconjugated hyperbilirubinemia in another patient. It has been proposed that the glutathione redox system (of which glutathione reductase is apart) is almost exclusively responsible for the protecting of eye lens cells from hydrogen peroxide because these cells are deficient in catalase, the enzyme which catalyzes the breakdown of hydrogen peroxide, and the high rate of cataract incidence in glutathione reductase deficient individuals.

Some patients exhibit deficient levels of glutathione activity as a result of not consuming enough riboflavin in their diets. Riboflavin is a precursor for FAD, whose reduced form donates two electron to the disulfide bond which is present in the oxidized form of glutathione reductase in order to begin the enzyme's catalytic cycle.
In 1999, a study found that 17.8% of males and 22.4% of females examined in Saudi Arabia suffered from low glutathione reductase activity due to riboflavin deficiency.

Glutathione reductase deficiency in Saudi Arabia.

Abstract

Glutathione reductase (GR) is a ubiquitous enzyme required for the conversion of oxidized glutathione (GSSG) to reduced glutathione (GSH) concomitantly oxidizing reduced nicotinamide adenine dinucleotide phosphate (NADPH) in a reaction essential for the stability and integrity of red cells. Mutations in the GR gene and nutritional deficiency of riboflavin, a co-factor required for the normal functioning of GR, can cause GR deficiency. We conducted a study on 1691 Saudi individuals to determine the overall frequency of GR deficiency and to identify whether the deficiency results from genetic or acquired causes or both. The activity of GR was measured in freshly prepared red cell haemolysate in the presence and absence of flavin adenine dinucleotide (FAD) and the activity coefficient (AC) was determined. Samples with low GR activity (> 2.0 IU/g haemoglobin) both in the presence and absence of FAD and an AC between 0.9 and 1.2 were considered GR-deficient. Samples with AC > or = 1.3 were considered riboflavin-deficient. The overall frequency of partial GR deficiency was 24.5% and 20.3% in males and females respectively. In addition, 17.8% of males and 22.4% of females suffered from GR deficiency due to riboflavin deficiency. This could be easily corrected by dietary supplementation with riboflavin. No cases of severe GR deficiency were identified.

Regular readers may recall something very similar with biotin and its enzyme biotinidase.  Biotinidase deficiency is supposedly such a rare metabolic disorder that it is no longer screened for; however, in an autism study in Crete, Greece it was found that partial biotinidase deficiency was quite common.

Glutathione peroxidase

Glutathione peroxidase (GPx) is the general name of an enzyme family with peroxidase activity whose main biological role is to protect the organism from oxidative damage.

The biochemical function of glutathione peroxidase is to reduce lipid hydroperoxides to their corresponding alcohols and to reduce free hydrogen peroxide to water.

In earlier posts on anti-oxidants we saw the following presentation from the German scientist.  Note Glutathione (GSH) peroxidases, left halfway down

Glutamate Cysteine Ligase (GCL)

  

Glutamate Cysteine Ligase (GCL) is the first enzyme of the cellular glutathione (GSH) biosynthetic pathway.

GSH, and by extension GCL, is critical to cell survival.

Nearly every eukaryotic cell, from plants to yeast to humans, expresses a form of the GCL protein for the purpose of synthesizing GSH

Dysregulation of GCL enzymatic function and activity is known to be involved in the vast majority of human diseases, such as diabetes, Parkinson's disease, Alzheimers disease, COPD, HIV/AIDS, and cancer. This typically involves impaired function leading to decreased GSH biosynthesis, reduced cellular antioxidant capacity, and the induction of oxidative stress.

Measuring GR, GPx, GCL in Autism

Fortunately somebody has already measured GR, GPx and GCL in autism, and not surprisingly they are all dysfunctional.  The paper is by the Chauhans, who already feature on my Dean’s list of researchers.

Impaired synthesis and antioxidant defense of glutathione in the cerebellum of autistic subjects: alterations in the activities and proteine xpression of glutathione-related enzymes.

In the cerebellum tissues from autism (n=10) and age-matched control subjects (n=10), the activities of GSH-related enzymes glutathione peroxidase (GPx), glutathione-S-transferase (GST), glutathione reductase (GR), and glutamate cysteine ligase (GCL) involved in antioxidant defense, detoxification, GSH regeneration, and synthesis, respectively, were analyzed. GCL is a rate-limiting enzyme for GSH synthesis, and the relationship between its activity and the protein expression of its catalytic subunit GCLC and its modulatory subunit GCLM was also compared between the autistic and the control groups. Results showed that the activities of GPx and GST were significantly decreased in autism compared to that of the control group (P<0.05). Although there was no significant difference in GR activity between autism and control groups, 40% of autistic subjects showed lower GR activity than 95% confidence interval (CI) of the control group. GCL activity was also significantly reduced by 38.7% in the autistic group compared to the control group (P=0.023), and 8 of 10 autistic subjects had values below 95% CI of the control group. The ratio of protein levels of GCLC to GCLM in the autism group was significantly higher than that of the control group (P=0.022), and GCLM protein levels were reduced by 37.3% in the autistic group compared to the control group. A positive strong correlation was observed between GCL activity and protein levels of GCLM (r=0.887) and GCLC (r=0.799) subunits in control subjects but not in autistic subjects, suggesting that regulation of GCL activity is affected in autism. These results suggest that enzymes involved in GSH homeostasis have impaired activities in the cerebellum in autism, and lower GCL activity in autism may be related to decreased protein expression of GCLM.

GCLM referred to above is Glutamate-cysteine ligase, it is the first rate limiting enzyme of glutathione synthesis, it is encoded by the GCLM gene. This is an enzyme/ gene you would want to upregulate.

https://en.wikipedia.org/wiki/GCLM

Fortunately we can upregulate GPx enzyme activity with catechin or epicatechin.

Effects of catechin and epicatechin on superoxide dismutase and glutathione peroxidase activity,  in vivo

  

Abstract

OBJECTIVES:

The objective of this study was to investigate the effects of catechin and epicatechin on the activity of the endogenous antioxidant enzymes superoxide dismutase (SOD) and glutathione peroxidase (GPx) (as well as the total antioxidant capacity (TAC)) of rats after intra-peritoneal (i.p.) administration.

METHODS:

Twenty-four Wistar rats were randomly divided into two groups: the experimental group which was administered daily with a 1:1 mixture of epicatechin and catechin at a concentration of 23 mg/kg body weight for 10 days and the control group which was injected daily with an equal amount of saline. Blood and urine samples were collected before and after the administration period, as well as 10 days after (follow-up).

RESULTS:

Intra-peritoneal administration of catechins led to a potent decrease in GPx levels and a significant increase in SOD levels. TAC was significantly increased in plasma and urine. Malonaldehyde levels in urine remained stable. In the animals treated with catechins, SOD activity showed a moderate negative correlation with GPx activity.

DISCUSSION:

Boosting the activity of the antioxidant enzymes could be a potential adjuvant approach for the treatment of the oxidative stress-related diseases.

The objective of this study was to determine whether i.p. administration of catechin and epicatechin could affect the activity of the antioxidant enzymes, SOD and GPx, as well as the TAC in RBCs, blood plasma, and urine.

The antioxidant enzymes are agents that promote reactions for the removal of reactive species (e.g. O2•,.H2O2, etc.). They constitute the first line of

defense against oxidative stress. In conditions of increased oxidative stress, the upregulation of the enzyme activity or even, a possible protection of the enzymes’ substrate could be of great importance.

Oxidative stress disturbing homeostasis can be resolved by the application of catechins and epigallocatechin gallate (EGCG)18 and there is growing evidence that, the protection, offered by flavonoids and their in vivo metabolites, is not mediated primarily by H-donating antioxidant processes, but is likely to be partly mediated through specific actions, within signaling pathways.

Catechin and epicatechin administration modulated the activity of SOD and GPx but the overall TAC of the RBCs and of the rat’s plasma remained stable.

Catechins are considered as potent antioxidants and many of their biological actions have been attributed to that. It would have been expected that since catechins are potent antioxidants in vitro, they would have exerted their classical hydrogen-donating antioxidant activity leading to an increase in TAC; as it is seen in the TAC of plasma. The modulation of the enzymes activity may provide evidence that, catechins exert their primary antioxidant activity by specific action within specific molecular pathways, rather than as scavengers of free radicals.

Oxidative stress is a prominent feature of many acute and chronic diseases and even of the normal aging process. The normal function of the antioxidant enzymes guarantees the preservation of cell integrity and thus they can be considered as potential therapeutic targets of oxidative stress-related diseases.

Various antioxidants are available for therapeutic use but most of them have failed in clinical studies of diseases correlated with oxidative stress. Our results suggest that catechins exert their activity not only by H-donating antioxidant processes but likely through mechanisms and pathways that directly or indirectly regulate the expression of the enzymatic antioxidants.

The understanding of these pathways could be important, in developing pharmacological strategies against oxidative stress-related diseases.

For those with autism plus GI issues / ulcerative colitis :- 

  

  

Epicatechin Used in the Treatment of Intestinal Inflammatory Disease: An Analysis by Experimental Models

Abstract

Background. This study was pathway of (−)-epicatechin (EC) in the prevention and treatment of intestine inflammation in acute and chronic rat models. Methods. Intestine inflammation was induced in rats using TNBS. The morphological, inflammatory, immunohistochemical, and immunoblotting characteristics of colon samples were examined. The effects of EC were evaluated in an acute model at doses of 5, 10, 25, and 50 mg/kg by gavage for 5 days. The chronic colitis model was induced 1st day, and treated for 21 days. For the colitis relapse model, the induction was repeated on 14th. Results. EC10 and EC50 effectively reduced the lesion size, as assessed macroscopically; and confirmed by microscopy for EC10. The glutathione levels were higher in EC10 group but decreased COX-2 expression and increased cell proliferation (PC) were observed, indicating an anti-inflammatory activity and a proliferation-stimulating effect. In the chronic colitis model, EC10 showed lower macroscopic and microscopic lesion scores and increase in glutathione levels. As in the acute model, a decrease in COX-2 expression and an increase in PC in EC10, the chronic model this increase maybe by the pathway EGF expression. Conclusion. These results confirm the activity of EC as an antioxidant that reduces of the lesion and that has the potential to stimulate tissue healing, indicating useful for preventing and treating intestine inflammation.

Inhibition of ulcerative colitis in mice after oral administration of a polyphenol-enriched cocoaextract is mediated by the inhibition of STAT1 and STAT3 phosphorylation incolon cells.

Abstract

We studied a polyphenol-enriched cocoa extract (PCE) with epicatechin, procyanidin B2, catechin, and procyanidin B1 as the major phenolics for its anti-inflammatory properties against dextran sulfate sodium (DSS)-induced ulcerative colitis (UC) in mice. PCE reduced colon damage, with significant reductions in both the extent and the severity of the inflammation as well as in crypt damage and leukocyte infiltration in the mucosa. Analysis ex vivo showed clear decreases in the production of nitric oxide, cyclooxygenase-2, pSTAT-3, and pSTAT1α, with NF-κB p65 production being slightly reduced. Moreover, NF-κB activation was reduced in RAW 264.7 cells in vitro. In conclusion, the inhibitory effect of PCE on acute UC induced by DSS in mice was attenuated by oral administration of PCE obtained from cocoa. This effect is principally due to the inhibition of transcription factors STAT1 and STAT3 in intestinal cells, with NF-κB inhibition also being implicated.

 Here is an excellent paper on oxidative stress.  It is about COPD, but applicable to any condition in which oxidative stress is present.

Oxidative stress and free radicals in COPD – implications and relevance for treatment

  

The following paper would suggest that people with COPD would benefit from epicatechin.

The cocoa flavanol (-)-epicatechin protects the cortisol response.

Abstract

Various health benefits of the cocoa flavanol (-)-epicatechin (EC) have been attributed to its antioxidant and anti-inflammatory potency. In the present study we investigated whether EC is able to prevent deterioration of the anti-inflammatory effect of the glucocorticoid (GC) cortisol in the presence of oxidative stress. It was found that cortisol reduces inflammation in differentiated monocytes. Oxidative stress extinguishes the anti-inflammatory effect of cortisol, leading to cortisol resistance. EC reduces intracellular oxidative stress as well as the development of cortisol resistance. This further deciphers the enigmatic mechanism of EC by which it exerts its anti-inflammatory and antioxidant action. The observed effect of the cocoa flavanol EC will especially be of relevance in pathophysiological conditions with increased oxidative stress and consequential GC resistance and provides a fundament for the rational use of dietary antioxidants.

Conclusion

It would seem that in someone with autism epicatechin is worth a try, other indicators might well include:-

·        Low MOCOS

·        Low ferritin

·        Oxidative stress

And even

·        Restless leg syndrome (symptom of low ferritin)

·        Poor sleep patterns (symptom of low ferritin)

Boosting anti-oxidant enzymes (via gene expression) may be a useful add-on therapy to anti-oxidants themselves.  This is likely true for COPD and autism/schizophrenia.

If you are wondering whether there is anemia or iron deficiency in autism, your questions are likely answered here:-

Iron deficiency in autism and Asperger syndrome.

This research considers the prevalence of iron deficiency in children with autism and Asperger syndrome and examines whether this will influence guidelines and treatment. Retrospective analysis of the full blood count and, as far as available, serum ferritin measurements of 96 children (52 with autism and 44 with Asperger syndrome) was undertaken. Six of the autistic group were shown to have iron deficiency anaemia and, of the 23 autistic children who had serum ferritin measured, 12 were iron deficient. Only two of the Asperger group had iron deficiency anaemia and, of the 22 children who had their serum ferritin measured, only three were iron deficient. Iron deficiency, with or without anaemia, can impair cognition and affect and is associated with developmental slowing in infants and mood changes and poor concentration in children. This study showed a very high prevalence of iron deficiency in children with autism, which could potentially compromise further their communication and behavioural impairments.

As we saw with biotin and soon will with vitamin B12, it seems that people with autism can have unexpected deficiencies of key substances even though their diet may not be deficient.  The identified iron deficiency is an iron storage deficiency.  With biotin the body was unable to recycle the vitamin biotin, due to a problem with the enzyme biotinidase, hence there was a deficiency.

Correcting these deficiencies is quite simple and may well improve any related autism symptoms.  In people without these dysfunctions/deficiencies any such supplements would yield no benefit and might even produce side effects.

Activated Microglia and Inflammation in Autism

There have been yet more autism studies recently, highlighting neuroinflammation and the role of cells called microglia.  The result is this rather long post; but there is film to watch, if it gets heavy going.

Glia derives from a Greek word for glue. The original thought was that the glial cells “glued” the neurons together.

It turned out that glial cells do very much more and might be better thought of as “resident immune cells”.  They have other functions including synaptic pruning, which appears to have gone awry in autism.  They also form myelin, and when this goes wrong, big problems follow.

Microglia are inside the blood brain barrier and one of their jobs is to swallow up any foreign bodies that should not be there, before they can do damage.  It appears that this process is mainly modulated via potassium channels.  The majority of research focuses on the calcium-activated K⁺ channels, particularly KCNN4/KCa2 and 3.1, and ATP-sensitive K⁺ channels (K_ATP).  Administration of diazoxide, a classic K_ATP channel activator, is shown to reduce microglial activation and is neuroprotective in a variety of models involving neuroinflammation. 

However, K_v 1.3 and K_v 1.5 are also involved in activated glia.  We have seen in earlier posts, that blocking K_v 1.3 can be effective in autism (remember those TSO worms).

Immunomodulatory Therapy in Autism - Potassium Channel Kv1.3, Parasitic Worms, and their ShK–related peptides

For the scientists among you:-

Microglial Ion Channels as Potential Targets for Neuroprotection in Parkinson’s Disease

Protective Roles for Potassium SK/KCa2 Channels in Microglia and Neurons

Synaptic pruning

A very small Acer Palmatum

Synaptic pruning could itself be the subject of an entire blog.  I will just use the analogy of a different kind of pruning.

With ornamental trees, to obtain the perfect form, pruning is very important.  You have to clear away the dead wood and encourage growth in particular areas to achieve the optimal shape.  You need to know when to cut, where to cut and how much to cut.

The human brain develops with far too many synapses and they too need pruning.  The weak ones need to give way for the strong ones to prosper.  Too many synapses lead to poor brain function.  This process is going on from childhood to early adulthood.  Microglia are heavily involved in this pruning process, as you will see in the video shortly.

We know that synaptic pruning is implicated in autism and very likely in its big brother, schizophrenia.

Impaired Synapse 'Pruning'Linked to Autism

Activation of Microglia

Microglia can be in either a resting or activated state. In the activated state, for no good reason, they can do damage.  They can also react with mast cells to produce more inflammation.

(here is a link for the mast cell followers of Theoharides; they know who they are)

Dysregulated Brain Immunity and Neurotrophin Signaling in Rett Syndrome and Autism Spectrum Disorders

The subject is very complex.  For those with an hour to spare there is an excellent presentation by Beth Stevens from Harvard.  Click on the link below to go to the SFARI website and the video.

http://sfari.org/sfari-community/community-blog/webinar-series/2013/webinar-beth-stevens-discusses-brain-immunity-and-wiring

By a bizarre coincidence, there is another B Stevens researching glial cells and autism.  This time it is Bruce Stevens, in Florida.

His paper is interesting because he is using a known anti-oxidant (alpha lipoic acid, ALA) to affect brain glial cells.

One of the odd things is that we know in autism there is both oxidative stress and neuro-inflammation; they are a self-perpetuation combination.  There are numerous effective anti-oxidants; almost too many.  There is, however, a paucity of effective, safe, anti-inflammatory drugs.  In fact the best anti-inflammatory drug is probably an anti-oxidant.  So called Reactive Oxygen Species (ROS) are among the biggest causes of neuroinflammation.  With anti-oxidants you can neutralize the ROS, and thereby you take a big bite out of the neuroinflammation.

  

Alpha-lipoic acid effects on brain glial functions accompanying double-stranded RNA antiviral and inflammatory signaling.

Abstract

Double-stranded RNAs (dsRNA) serve as viral ligands that trigger innate immunity in astrocytes and microglial, as mediated through Toll-like receptor 3 (TLR3) and dsRNA-dependent protein kinase (PKR). Beneficial transient TLR3 and PKR anti-viral signaling can become deleterious when events devolve into inflammation and cytotoxicity. Viral products in the brain cause glial cell dysfunction, and are a putative etiologic factor in neuropsychiatric disorders, notably schizophrenia, bipolar disorder, Parkinson's, and autism spectrum. Alpha-lipoic acid (LA) has been proposed as a possible therapeutic neuroprotectant. The objective of this study was to test our hypothesis that LA can control untoward antiviral mechanisms associated with neural dysfunction. Utilizing rat brain glial cultures (91% astrocytes:9% microglia) treated with PKR- and TLR3-ligand/viral mimetic dsRNA, polyinosinic-polycytidylic acid (polyI:C), we report in vitro glial antiviral signaling and LA reduction of the effects of this signaling. LA blunted the dsRNA-stimulated expression of IFNα/β-inducible genes Mx1, PKR, and TLR3. And in polyI:C treated cells, LA promoted gene expression of rate-limiting steps that benefit healthy neural redox status in glutamateric systems. To this end, LA decreased dsRNA-induced inflammatory signaling by downregulating IL-1β, IL-6, TNFα, iNOS, and CAT2 transcripts. In the presence of polyI:C, LA prevented cultured glial cytotoxicity which was correlated with increased expression of factors known to cooperatively control glutamate/cysteine/glutathione redox cycling, namely glutamate uptake transporter GLAST/EAAT1, γ-glutamyl cysteine ligase catalytic and regulatory subunits, and IL-10. Glutamate exporting transporter subunits 4F2hc and xCT were downregulated by LA in dsRNA-stimulated glia. l-Glutamate net uptake was inhibited by dsRNA, and this was relieved by LA. Glutathione synthetase mRNA levels were unchanged by dsRNA or LA. This study demonstrates the protective effects of LA in astroglial/microglial cultures, and suggests the potential for LA efficacy in virus-induced CNS pathologies, with the caveat that antiviral benefits are concomitantly blunted. It is concluded that LA averts key aspects of TLR3- and PKR-provoked glial dysfunction, and provides rationale for exploring LA in whole animal and human clinical studies to blunt or avert neuropsychiatric disorders

The obvious question is whether other antioxidants have the same effect.  Most likely nobody knows.  I did ask both B Stevens #1 and B Stevens #2 for their thoughts on this – so far no answer.

Brain inflammation a hallmark of autism, according to large-scale analysis

Finally to the subject of this post, the recent Johns Hopkins study that shows inflammation in the autistic brain.

This is the press release from Johns Hopkins so it is quite readable.

While many different combinations of genetic traits can cause autism, brains affected by autism share a pattern of ramped-up immune responses, an analysis of data from autopsied human brains reveals. The study, a collaborative effort between Johns Hopkins and the University of Alabama at Birmingham, included data from 72 autism and control brains. It was published online today in the journal Nature Communications.

“There are many different ways of getting autism, but we found that they all have the same downstream effect,” says Dan Arking, Ph.D., an associate professor in the McKusick-Nathans Institute for Genetic Medicine at the Johns Hopkins University School of Medicine. “What we don’t know is whether this immune response is making things better in the short term and worse in the long term.”

The causes of autism, also known as autistic spectrum disorder, remain largely unknown and are a frequent research topic for geneticists and neuroscientists. But Arking had noticed that for autism, studies of whether and how much genes were being used — known as gene expression — had thus far involved too little data to draw many useful conclusions. That’s because unlike a genetic test, which can be done using nearly any cells in the body, gene expression testing has to be performed on the specific tissue of interest — in this case, brains that could only be obtained through autopsies.

To combat this problem, Arking and his colleagues analyzed gene expression in samples from two different tissue banks, comparing gene expression in people with autism to that in controls without the condition. All told, they analyzed data from 104 brain samples from 72 individuals — the largest data set so far for a study of gene expression in autism.

Previous studies had identified autism-associated abnormalities in cells that support neurons in the brain and spinal cord. In this study, Arking says, the research team was able to narrow in on a specific type of support cell known as a microglial cell, which polices the brain for pathogens and other threats. In the autism brains, the microglia appeared to be perpetually activated, with their genes for inflammation responses turned on. “This type of inflammation is not well understood, but it highlights the lack of current understanding about how innate immunity controls neural circuits,” says Andrew West, Ph.D., an associate professor of neurology at the University of Alabama at Birmingham who was involved in the study.

Arking notes that, given the known genetic contributors to autism, inflammation is unlikely to be its root cause. Rather, he says, “This is a downstream consequence of upstream gene mutation.” The next step, he says, would be to find out whether treating the inflammation could ameliorate symptoms of autism.

The full study is here:-

Transcriptome analysis reveals dysregulation of innate immune response genes and neuronal activity-dependent genes in autism

What I liked about the study was the comment made by Arking, a specialist in genetics, that it did not seem to matter what the genetic cause was, all the brain samples exhibited the same inflammation.  So it does not matter which of millions of possible combinations of genetic dysfunction is present, one key physiological result is shared neuroinflammation.

Take home message:  Treat the neuroinflammation in people with Autism.

The question of course is how.

Since it seems easy to treat oxidative stress, a leading cause of neuroinflammation, we should go to extreme lengths to finish that job. 

I started it with NAC and recently added Sulforaphane/broccoli.  I suspect there are more “low hanging fruit” to be gathered here. Perhaps just an additional supplemental (exogenous) antioxidants, or perhaps something clever like increasing the amount DJ-1, which is needed to support Nrf2 which turns on the anti-oxidant genes. Early 2015 will see my oxidative stress therapy optimized.

Treating Neuroinflammation in Autism

There are lots of possible ways to treat neuroinflammation, some of which we have already covered in this blog.  Sometimes it gets called immunomodulatory therapy.

There are some natural options like quercetin and turmeric.  Turmeric is also possibly chemo-protective:-

“Currently there is no research evidence to show that turmeric or curcumin can prevent or treat cancer but early trials have shown some promising results.”

Cancer Research UK

Interestingly, people who eat a lot of curry (Indians) have a very low incidence of cancer.

1.     Steroids, like Prednisone

These are already used, particularly in regressive autism.  They are potent, but have side effects.

2.     Blockers of Potassium channel Kv1.3

This is a clever approach, since it appears that this potassium channel is involved in mediating the inflammatory response. By blocking these channels the response we have seen that the immune response can be moderated and in some people, there autism moderated.

3.     Activators of Potassium channel K_ATP

We learned earlier in this post about diazoxide

4.     Other Microglial Ion Channels

The various other potassium, calcium and sodium channels need to be considered.

5.     Ibuprofen

This common painkiller reduces inflammation and is used to reduce inflammation associated with autism secondary to mitochondrial disease.

Do not use acetaminophen/paracetamol/Tylenol.  These will increase oxidative stress, since it depletes GSH and also affect mitochondria.

6.     Leukotriene receptor inhibitors (i.e. montelukast, zafirlukast)

These are interesting because they are used to treat asthma and so are very widely used. They are not steroids and so do not have their side effects.  They are proved to have anti-inflammatory effects.

Montelukast/Zafirlukast is used to reduce inflammation associated with autism secondary to mitochondrial disease.

7.     Pregnenolone

I wrote a post a while back on Pregnenolone, which is interesting, since you do not need a prescription.  But does it work?

Well, after I wrote the post below, the results from a clinical trial in adults with autism was finally published.

Pregnenolone - an effective OTC anti-inflammatory therapy for autism?

Brief report: an open-label study ofthe neurosteroid pregnenolone in adults with autism spectrum disorder.

Abstract

The objective of this study was to assess the tolerability and efficacy of pregnenolone in reducing irritability in adults with autism spectrum disorder (ASD). This was a pilot, open-label, 12-week trial that included twelve subjects with a mean age of 22.5 ± 5.8 years. Two participants dropped out of the study due to reasons unrelated to adverse effects. Pregnenolone yielded a statistically significant improvement in the primary measure, Aberrant Behavior Checklist (ABC)-Irritability [from 17.4 ± 7.4 at baseline to 11.2 ± 7.0 at 12 weeks (p = 0.028)]. Secondary measures were not statistically significant with the exception of ABC-lethargy (p = 0.046) and total Short Sensory Profile score (p = 0.009). No significant vital sign changes occurred during this study. Pregnenolone was not associated with any severe side effects. Single episodes of tiredness, diarrhea and depressive affect that could be related to pregnenolone were reported. Overall, pregnenolone was modestly effective and well-tolerated in individuals with ASD.

Trial doses were:-

Days 1-14: 100 mg

Week 1 and 2: 200 mg

Week 3 and 4: 350 mg

Week 5 and 6: 400 mg

Week 7 -12: 500 mg

So it was modestly effective, but the doses were huge.  It is a hormone and our endocrinologist did not much approve of the idea.

I will give this idea a miss.

8.     Statins

The current treatment for neuroinflammation in my Polypill is Atorvastatin.

I have already written a great deal about why statins may be effective in some people with autism; just make sure you do not have low cholesterol or mitochondrial disease.

Arthritis is another disease mediated by inflammation:-

Statin treatment for rheumatoid arthritis: a promising novel indication

To me it is no surprise that statins have therapeutic value in rheumatoid arthritis.

9.     NF-κB inhibitors

Because NF-κB controls many genes involved in inflammation, it is not surprising that NF-κB is found to be chronically active in many inflammatory diseases, such as inflammatory bowel disease, arthritis, sepsis, gastritis, asthma, atherosclerosis and others.

So perhaps NF-κB is for inflammation ,what Nrf2 is for oxidative stress, a force multiplier?

There are very many other inflammatory diseases like rheumatoid arthritis and so it is quite a well-trod path looking for inhibitors of NF-κB.

Before we get into that, a quick check on what we already know from research to schizophrenia (adult-onset autism).

The interaction of nuclear factor-kappa B (NF-κB) and cytokines is associated with schizophrenia. 

Abstract

BACKGROUND:

Many reports suggest that schizophrenia is associated with the inflammatory response mediated by cytokines, and nuclear factor-kappa B (NF-kappaB) regulates the expression of cytokines. However, it remains unclear whether the interaction between NF-kappaB and cytokines is implicated in schizophrenia and whether the effect of neuroleptics treatment for 4 weeks is associated with the alteration of cytokines.

METHODS:

Sixty-five healthy subjects and 83 first-episode schizophrenic patients who met DSM-IV criteria and who were never treated with neuroleptics previously were included. Serum levels of cytokines such as interleukin-1beta (IL-1beta) and tumor necrosis factor-alpha (TNF-alpha) were examined by using sandwich enzyme immunoassay (EIA). Peripheral blood mononuclear cell (PBMC) mRNA expressions of cytokines (IL-1beta, TNF-alpha) and NF-kappaB were detected by using semiquantitative reverse transcription polymerase chain reaction (RT-PCR). NF-kappaB activation was examined by using transcription factor assay kits.

RESULTS:

Schizophrenic patients showed significantly higher serum levels and PBMC mRNA expressions of IL-1beta and TNF-alpha compared with healthy subjects. However, treatment with the neuroleptic risperidone for 4 weeks significantly decreased serum levels and PBMC mRNA expressions of IL-1beta in schizophrenic patients. NF-kappaB activation and PBMC mRNA expression in patients were significantly higher than those in healthy subjects. Furthermore, PBMC mRNA expressions of IL-1beta and TNF-alpha were positively correlated to NF-kappaB activation in both schizophrenic patients and healthy control subjects.

CONCLUSIONS:

Schizophrenic patients showed activation of the cytokine system and immune disturbance. NF-kappaB activation may play a pivotal role in schizophrenia through interaction with cytokines.

It seems fair to conclude that NF-κB inhibitors are well worth investigating.

Interestingly, one of my new “pet” compounds, alpha lipoic acid appears to have another role here:-

Evidence that α-lipoic acid inhibitsNF-κB activation independent of its antioxidant function.

Abstract

OBJECTIVE:

α-Lipoic acid (LA) exerts beneficial effects in cardiovascular diseases though its antioxidant and/or anti-inflammatory functions. It is postulated that the anti-inflammatory function of LA results from its antioxidant function. In this study we tested whether inhibition of NF-κB by LA is dependent on its antioxidant function.

METHODS:

Human umbilical vein endothelial cells (HUVECs) were treated with tumor necrosis factor-α (TNFα) in the presence of various antioxidants, including LA, tiron, apocynin, and tempol. The activation of the nuclear factor-κB (NF-κB) signaling pathway was then analyzed.

RESULTS:

LA, but not other tested antioxidants, inhibited TNFα-induced inhibitor-kappaB-α (IκBα) degradation and VCAM-1 and COX2 expression in HUVECs. Although LA activated the phosphatidylinositol-3-kinase (PI3-kinase)/Akt pathway in HUVECs, inhibition of Akt by LY294002 did not affect inhibition of TNFα-induced IκBα degradation by LA. In transient co-transfection assays of a constitutively active mutant of IκB kinase-2 (IKK2), IKK2(EE), and a NF-κB luciferase reporter construct, LA dose-dependently inhibited IKK2(EE)-induced NF-κB activation in addition to inhibiting IKK activity in in vitro assays. Consistent with the effect on luciferase expression, LA inhibited IKK2(EE)-induced cyclo-oxygenase-2 (COX2) expression, suggesting that IKK2 inhibition by LA may be a relevant mechanism that explains its anti-inflammatory effects.

CONCLUSIONS:

LA inhibits NF-κB activation through antioxidant-independent and probably IKK-dependent mechanisms.

 

This really makes ALA look very interesting.  It is cheap, widely available and well tolerated.

10.       Low Dose Naltrextone                       

Your local doctor will probably tell you that Low Dose Naltrexone (LDN) is a load of quack nonsense, partly because it is claimed to help so many unrelated disorders.

I would not have questioned that opinion, before I had started by investigation into the biology of the brain and seen how many apparently unrelated conditions are actually interrelated.  This can be established by science, not quackery.

First to note is that tiny doses of some substances do indeed sometimes have effects quite different to large doses.

We saw earlier how a tiny stimulation of the body’s nicotinic receptors produces a different effect to a large dose.

My own experience showed that a tiny, but specific, dose of Clonazepam has a marked effect, whereas conventional medical wisdom would say such a small dose would do absolutely nothing.  In this case, I was just following the clever idea of Professor Catterall, from the University of Washington.

I also found that tiny doses of a TRH analog had a positive effect and quite different to the “regular” dose.

The advocates of LDN suggest it for conditions including Crohn's disease, fibromyalgia and multiple sclerosis (MS).  As I mentioned earlier in this blog, some Fibromyalgia appears to be a condition that was almost autism; perhaps the final hit, in a multiple-hit process failed to occur.  Crohn’s is an immune disease and is a type of inflammatory bowel disease (IBD).  MS is an inflammatory disease in which the insulating covers of nerve cells in the brain and spinal cord are damaged.

Preliminary research suggests LDN may have an effect on inflammation. Naltrexone has an antagonistic effect on Toll-like receptor 4 (TLR4), which are found on microglia, which can modulate the body's response to inflammation. It has been hypothesized that LDN may have anti-inflammatory effects through this pathway.

  

Conclusion

The immediate conclusion is that there are plenty of ways, already existing, that might very well help reduce neuroinflammation in autism.  They just requires a little further thought and investigation.

The broader conclusion here is about the merit of genetic testing.

Undoubtedly, if you could analyze the entire genome in a person with autism and also measure the expression of those suspect genes in the brain, you would gain a great deal of information.  In a few cases, where there is a single gene causing the “autism”, you might well be able to figure out a therapy.

You cannot take brain biopsies from living people.  We did come across that clever Ricardo Dolmetsch, growing brain samples from skin cells.  He has now moved over to the private sector.

Future Science - Accurate Diagnosis of Autism Phenotype using Brain Biopsies grown from Skin Cells

So for the moment genetic testing will just generate a vast amount of data, that in many cases will not be of any immediate clinical relevance.

The good news, as pointed out by Dan Arking, from Johns Hopkins, is that many of these numerous, unrelated, genetic dysfunctions end up with the same biological manifestations.

There may be thousands, or even millions of combinations, of genetic dysfunctions that lead to autism with neuro-inflammation.

You can go ahead and treat the neuro-inflammation, without any knowledge of exactly which gene has which SNP (single nucleotide polymorphisms)  or who had what CNV (copy number variant).

For me, the identification of so-called autism genes like PTEN and BCL2 is interesting, as are the single gene causes of autism.  We can then see that a reduced expression of that gene might contribute to autism, caused by multiple gene dysfunction (multiple-hits).  For the great majority of people with ASD, they have had multiple-hits.

I read Ricardo Dolmetsch’s Stanford research into Timothy syndrome, which is caused just by one gene, albeit a very important one.  I considered that perhaps a partial dysfunction might occur, leading to disturbance in the protein expressed by this gene.  I had no idea whether in my son this dysfunction existed, whether it might be caused by a SNP (there are several known ones) or if a dysfunction was caused as a consequence of a metabolic disruption caused by autism, such as oxidative stress or neuroinflammation,  affecting the function of an undamaged gene.

It did not matter; I just carried on and did a little practical test.  This led me to include Verapamil in my Polypill.  No genetic testing was required.

It was suggested to me that genetic testing might help point me in the right direction.  I think it would likely point me in all directions.  We all carry many genetic errors, and most of us thrive regardless, so most genetic errors are irrelevant.

The clever future diagnostic tool is proteomics.

  

Clusters

From now, I will consider autism in terms of a manageable group of clusters.  Once you know, based on symptoms and some measurable biomarkers, which cluster you are in, you would have a good chance of predicting which drugs would be effective.

The underlying genetic causes may, or may not, overlap with other people in that cluster.

Some clusters may overlap. Note the case of siblings with autism, when one is early onset and the other is regressive.  Was the regressive one really symptom free early one? Or, was it just a second hit nudged him “over the edge” and then people noticed?

This would be a practical approach that could be used.  I think when people talk of phenotypes and autisms, they are thinking about very precise biological causes and then it just becomes too complicated to expect your local doctor to ever figure out.

90+% of people quite probably fit into a handful of clusters.  Then you just need a diagnostic flowchart leading to the relevant cluster and then a specific drug toolkit.

My Polypill is the drug toolkit for one cluster; and it is not a rare one.