A RORα Agonist for Autism?

Today’s post is again about RORα, which was suggested to be a nexus where different biological dysfunctions that lead to autism may converge. I think you can consider RORα like a dimmer switch on your lights, you need to adjust the brightness to give the effect you want.

Fine tuning RORα to tune autism gene expression

I recently came across some research where the scientist clearly has the same idea. He has been working on a synthetic RORα/γ agonist for some years and has investigated its use as both a cancer therapy and an autism therapy.

I have become rather interested in cancer therapies because there are so many overlaps between what can lead to cancer and what exists in autism. The big research money is of course in cancer research.

Tumor suppressor genes/proteins like PTEN and p53 have been shown to be disturbed in autism, as is Bcl-2. The Bcl-2 family of proteins regulate cell death (apoptosis); some members induce cell death and other inhibit it; the balance is important.

Generally it seems that most people with autism might benefit from more PTEN and Bcl-2. 

Therapeutic Effect of a Synthetic RORα/γ Agonist in an Animal Model of Autism  

Autism is a developmental disorder of the nervous system associated with impaired social communication and interactions as well excessive repetitive behaviors. There are no drug therapies that directly target the pathology of this disease. The retinoic acid receptor-related orphan receptor α (RORα) is a nuclear receptor that has been demonstrated to have reduced expression in many individuals with autism spectrum disorder (ASD). Several genes that have been shown to be downregulated in individuals with ASD have also been identified as putative RORα target genes. Utilizing a synthetic RORα/γ agonist, SR1078, that we identified previously, we demonstrate that treatment of BTBR mice (a model of autism) with SR1078 results in reduced repetitive behavior. Furthermore, these mice display increased expression of ASD-associated RORα target genes in both the brains of the BTBR mice and in a human neuroblastoma cell line treated with SR1078. These data suggest that pharmacological activation of RORα may be a method for treatment of autism. 

The RORs have been linked to autism in human in several studies. In 2010, Nguyen and co-workers reported that RORα protein expression was significantly reduced in the brains of autistic patients and this decrease in expression was attributed to epigenetic alterations in the RORA gene.¹⁵ Additional work from this group demonstrated that multiple genes associated with autism spectrum disorder are direct RORα target genes and suggested that reduction of RORα expression results in reduced expression of these genes associated with the disorder leading to the disease.¹⁶ Independently, Devanna and Vernes demonstrated that miR-137, a microRNA implicated in neuropsychiatric disorders, targets a number of genes associated with autism spectrum disorder including RORA.¹⁷ There are also additional links between RORα and autism. Deficiency of Purkinje cells is one of the most consistently identified neuroanatomical abnormalities in brains from autistic individuals^18,19 and RORα is critical in development of the Purkinje cells.²⁰⁻²³ Significant circadian disruptions have also been recognized in autistic patients,²⁴⁻²⁷ and RORs play a critical role in regulation of the circadian rhythm.^7,28 Additionally, the staggerer mouse displays behaviors that are associated with autism including abnormal spatial learning, reduced exploration, limited maze patrolling, and perseverative behavior relative to wt mice.²⁹⁻³³

SR1078 is a relatively low potency compound with limited RORα efficacy (3–5 μM EC₅₀E_max ∼ 40%),⁸ but the efficacy compares favorably to other classes of compounds that have been optimized such as a 38% decrease in the same model induced by the mGluR5 allosteric modulator GRN-529⁴⁹ and a 47% reduction by the mGluR5 antagonist MPEP.⁴⁵ Both of these compounds have been optimized and display high potency (single digit nanomolar range at mGluR5) and strong efficacy.^53,54 Thus, we believe that focused optimization of RORα ligands will provide compounds that will have improved efficacy in this model. It should also be noted that SR1078 has both RORα and RORγ agonist activity⁸ and a RORα selective agonist has not yet been developed. Thus, it is possible that the RORγ activity of this compound may also play a role in its efficacy in this model of autism. In summary, we have demonstrated that a synthetic RORα/γ agonist is able to increase the expression of key genes whose decrease in expression is associated with ASD both in cell culture and in vivo. Furthermore, the agonist decreases repetitive behavior in an animal model of autism suggesting that it is possible that ROR agonists may hold utility in treatment ASD. 

Regulation of p53 Stability and Apoptosis by a ROR Agonist

Activation of p53 function leading to cell-cycle arrest and/or apoptosis is a promising strategy for development of anti-cancer therapeutic agents. Here, we describe a novel mechanism for stabilization of p53 protein expression via activation of the orphan nuclear receptor, RORα. We demonstrate that treatment of cancer cells with a newly described synthetic ROR agonist, SR1078, leads to p53 stabilization and induction of apoptosis. These data suggest that synthetic ROR agonists may hold utility in the treatment of cancer.  

Levels of Bcl-2 and P53 Are Altered in Superior Frontal and Cerebellar Cortices of Autistic Subjects 

Results showed that levels of Bcl-2 decreased by 38% and 36% in autistic superior frontal and cerebellar cortices, respectively when compared to control tissues. By the same token, levels of P53 increased by 67.5% and 38% in the same brain areas in autistic subjects vs. controls respectively. Calculations of ratios of Bcl-2/P53 values also decreased by 75% and 43% in autistic frontal and cerebellar cortices vs. controls respectively. The autistic cerebellar values were significantly reduced (p < 0.08) vs. control only. There were no significant differences in levels of β-actin between the two groups. Additionally, there were no correlations between Bcl-2, P53, and β-actin concentrations vs. age or PMI in either group.

These results confirm and extend previous data that levels of Bcl-2 and P53 are altered in three important brain tissues, i.e. frontal, parietal, and cerebellar cortices of autistic subjects, alluding to deranged apoptotic mechanisms in autism.  

Conclusion

Increasing PTEN and Bcl-2 is already part of my Polypill, via the use of Atorvastatin.

There are of course many other genes miss-expressed in autism and we cannot give a drug for each one. We need to identify a handful of nexus, where multiple anomalies can be resolved with a single intervention.

It is good that Thomas Burris, the lead researcher, has been working on SR1078 for at least 6 years, let’s hope he continues to persevere.

I think it highly likely that some types of autism will need the opposite therapy, a RORα antagonist.

My method of attempting to modulate RORα will be different. I come back to my earlier gross simplification of autism :- 

As we have seen in earlier posts, the hormonal dysfunction, this time the balance between testosterone and estradiol, has a direct effect on RORα (and vice versa).

The schematic illustrates a mechanism through which the observed reduction in RORA in autistic brain may lead to increased testosterone levels through downregulation of aromatase. Through AR, testosterone negatively modulates RORA, whereas estrogen upregulates RORA through ER.

androgen receptor = AR 

estrogen receptor = ER

As you might know, many hormones are interrelated, so what are thought of as male/female sex hormones have much wider effects. They impact growth hormones and play a big role in calcium metabolism. They also affect serotonin.

We know that in most autism aromatase is reduced, estradiol is reduced and that there is reduced expression of estrogen receptor beta.

In the ideal world it might indeed be best to use an agonist or antagonist to fine tune RORα.

We have a chicken and the egg situation. Is RORα out of tune in autism because the hormones are disturbed, or vice versa?

We do know that hormones generally have feedback loops, but we also know that increasing a hormone like estradiol via obesity is not fully matched by a corresponding reduction in aromatase. So it looks highly plausible that you can tune RORα via estradiol, and that this could be a long term strategy, not just a short term strategy.

In the case of people with low T3 thyroid hormone centrally (in the brain), giving exogenous T3 may help initially, but in the long term it does not because feedback loops to the thyroid will reduce production of the pro-hormone T4. In the extreme you will make the thyroid gland shut down, this does happen to people using thyroid hormones for depression and even weight loss. 

T3 is quite commonly prescribed by alternative practitioners in the US for autism and also for depression in older people. In Europe this hormone is rarely even available. 

Many phytoestrogens are used as OTC autism therapies. These are dietary estrogens that are structurally similar to the human hormone estradiol and so produce estrogen-like effects. They include soy products, fenugreek, kudzu, EGCG etc.

Treated ID and CBS/DYRK1A in Autism and Down Syndrome

One of the most interesting concepts I have come across writing this blog is the idea of treating people with mental retardation (MR) / intellectual disability (ID). I do keep using the term MR, because 90% of the world has no idea what ID means. MR is a very precise description, which is increasingly rare these days.

I still recall several years ago going to a French-speaking neighbour’s barbecue. The French are generally very family-oriented, but quite traditional when it comes to parenting, (hence their low rates of ADHD diagnosis). At that time, Monty aged around 8, could act strangely and was rather obsessed with fire, matches and cigarette lighters. Our neighbour introduced us to his French friends and explained Monty with a brief use of the word “retardé”, which did not prompt any comments or requests for clarification. In the English language this might have been regarded as a big faux-pas; it did not bother me.  It seemed to work very well to forewarn people not to over-react to any unexpected behaviours. 

In the English language, autism has become a nice word and seems the new ADHD, with people even wanting to be diagnosed with it.  MR/ID is still something reserved for other people; it is not something most people want to be associated with. I do use the term cognitive dysfunction, which is just as explicit as MR but does not seem to upset people.

Cognitive dysfunction (MR/ID) is an inevitable consequence of more severe autism and it is just a question of degree. It is not a comorbidity, it is all part of the same package.

In Down Syndrome (DS) IQ is usually between 45 and 71 and worsens with age. MR/ID is defined as an IQ less than 70 and accounts for 2.3% of the general population. An IQ of 100 would put you in the middle of the IQ bell curve. People with DS tend to be very happy and contented, without the problematic behaviors that can occur in autism. 

The good news is that cognitive dysfunction (MR/ID) is likely to be treatable, as some readers of this blog have discovered. You just need to figure out how, which in itself is more about your perseverance than your IQ. You do not need to be an Einstein (IQ > 160), rather a marathon runner.

I just had the uncanny experience at school during the parent-teacher meetings, to be told that other class members could learn from my younger son Monty, aged 14 with autism; that he has the neatest handwriting in class, his essay had the best structure and that when his geography teacher told his assistant to skip the final question in the test (using longitude and latitude) because it was hard, the assistant said just let him try it; he was the only one to get it right. 

So from aged 8 to 14 he has gone from “retardé” to being something quite different.  The teachers do love his assistants, who are great; but he has had an assistant from the age of 4 and back then things moved forward extremely slowly. He learnt to read and write the very hard way, with a vast amount of 1:1 instruction and the school was amazed when his then assistant taught him to read; I don’t think they expected it ever to happen. By treating cognitive dysfunction pharmacologically for five years normal learning became possible and remains a big surprise to everyone.  His new English teacher knows him from back in the darker old days and seemed more shocked than surprised, after a month of teaching him. "Is this the same boy?"

For the first time at school I am being told to be proud of my younger son’s academic achievements, rather than how talented my older son is. Big brother certainly did not expect such a day and his response was along the lines of “well the others in his class must be really thick then” (like it or not, this is a typical teenage male comment). Little brother still has autism, but it is much less disabling. Big brother is currently teaching him to fence (sword fighting), which he would not have bothered to try doing until recently, because it would not have ended well. Years ago Monty did learn to ski, play basketball and soccer, but that all took a lot of effort with very patient (mostly female) instruction; he initially had no idea what to do if a ball was rolled towards him.  Last week he happily sat through the new Blade Runner film, which is nearly three hours long with the trailers. 

Perhaps there is no need for further “breakthroughs” with my Polypill therapy.  It may be good enough already.

It just seems a pity that more people with cognitive dysfunctions are not treated. There are some extremely intelligent parents with children who have severe autism, indeed an ironic twist of genetics. Some even write autism research, or indeed fund it. Even these people are not treating it.   Their fear of quackery blinds them. There certainly are quacks and there are also those who straddle the line, some of what they say is nonsense, but other ideas may not be.

Imagine having a conversation with Bill Gates, who is using his billions to use vaccines to save millions of lives in poor countries, about the possibility that in some people vaccines might trigger mitochondrial disease and autism.  Any organization talking about autism in relation to vaccines, chelation, aluminium, heavy metals etc and anyone who associates with them are in effect blacklisted.

Why does the global head of neuroscience at Novartis not attend the Autism One or TACA conferences? He does have a son with severe autism. It would be very difficult for him to apply any therapy promoted by anyone who attends these events.

Why does a Professor of Medicine from the US Ivy League apply ideas from this blog to his son, but never leave a comment? It is very clear to me why.

As our reader Roger has commented, why do some leading autism researchers still go on about vaccines? It does their interests much more harm than good. 

I think Roger could teach Dr Naviaux a thing or two about getting his Suramin research funded.  

Enhancing Cognition

The first area I came across where serious research is underway to treat MR/ID concerns RASopathies, a group of disorders that share disturbed levels of a protein called RAS. It was actually French research.

In Down Syndrome (DS) I highlighted research that aims to increase cognitive function by targeting the alpha 5 subunit of the GABA_A receptor. We also saw that the same abnormal level of chloride within in cells that exists in much autism also occurs in Down Syndrome (DS); this is why the Frenchman Ben Ari has patented Bumetanide as a therapy for DS. 

In schizophrenia and bipolar there is also reduced cognitive function, but only in schizophrenia has there been much research and clinical trials to improve it. Histamine receptors were one target of this research. 

Too much or too little CBS (Cystathionine-β-synthase )

One known cause of cognitive dysfunction that has not been mentioned in my posts is CBS and since it was raised in a comment I thought it should be included.

All you need to know if you want to rule out a CBS problem is your level of homocysteine. If it is normal you do not have a problem with CBS. If homocysteine is high you have a case of Hyper-homocystinuria, which may be caused by too little CBS, or for a different reason. If you have very low levels of homocysteine (Hypo-homocystinuria) that may be caused by too much CBS and if you have Down Syndrome elevated CBS is inevitable.

Normalizing CBS is very likely to help cognition.

Cystathionine-β-synthase, also known as CBS, is an enzyme that in humans is encoded by the CBS gene. It catalyzes the first step of the transsulfuration pathway, from homocysteine to cystathionine:

L-serine + L-homocysteine    <------>     L-cystathionine + H₂O

Down syndrome is a medical condition characterized by an overexpression of cystathionine beta synthase (CBS) and so a low level of homocysteine in the blood. It has been speculated that cystathionine beta synthase overexpression could be the major culprit in this disease (along with dysfunctioning of GABA_A and Dyrk1a). The phenotype of down syndrome is the opposite of Hyperhomocysteinemia (described below). Pharmacological inhibitors of CBS have been patented by the Jerome Lejeune Foundation and trials are planned.

Cystathionine beta-synthase is enriched in the brains of Down's patients.

Down's syndrome (DS) or trisomy 21 is the most common genetic cause of mental retardation, and adults with DS develop Alzheimer type of disease (AD). Cystathionine beta-synthase (CBS) is encoded on chromosome 21 and deficiency in its activity causes homocystinuria, the most common inborn error of sulfur amino acid metabolism and characterized by mental retardation and vascular disease. Here, we show that the levels of CBS in DS brains are approximately three times greater than those in the normal individuals. CBS is localized to astrocytes and those surrounding senile plaques in the brains of DS patients with AD. The over-expression of CBS may cause the developmental abnormality in cognition in DS children and that may lead to AD in DS

It is a French foundation that is funding research is develop CBS inhibitors to improve cognition in Down Syndrome.

NovAliX To Collaborate With The Fondation Jérôme Lejeune On Down Syndrome (Trisomy 21)

NovAliX will use its expertise and capabilities in medicinal chemistry and structural biology to develop small molecule lead candidates targeting the cystathionine-beta-synthase (CBS). Indeed inhibition of CBS over-expression has been associated with restoration of cognitive impairment in animal models afflicted with trisomy. 

People with DS have a low incidence of coronary atherosclerotic disease (CAD), which would seem to be linked to their low level of homocysteine (high CBS), but their high level of DYRK1A (see later) may be the cause of their early onset Alzheimer’s. 

Some background on homocystinuria, courtesy of Wikipedia:- 

Classical homocystinuria, also known as cystathionine beta synthase deficiency or CBS deficiency, is an inherited disorder of the metabolism of the amino acid methionine, often involving cystathionine beta synthase.

Homocystinuria represents a group of hereditary metabolic disorders characterized by an accumulation of the amino acid homocysteine in the serum and an increased excretion of homocysteine in the urine.

Signs and symptoms of homocystinuria that may be seen include the following:

• A family history of homocystinuria
• Flush across the cheeks
• Musculoskeletal
• Tall, thin build resembling Marfanoid habitus
• Long limbs (dolichostenomelia)
• High-arched feet (pes cavus)
• Knock knees (genu valgum)
• Pectus excavatum and Pectus carinatum
• Intellectual disability
• Seizures
• Psychiatric disease

The term homocystinuria describes an increased excretion of homocysteine in urine (and incidentally, also an increased concentration in plasma). The source of this increase may be one of many metabolic factors, only one of which is CBS deficiency. Others include the re-methylation defects (cobalamin defects, methionine sythase deficiency, MTHFR) and vitamin deficiencies (cobalamin (vitamin B12) deficiency, folate (vitamin B9) deficiency, riboflavin deficiency (vitamin B2), pyridoxal phosphate deficiency (vitamin B6)). In light of this information, a combined approach to laboratory diagnosis is required to reach a differential diagnosis.  

DYRK1A

You may have noticed that DYRK1A was mentioned as another cause of cognitive loss in Down Syndrome.  DYRK1A is yet another autism gene; it encodes an enzyme that is important in how the brain develops. Too much DYRK1A also leads to reduced levels of homocysteine. 

An OTC DYRK1A inhibitor exists today, epigallocatechin gallate (EGCG).

Targeting trisomic treatments: optimizing Dyrk1a inhibition to improve Down syndrome deficits

A chemical with proven clinical safety rescues Down-syndrome-related phenotypes in through DYRK1A inhibition.

DYRK1A is important in neuronal development and function, and its excessive activity is considered a significant pathogenic factor in Down syndrome and Alzheimer's disease. Thus, inhibition of DYRK1A has been suggested to be a new strategy to modify the disease. Very few compounds, however, have been reported to act as inhibitors, and their potential clinical uses require further evaluation. Here, we newly identify CX-4945, the safety of which has been already proven in the clinical setting, as a potent inhibitor of DYRK1A that acts in an ATP-competitive manner. The inhibitory potency of CX-4945 on DYRK1A (IC50=6.8 nM) in vitro was higher than that of harmine, INDY or proINDY, which are well-known potent inhibitors of DYRK1A. CX-4945 effectively reverses the aberrant phosphorylation of Tau, amyloid precursor protein (APP) and presenilin 1 (PS1) in mammalian cells. To our surprise, feeding with CX-4945 significantly restored the neurological and phenotypic defects induced by the overexpression of minibrain, an ortholog of human DYRK1A, in the Drosophila model. Moreover, oral administration of CX-4945 acutely suppressed Tau hyperphosphorylation in the hippocampus of DYRK1A-overexpressing mice. Our research results demonstrate that CX-4945 is a potent DYRK1A inhibitor and also suggest that it has therapeutic potential for DYRK1A-associated diseases

Epigallocatechin gallate: A useful therapy for cognitive disability in Down syndrome?

Neurodevelopmental alterations and cognitive disability are constant features of Down syndrome (DS), a genetic condition due to triplication of chromosome 21. DYRK1A is one of the triplicated genes that is thought to be strongly involved in brain alterations. Treatment of Dyrk1A transgenic mice with epigallocatechin gallate (EGCG), an inhibitor of DYRK1A, improves cognitive performance, suggesting that EGCG may represent a suitable treatment of DS. Evidence in the Ts65Dn mouse model of DS shows that EGCG restores hippocampal development, although this effect is ephemeral. Other studies, however, show no effects of treatment on hippocampus-dependent memory. On the other hand, a pilot study in young adults with DS shows that EGCG transiently improves some aspects of memory. Interestingly, EGCG plus cognitive training engenders effects that are more prolonged. Studies in various rodent models show a positive impact of EGCG on brain and behavior, but other studies show no effect. In spite of these discrepancies, possibly due to heterogeneity of protocols/timing/species, EGCG seems to exert some beneficial effects on the brain. It is possible that protocols of periodic EGCG administration to individuals with DS (alone or in conjunction with other treatments) may prevent the disappearance of its effects.

Conclusion

Understanding emerging therapies that treat various types of MR/ID, and also the various types of dementia, should unlock interesting avenues to raise cognitive function in many types of autism.

Homocysteine levels are very easy to measure. 

Because the gene miss-expression in Down Syndrome (DS) is fully understood, it makes sense that treatment is more advanced than in autism, which is so heterogenous. There are a lot of people in the world with DS and so there is a big market for drug makers.

The potential drug therapies to improve cognition in Down Syndrome (DS) appear to be:- 

·        Basmisanil, a negative allosteric modulator of α₅ subunit-containing GABA_A receptors. It appears that sodium benzoate may have a similar effect.

·        Bumetanide, an NKCC1 inhibitor

·        Potassium bromide, Br^- displaces Cl^- to lower intracellular Cl^-

·        CBS inhibitor

·        DYRK1A inhibitor, like Epigallocatechin gallate (EGCG), but a more potent inhibitor like CX-4945 (Silmitasertib) might be better.

There is mouse model research to show that a single dose just after birth of a drug that stimulates the sonic hedgehog signaling pathway results in a "normal" adult brain.

The risk of Down Syndrome (DS), caused by a third copy of chromosome 21 (trisomy 21), rises rapidly with increasing maternal age, nonetheless the number of births is stable to falling in most developed countries, due to increased prenatal testing and termination of pregnancy for fetal anomaly (TOPFA). TOPFA is not practiced in countries like Poland and Ireland. In Denmark screening has long been free and TOPFA has risen to 98%. In the UK two thirds of mothers opt for their free DS screening and 90% of those who test positive, opt for their free TOPFA. The one third letting nature take its course are probably mainly younger mothers.

In Catholic countries you have both extremes - in Cork, Ireland DS is present 30 times per 10,000 births, but in Zagreb Croatia it is just 6 per 10,000. In the US the CDC say it 14, while in the UK it is 10.  In South Africa 20 cases of DS occur per 10,000 births; mothers are younger than in Ireland.

In developed countries, the natural prevalence of DS looks to be 0.3%, which is the same as the incidence of strictly defined autism (SDA), which I estimated in an earlier post to be 0.3%. It is just that in developed countries most people with DS are never born. 

I would have thought CX-4945 should be trialed by some clever Alzheimer's researcher and indeed for any Tauopathy. In the meantime perhaps Grandad should drink a lot of green tea to get his dose of EGCG.

Green Tea Catechin EGCG in Down Syndrome, but Autism? and Cerebrolysin

In a recent comment a reader from Poland highlighted the popularity there of a drug called cerebrolysin to treat autism and Down syndrome.  It turns out that this treatment in also widespread in the former Soviet Union.

Green tea as a source of Epigallocatechin gallate (EGCG)

Cerebrolysin is a mixture of peptides purified from pig brains, including  brain-derived neurotrophic factor (BDNF), glial cell line-derived neurotrophic factor (GDNF), nerve growth factor (NGF), and ciliary neurotrophic factor (CNTF).

While cerebrolysin is used for stroke and vascular dementia, it is used by some as a nootropic. 

There are two Russian studies supporting the use of Cerebrolysin:

The effect of cerebrolysin on cognitive functions in childhood autism and in Asperger syndrome

An effect of long-term cerebrolysin therapyin combination with neuroleptics on behavioral and cognitive disturbances in endogenous childhood autism

 

I was informed that cerebrolysin is prescribed off-label in Poland to treat autism, with some good results.

Three other substances were then mentioned.

MemoProve, an oral OTC product made by the same Austrian company that produces cerebrolysin, and then two research compounds P6 and P21. The P21 research is also part funded by the same Austrians. People in the US are using intranasal P21 as a nootropic.

It does seem that some people with autism do indeed benefit from cerebrolysin. 

As we have seen in previous posts the various growth factors (BDNF, NGF, IGF-1 etc) are disturbed in autism and they play a key role in various signaling cascades. There certainly is logic in using growth factors as autism therapies, but it would be important to use the right ones. In Rett syndrome there is almost no nerve growth factor (NGF), whereas in much autism there are elevated levels. Insulin-like growth factor IGF-1 already is a target autism therapy.

The disadvantage of cerebrolysin is that it is made from pigs’ brains and you need to inject it every day.

Unless you live in Poland, Russia or Romania, I doubt you will be able to try cerebrolysin, even if you want to.

Another therapy I am told is used in Poland is EGCG, which stands for Epigallocatechin gallate, or just green tea. 

Epigallocatechin gallate (EGCG)

EGCG is another natural substance like resveratrol, curcumin and indeed quercetin that has potent properties in lab, but never quite makes it in the human world.

The normal problem is low bioavailability and the lack of funding to do conclusive clinical trials.

In the case of EGCG there are now some serious studies being done in Spain. 

Egcg, a dyrk1a Inhibitor as Therapeutic Tool for Reversing Cognitive Deficits in Down Syndrome Individuals.

There is a mounting evidence of the modulation properties of the major catechin in green tea, epigallocatechin-3-gallate (EGCG), on dual specificity tyrosine-phosphorylation-regulated kinase 1A (DYRK1A) gene overexpression in the brains of DS mouse models. The aims are to investigate the clinical benefits and safety of EGCG administration in young adults with DS, to establish short-term EGCG effects (three months) on neurocognitive performance, and to determine the persistency or reversibility of EGCG related effects after three months of discontinued use. 

Epigallocatechin Gallate (EGCG) to Improve Cognitive Performance in Foetal Alcohol Syndrome (FAS) Children (Neuro-SAF)

The flavonoid epigallocatechin gallate (EGCG) is a modulator of neuronal plasticity useful in other neurodevelopmental diseases. A recent study showed that EGCG is a promising tool for cognitive and health related quality of life improvement in Down's syndrome.

The objective is to determine the efficacy of EGCG as a therapeutic candidate for the improvement of cognitive performance in FAS patients  

Using Epigallocatechin Gallate (EGCG) and Cognitive Training to Modulate Cognitive Performance in Patients With Fragile X Syndrome" (TESFX)

Fragile X syndrome (FXS) present alterations in synaptic plasticity that produce intellectual disability. can produce improvement. Estrogens (targeting Estrogen Receptors beta (ER-β) can act as neuroprotective agents, promoting synaptic plasticity and neurite outgrowth, and health benefits derived from flavonoids, as the flavonol epigallocatechin gallate (EGCG), phytoestrogens of natural origin are partially explained by their interaction with membrane ER. Selective ER-β flavonoids are thus good candidates for their therapeutic evaluation in intellectual disabilities. EGCG also targets central intracellular transduction signals altered in FXS and improves memory recognition in a FXS animal model(adenosine triphosphate (ATP)-inhibitor of phosphatidylinositol 3-kinase (PI3K)and mammalian target of rapamycin (mTOR) and extracellular signal-regulated kinase (ERK1/2). This study targets the synaptic plasticity alterations that underlie the learning and memory impairment but also the computational disability in FXS. The hypothesis is that EGCG can act by favoring the physiological processes involved in cognition. 

The Spanish Science.

You might wonder why a hospital in Barcelona is doing all this research into a green tea extract.

EGCG has numerous biological effects and in the three trials they are not claiming the same mode of action.  In the fragile X trial it is the effect on Estrogen receptor beta, while in Down syndrome it is the effect on DYRK1A gene overexpression. 

Trial results

The only trial to have yet published results is the one on Down Syndrome.  Here the results were pretty good, given that this is a cheap supplement and the dose was modest.

The easy reading version:-

Green tea extract 'boosts mental ability' in people with Down's 

What were the basic results?

For most of the tests (21 of 24) there were no differences between the groups.

However, in three tests people who'd taken EGCG did better. This improvement lasted for six months after the study ended.

These were:

·         remembering and recognizing patterns

·         inhibitory control – the ability to override instinct to follow instructions; for example; in this test, to say "cat" when shown a picture of a dog, and vice versa

·         ability to carry out everyday living tasks (adaptive behaviour)   

I am very surprised that the benefit lasted six months after the study ended.  It would be great if they could validate that in their phase 3 trial. 

The full study:- 

Safety and efficacy of cognitive training plus epigallocatechin-3-gallate in young adults with Down's syndrome (TESDAD): a double-blind, randomised, placebo-controlled, phase 2 trial 

We enrolled adults (aged 16–34 years) with Down's syndrome from outpatient settings in Catalonia, Spain, with any of the Down's syndrome genetic variations (trisomy 21, partial trisomy, mosaic, or translocation) in a double-blind, placebo-controlled, phase 2, single centre trial (TESDAD). Participants were randomly assigned at the IMIM-Hospital del Mar Medical Research Institute to receive EGCG (9 mg/kg per day) or placebo and cognitive training for 12 months. We followed up participants for 6 months after treatment discontinuation. We randomly assigned participants using random-number tables and balanced allocation by sex and intellectual quotient. Participants, families, and researchers assessing the participants were masked to treatment allocation. The primary endpoint was cognitive improvement assessed by neuropsychologists with a battery of cognitive tests for episodic memory, executive function, and functional measurements. Analysis was on an intention-to-treat basis. This trial is registered with ClinicalTrials.gov, number NCT01699711.

Findings

The study was done between June 5, 2012, and June 6, 2014. 84 of 87 participants with Down's syndrome were included in the intention-to-treat analysis at 12 months (43 in the EGCG and cognitive training group and 41 in the placebo and cognitive training group). Differences between the groups were not significant on 13 of 15 tests in the TESDAD battery and eight of nine adaptive skills in the Adaptive Behavior Assessment System II (ABAS-II). At 12 months, participants treated with EGCG and cognitive training had significantly higher scores in visual recognition memory (Pattern Recognition Memory test immediate recall, adjusted mean difference: 6·23 percentage points [95% CI 0·31 to 12·14], p=0·039; d 0·4 [0·05 to 0·84]), inhibitory control (Cats and Dogs total score, adjusted mean difference: 0·48 [0·02 to 0·93], p=0·041; d 0·28 [0·19 to 0·74]; Cats and Dogs total response time, adjusted mean difference: −4·58 s [–8·54 to −0·62], p=0·024; d −0·27 [–0·72 to −0·20]), and adaptive behaviour (ABAS-II functional academics score, adjusted mean difference: 5·49 [2·13 to 8·86], p=0·002; d 0·39 [–0·06 to 0·84]). No differences were noted in adverse effects between the two treatment groups.

Interpretation

EGCG and cognitive training for 12 months was significantly more effective than placebo and cognitive training at improving visual recognition memory, inhibitory control, and adaptive behaviour. Phase 3 trials with a larger population of individuals with Down's syndrome will be needed to assess and confirm the long-term efficacy of EGCG and cognitive training.  

Epigallocatechin gallate: A useful therapy for cognitive disability in Down syndrome?

The science behind EGCG

Green tea catechin, epigallocatechin-3-gallate (EGCG): mechanisms, perspectives and clinical applications 

An expanding body of preclinical evidence suggests EGCG, the major catechin found in green tea (Camellia sinensis), has the potential to impact a variety of human diseases. Apparently, EGCG functions as a powerful antioxidant, preventing oxidative damage in healthy cells, but also as an antiangiogenic and antitumor agent and as a modulator of tumor cell response to chemotherapy. Much of the cancer chemopreventive properties of green tea are mediated by EGCG that induces apoptosis and promotes cell growth arrest by altering the expression of cell cycle regulatory proteins, activating killer caspases, and suppressing oncogenic transcription factors and pluripotency maintain factors. In vitro studies have demonstrated that EGCG blocks carcinogenesis by affecting a wide array of signal transduction pathways including JAK/STAT, MAPK, PI3K/AKT, Wnt and Notch. EGCG stimulates telomere fragmentation through inhibiting telomerase activity. Various clinical studies have revealed that treatment by EGCG inhibits tumor incidence and multiplicity in different organ sites such as liver, stomach, skin, lung, mammary gland and colon. Recent work demonstrated that EGCG reduced DNMTs, proteases, and DHFR activities, which would affect transcription of TSGs and protein synthesis. EGCG has great potential in cancer prevention because of it’s safety, low cost and bioavailability. In this review, we discuss its cancer preventive properties and it’s mechanism of action at numerous points regulating cancer cell growth, survival, angiogenesis and metastasis. Therefore, non-toxic natural agent could be useful either alone or in combination with conventional therapeutics for the prevention of tumor progression and/or treatment of human malignancies.

Mast Cells and EGCG

One interesting effect of EGCG, at least in the lab, is that it can stabilize mast cells. This would mean that it might he helpful in treating allergy and some types of GI problems, if you have enough of it.

Epigallocatechin-3-gallate Reduces Mast Cells Activity TNF-α and NFKB in Colitis by Interrupting an Inflammatory Cascade (MUC2P.827)

Epigallocatechin-3-gallate inhibits mast cell degranulation, leukotriene C4 secretion, and calcium influx via mitochondrial calcium dysfunction.

Conclusion

The green tea extract EGCG is inexpensive and widely available. It is often taken for its antioxidant properties. In most trials so-called phytoestrogens like EGCG have almost no estrogen-like effect in humans, so I doubt this mode of action.

The trials all used a dosage of 9mg/kg of EGCG which is easy to achieve with OTC supplements.

Given the positive results from the small trial in Down Syndrome (DS), it would fall into the “no-brainer” category to make a home trial, if you have a child with DS.

This is quite different to injecting your child with Cerebrolysin from pig’s brains, where there are some drawbacks.

Will EGCG help in Fragile-X or Fetal Alcohol Syndrome? I have no idea; but being having well established antioxidant properties, I expect it is almost guaranteed to help a least marginally.

Will EGCG help in autism? Given its safety profile, price and availability, it really should have a place on your to-do list. It is an antioxidant with numerous other possible effects, some of which hopefully may be evident in humans.  Compared to some exotic antioxidants that people buy, it is cheap.

With no great expectations, I will see if EGCG has any effect. It might help an as antioxidant, it might help stabilize mast cells and, if has enough potency as an estrogen, it would help via RORa. As you can see in the chart above it actually has dozens of potential effects.

Some natural substances like quercetin have undoubted positive effects, but after continued usage can give side effects.  The EGCG trial was 12 months long and they did not find adverse effects compared to the placebo.

The amount of EGCG in green tea varies wildly, making standardized supplements a safer bet.  Apparently, Lipton Green Tea bags contain about 70mg of EGCG per serving. So my son would need to drink 6 cups of green tea a day to match the trial dose.