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Showing posts with label DS. Show all posts
Showing posts with label DS. Show all posts

Thursday 24 June 2021

Betaine (TMG) and Gene Therapy as potential alternatives to Bumetanide Treatment in Autism?


Betaine (also known as TMG, or trimethylglycine) is a methyl derivative of glycine, first isolated from sugar beet and hence its name.

Today’s post was prompted by our reader, and Covid home-school instructor, AJ.  He raised the question of whether betaine can be used like Bumetanide to normalize chloride levels in neurons.

I am combing this idea with news from Genoa in Italy, where they have developed gene therapy as an alternative to Bumetanide and in their words :-

“This sets the stage for the development of a gene therapy approach to overcome the shortcomings of bumetanide treatment.”

The interesting thing is that neither of these ideas come from autism research.  The idea to use Betaine was stumbled upon and was then written up in a Norwegian case study about Creatine transporter deficiency.  The Italians are trying to improve cognition in brain disorders and their model of choice was Down syndrome. 

As we have seen time and again, elevated chloride within neurons is a common feature of many types of brain disorders from some idiopathic autism, to Down syndrome, to adult conditions such as Parkinson’s disease.  Today we learn that it is may well be a feature of Creatine Transporter Deficiency.

I have been rather wary of writing about any kind of gene therapy, because it seemed either too far ahead of its time, or just absurdly expensive.  There are some new $1+ million treatments.

This may be about to change given that the Biontech (AKA Pfizer vaccine), Moderna, Janssen (Johnson & Johnson) and Oxford AstraZeneca vaccines for Covid 19 are all based on gene therapy.

The Biontech people are really clever and were already trying to treat various kinds of cancer and other condition using gene therapy, before they developed their highly successful Covid vaccine.

The Italians in Genoa used an adeno-associated virus (AAV)-mediated RNA interference (RNAi) to target and reduce neuronal NKCC1 expression, rescue neuronal Cl-  homeostasis, GABAergic transmission, and cognitive deficits.   The benefit was still there 6 months after the injection.

Don’t worry if the above paragraph makes little sense. Just read on.

The same type of adeno-associated virus (AAV) vector is the platform for gene therapy delivery used in the Astra Zeneca, Janssen and the Russian Sputnik covid vaccines.

The virus is just the delivery system (vector) to get some genetic code into cells.

The Oxford-AstraZeneca COVID-19 vaccine uses a chimpanzee adenoviral vector. It delivers the gene that encodes the SARS-CoV-2 spike protein, to our cells.  Our cells then transcribe this gene into messenger RNA, or mRNA, which in turn prompts our cellular machine to make the spike protein in the main body of the cell. The mRNA molecule behaves essentially like a recipe.  Then our cells present the spike protein on the cell surface, prompting our immune system to make antibodies and mount T cell responses.

Biontech and Moderna are pioneers of mRNA vaccines, which bypass one step in the above process. They do not require our cells to make the messenger RNA, or mRNA.  They have already made it for you.

 

Gene therapy for autism?

Single gene autisms are all potential candidates for gene therapy.

The problem is that most autism and all Down syndrome is polygenic, there can be hundreds of miss-expressed genes.

But the researchers in Italy show us that even polygenic autism and Down syndrome can benefit from therapy targeting a single gene.  You just have to select the right one.

The problem is the price. Covid vaccines are made in huge quantities and are cheap.

Customized gene therapy is ultra expensive, in part because each therapy has to be approved individually.

 

An NKCC1 Gene Therapy?

The Italians have already made the NKCC1 Gene Therapy.  The question is will it ever going be available to humans with Down Syndrome, Autism or even Parkinson’s disease?

Restoring neuronal chloride homeostasis with anti-NKCC1 gene therapy rescues cognitive deficits in a mouse model of Down syndrome

A common feature of diverse brain disorders, is the alteration of GABA-mediated inhibition due to aberrant intracellular chloride homeostasis induced by changes in the expression and/or function of chloride transporters. Notably, pharmacological inhibition of the chloride importer NKCC1 is able to rescue brain-related core deficits in animal models of these pathologies and some human clinical studies. Here, we show that reducing NKCC1 expression by RNA interference in the Ts65Dn mouse model of Down syndrome (DS) restores intracellular chloride concentration, efficacy of GABA-mediated inhibition and neuronal network dynamics in vitro and ex vivo. Importantly, AAV-mediated neuron-specific NKCC1 knockdown in vivo rescues cognitive deficits in diverse behavioral tasks in Ts65Dn animals. Our results highlight a mechanistic link between NKCC1 expression and behavioral abnormalities in DS mice, and establish a molecular target for new therapeutic approaches, including gene therapy, to treat brain disorders characterized by neuronal chloride imbalance.

 

This sets the stage for the development of a gene therapy approach to overcome the shortcomings of bumetanide treatment.

This highlights a causative role of NKCC1 upregulation in learning and memory deficits in adult Ts65Dn mice, thus also validating brain NKCC1 as a target for ameliorating cognitive disabilities in DS. Furthermore, our neuro-specific knockdown approach points to neurons as major players in the NKCC1- dependent cognitive impairment in DS mice. Nevertheless, we cannot exclude that other cell types which also express NKCC1 (e.g. glial cells) could still play a role in the overall cognitive impairment that characterizes DS.

Despite the very large and fast-increasing literature both on animal models and patients indicating positive outcomes upon bumetanide treatment, there is not yet a strong demonstrated direct link between NKCC1 inhibition, restoration of Cl- homeostasis and full GABAergic inhibitory signaling, and rescue of brain deficits.  Moreover, bumetanide has strong diuretic activity, triggering ionic imbalance, and potential ototoxicity 25,26.  This hampers its use for clinical applications in lifelong treatments4,27 and may strongly jeopardize treatment compliance along years of treatment.  Moreover, bumetanide was given systemically in most studies, and the suboptimal brain pharmacokinetic profile of the drug28 raises questions on its mechanism of action29.  Here, we demonstrate that adeno-associated virus (AAV)-mediated RNA interference (RNAi) to target (and reduce) neuronal NKCC1 expression rescues neuronal Cl- homeostasis, GABAergic transmission, and cognitive deficits in the Ts65Dn mouse model of Down syndrome. This sets the stage for the development of a gene therapy approach to overcome the shortcomings of bumetanide treatment.

 

“Thus, our results indicate the efficacy of long-term AAV9-mediated neuro-specific NKCC1 knockdown in rescuing cognitive deficits in Ts65Dn mice.”

 

“Besides establishing a causal link between NKCC1 upregulation and cognitive impairment in DS, our data also provide a proof-of-concept for a neuro-specific RNAi gene therapy approach to restore hippocampus-dependent cognitive behaviors in adult animals specifically in the brain, and without affecting peripheral organs (e.g., the kidney). This is particularly relevant in the context of the current clinical trials repurposing the strong diuretic bumetanide to treat brain disorders with impaired chloride homeostasis3.  Importantly, we achieved a comparable degree of long-term cognitive rescue with two different amiR sequences against NKCC1, underlining the specificity of our approach.”

  

Gone Fishing




If a trip to Italy for gene therapy is not realistic, this takes us back to AJ’s idea, which is to use Betaine.  The correct version is TMG or glycine betaine, and confusingly not Betaine HCl.

Fish love the taste of betaine.

Betaine was first isolated from sugar beet.

I recall from my time at the sugar factory, when I was 18, that once you have sliced up the sugar beet and extracted as much sugar as possible you are left with the pulp.  This pulp is dried, molasses is added back and then it is made into pellets.  The pellets are fed to cattle and horses.  They taste pretty bad in my opinion.

To humans it tastes bad because of the beet molasses by-product.

The molasses by-product from sugar cane tastes great to humans.  That is why they make rum in the Caribbean, and not in England or Canada.

Brown sugar from a sugar beet factory is made by adding sugar cane molasses to white sugar from beet.  It is a cheat really.

Cows love sugar beet by-products.

It turns out that fish love betaine HCl.

Betaine HCl is an excellent natural attractor that stimulates a strong, prolonged feeding response from carp and many other coarse fish.

Betaine HCl is now used to induce feeding in the fish farming industry

As our reader Tyler has highlighted, Betaine HCl, that fish like and is available is a cheap supplement is not the same as the Betaine used in the medical case study. Confusingly, the original Betaine (TMG, or called glycine betaine) gave way to a class of compounds all called betaines. One of these betaines is betaine HCL.

In most cases, in the medical literature when they refer to Betaine, they mean glycine betaine, also known as TMG.

Betaine HCl is used to increase acidity in your stomach. The effect of betaine compounds other than glycine betaine/TMG on NKCC1 is unknown.


Glycine Betaine (TMG) and NKCC1

It seems that betaine reduces your level of NKCC1 RNA. 

In your DNA are the instructions to make the NKCC1 transporter. To go from these instructions to actually making the transporters you need RNA.

In some autism there are too many NKCC1 transporters, so put simply there was too much NKCC1 RNA. So, if you can find a substance that reduces NKCC1 RNA, you might well solve the problem.

The caveat is that the substance must not also increase KCC2 RNA.  This appears to be what taurine does.

Here, finally, is AJ’s paper:


Treatment experience in two adults with creatine transporter deficiency

Background

Creatine transporter deficiency (CTD) is an X-linked form of intellectual disability (ID) caused by SCL6A8 mutations. Limited information exists on the adult course of CTD, and there are no treatment studies in adults.

Methods

We report two half-brothers with CTD, 36 and 31 years at intervention start. Their clinical phenotypes were consistent with CTD, and intervention was indicated because of progressive disease course, with increased difficulties speaking, walking and eating, resulting in fatigue, and malnutrition. We therefore performed treatment trials with arginine, glycine and a proprietary product containing creatine and betaine, and then a trial supplementing with betaine alone. Results In the older patient, glycine and arginine were accompanied by adverse effects, while betaine containing proprietary product gave improved balance, speech and feeding. When supplementation stopped, his condition deteriorated, and improved again after starting betaine supplement. Betaine supplementation was also beneficial in the younger patient, reducing his exhaustion, feeding difficulties and weight loss, making him able to resume his protected work.

Discussion & conclusion

We report for the first time that betaine supplement was well tolerated and efficient in adults with CTD, while arginine and/or glycine were accompanied by side effects. Thus, betaine is potentially a new useful treatment for CTD patients. We discuss possible underlying treatment mechanisms. Betaine has been reported to have antagonistic effect on NKCC1 channels, a mechanism shared with bumetanide, a medication with promising results in both in autism and epilepsy. Further studies of betaine's effects in well-designed studies are warranted.

 

The mechanism of betaine’s assumed favorable effect is unknown. We do not know whether betaine influences the cell creatine content in itself or its effects are more aspesific. However, we would like to present some hypotheses. First, betaine may have effect in CTD by modulating GABA-transmission. Betaine has been reported to have an antagonistic effect on NKCC1 channels, which also influences GABAergic neurotransmission. Inhibiting NKCC1 is a mechanism shared with bumetanide, a well-known diuretic medication that in recent years has been found to influence GABAergic transmission, and thereby it has been found promising in treatment of several brain conditions, including autism, and epilepsy. NKCC1 inhibition by bumetanide has also been tried with success in other rare neurodevelopmental disorders fragile X syndrome and tuberous sclerosis. Second, betaine’s properties as an osmolyte may be of importance, as betaine has similarities with creatine in being an osmolyte. Osmotic properties are thought to be one of the central mechanism behind bumetanide’s efficacy in treating brain disorders. Thus, it could be speculated that the lack of intracellular creatine in CTD may result in inefficient osmolyte regulation, and that betaine supplementation replaces the lacking creatine and thereby improves the neuronal adaption to salinity changes, edema or cellular dehydration. Betaine has osmolyte properties that even makes it act as a “chemical chaperone” increasing the stability of cell and membrane proteins. Fourth, it is possible that betaine has some effect through modifying methylation. Methylation of GAA by GAMT to form creatine is a rate-limiting step in the creatine synthesis by neurons. Betaine could stimulate this by donating methyl groups to SAMe, which donates a methyl group to GAA to form creatine. This might reduce the burden when body demands more methyl groups for creatine synthesis. Similar mechanisms may be responsible for a beneficial effect of both betaine and s-adenosyl methionine (SAMe). However, as creatine and GAA share the same transporter, one would not expect GAA to enter the GAMTexpressing cells in patients suffering from CTD. Still, it cannot be excluded that there is some rest function in the creatine transporter, and that increased endogenous synthesis improves the condition slightly. Furthermore, it is possible that CTD increases the need for methylation agents in general, as creatine supplementation has been found to reduce the need for other methylation agents [34]. Thus, it is likely that betaine may have a positive effect in CTD by improving methylation capacity for other reactions than those directly involved in creatine production. Betaine’s effect on muscle may be also of importance, as animal studies have shown that muscles growth improves with betaine [35], which potentially could have had a positive impact on our patients fatigue and weight loss. To summarize, betaine has several properties that make it likely that it will have a beneficial effect in CTD, especially the properties as an osmolyte, a down regulator of the NKCC1 channel and an influencer of GABAergic transmission. These properties are similar to the properties of bumetanide, a promising new medication for treatment of autism and epilepsy, which are common symptoms of CTD. Further research is needed, however, to elucidate the role of betaine in CTD.

If you read the detail of the old paper that is referred to in the above paper, you see that betaine is not blocking the NKCC1 channels as suggested, but it seems to be reducing the number of them.  The net effect may be the same, but the process is very different.

 

Expression and regulation of the Na+/K+/2Cl− cotransporter NKCC1 in rat liver and human HuH-7 hepatoma cells

The expression of sodium potassium chloride cotransporter 1 (NKCC1) was studied in different liver cell types. NKCC1 was found in rat liver parenchymal and sinusoidal endothelial cells and in human HuH-7 hepatoma cells. NKCC1 expression in rat hepatic stellate cells increased during culture-induced transformation in the myofibroblast-like phenotype. NKCC1 inhibition by bumetanide increased α1-smooth muscle actin expression in 2-day-cultured hepatic stellate cells but was without effect on basal and platelet-derived-growth-factor-induced proliferation of the 14-day-old cells. In perfused rat liver the NKCC1 made a major contribution to volume-regulatory K+ uptake induced by hyperosmolarity. Long-term hyperosmotic treatment of HuH-7 cells by elevation of extracellular NaCl or raffinose concentration but not hyperosmotic urea or mannitol profoundly induced NKCC1 mRNA and protein expression. This was antagonized by the compatible organic osmolytes betaine or taurine. The data suggest a role of NKCC1 in stellate cell transformation, hepatic volume regulation, and long-term adaption to dehydrating conditions.

 

Aha!  Glycine Betaine and Taurine – not so fast 

You have to check the effect on both NKCC1 and KCC2.  One lets chloride into neurons and the lets it out.  You want to block NKCC1 and not KCC2, otherwise you undo all the good you have done.

Both glycine betaine (TMG) and taurine are already used as autism supplements at low doses.  The paper below suggest that Taurine is not a good idea for people with high levels of chloride within neurons.

 

Taurine inhibits K+-Cl- cotransporter KCC2 to regulate embryonic Cl- homeostasis via with-no-lysine (WNK) protein kinase signaling pathway

GABA inhibits mature neurons and conversely excites immature neurons due to lower K(+)-Cl(-) cotransporter 2 (KCC2) expression. We observed that ectopically expressed KCC2 in embryonic cerebral cortices was not active; however, KCC2 functioned in newborns. In vitro studies revealed that taurine increased KCC2 inactivation in a phosphorylation-dependent manner. When Thr-906 and Thr-1007 residues in KCC2 were substituted with Ala (KCC2T906A/T1007A), KCC2 activity was facilitated, and the inhibitory effect of taurine was not observed. Exogenous taurine activated the with-no-lysine protein kinase 1 (WNK1) and downstream STE20/SPS1-related proline/alanine-rich kinase (SPAK)/oxidative stress response 1 (OSR1), and overexpression of active WNK1 resulted in KCC2 inhibition in the absence of taurine. Phosphorylation of SPAK was consistently higher in embryonic brains compared with that of neonatal brains and down-regulated by a taurine transporter inhibitor in vivo. Furthermore, cerebral radial migration was perturbed by a taurine-insensitive form of KCC2, KCC2T906A/T1007A, which may be regulated by WNK-SPAK/OSR1 signaling. Thus, taurine and WNK-SPAK/OSR1 signaling may contribute to embryonic neuronal Cl(-) homeostasis, which is required for normal brain development.

 

So, it is likely only Glycine Betaine (TMG) may be of potential benefit, in the case of lowering chloride.

 

Glycine Betaine in the broader research

 

Betaine in Inflammation: Mechanistic Aspects and Applications

Betaine is known as trimethylglycine and is widely distributed in animals, plants, and microorganisms. Betaine is known to function physiologically as an important osmoprotectant and methyl group donor. Accumulating evidence has shown that betaine has anti-inflammatory functions in numerous diseases. Mechanistically, betaine ameliorates sulfur amino acid metabolism against oxidative stress, inhibits nuclear factor-κB activity and NLRP3 inflammasome activation, regulates energy metabolism, and mitigates endoplasmic reticulum stress and apoptosis. Consequently, betaine has beneficial actions in several human diseases, such as obesity, diabetes, cancer, and Alzheimer’s disease.

 

Betaine is a stable and nontoxic natural substance. Because it looks like a glycine with three extra methyl groups, betaine is also called trimethylglycine . In addition, betaine has a zwitterionic quaternary ammonium form [(CH3)3N+ CH2COO−] (Figure 1). In the nineteenth century, betaine was first identified in the plant Beta vulgaris. It was then found at high concentrations in several other organisms, including wheat bran, wheat germ, spinach, beets, microorganisms, and aquatic invertebrates. Dietary betaine intake plays a decisive role in the betaine content of the body. Betaine is safe at a daily intake of 9–15 g for human and distributes primarily to the kidneys, liver, and brain. The accurate amount of betaine intake generally relies on its various sources and cooking methods. Besides dietary intake, betaine can be synthesized from choline in the body. Studies report that high concentrations of betaine in human and animal neonates indicate the effectiveness of this synthetic mechanism.

  

Boosting amino acid derivative may be a treatment for schizophrenia

Many psychiatric drugs act on the receptors or transporters of certain neurotransmitters in the brain. However, there is a great need for alternatives, and research is looking at other targets along the brain's metabolic pathways. Lack of glycine betaine contributes to brain pathology in schizophrenia, and new research shows that betaine supplementation can counteract psychiatric symptoms in mice.

 

 

Supplement treats schizophrenia in mice, restores healthy “dance” and structure of neurons Repurposed drug works by building cells’ skeleton and transportation network


 

 

Conclusion

Early on in the Covid saga, I saw interviews with both the Moderna researchers and the Oxford (AstraZeneca) researchers. Both claimed that they designed their vaccines over a weekend.  This was made possible by the Chinese releasing the DNA code of the virus.

When you think about gene therapy for autism and Down syndrome, the same likely applies; much could be achieved over a weekend.

The expensive and time-consuming part is the testing and approval process.

In the Covid pandemic the approval process was modified to allow for emergency use.  Perhaps this should also be the case for all gene therapies?

What use is a $2 million therapy for autism or Down syndrome?

In theory, if you gave your gene therapy prior to birth or shortly thereafter, it might be fully curative.  Realistically, by the time you get the therapy it is just going to be beneficial and you will still need other ongoing therapies.

Note that gene therapy normally applies to just one gene.  In Down syndrome people have a third copy of all, or just part, of Chromosome 21.  This results directly in the miss-expression of hundreds of genes from that chromosome.

The gene that encodes NKCC1 is on Chromosome 5, which has nothing directly to do with Down syndrome.

The NKCC1 transporter is over-expressed in Down syndrome as a down stream consequence of the disorder. It is caused by the “faulty GABA switch”, referred to in earlier posts.

The Italian gene therapy to lower chloride in neurons and so raise cognition, has numerous applications, in people currently of all ages, so there is a big potential market.

Why not gene therapy for all single gene autisms?  It could be a highly productive use of the researcher’s weekends, for a year or two.

The issue is who would pay for the $20 to $30 million approval process, for each gene?

Maybe some of the billions in profit from clever Covid vaccines could be used for pro bono gene therapy?  Highly unlikely.

Biontech, who are the brains behind the Pfizer vaccine, do have plans to develop gene therapy for other medical conditions.  I think these will be ultra expensive,

That brings me back to Glycine Betaine (TMG), is 10g a day of this supplement really going to reduce the expression of NKCC1 transporters in neurons and so lower chloride within neurons?  It seems to work in creatine transporter deficiency, is all we can say.  

Glycine betaine, at much lower doses, has been used by DAN and now MAPS doctors for decades. They use it as a “methyl-donor”.  There is a combination of real science and hocus-pocus surrounding DNA methylation. 

 DNA Methylation and Susceptibility to Autism Spectrum Disorder


 

 



 

Tuesday 24 October 2017

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 GABAA 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 GABAA 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.


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 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:


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).



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

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 GABAA 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.