The Clever Ketogenic Diet for some Autism

I have covered the Ketogenic Diet (KD) in earlier posts. 

There are more and more studies being published that apply the KD to mouse models of autism.

Calling the KD a diet does rather under sell it.  The classic therapeutic ketogenic diet was developed for treatment of pediatric epilepsy in the 1920s and was widely used into the next decade, but its popularity waned with the introduction of effective epilepsy drugs.

There are various exclusion diets put forward to treat different medical conditions; some are medically accepted but most are not, but that does not mean they do not benefit at least some people.

When it comes to the ketogenic diet (KD) the situation is completely different, this diet is supposed to be started in hospital and maintained under occasional medical guidance. The KD was developed as a medical therapy to treat pediatric epilepsy.  It is very restrictive which is why it is used mainly in children, since they usually will (eventually) eat what is put in front of them.

The KD was pioneered as a medical therapy by researchers at Johns Hopkins in the 1920s, over the years they have shown that most of the benefit of the KD can be achieved by the much less restrictive Modified Atkins Diet (MAD).  The first autism mouse study below suggests something similar “Additional experiments in female mice showed that a less strict, more clinically-relevant diet formula was equally effective in improving sociability and reducing repetitive behavior”.

What about the KD in Autism?

Most people with autism, but without epilepsy, will struggle to get medical help to initiate the KD.  Much research in animal models points to the potential benefit of the KD.

Ketogenic diets improve behaviors associated with autism spectrum disorder in a sex-specific manner in the EL mouse

·        Drug treatments are poorly effective against core symptoms of autism.

·        Ketogenic diets were tested in EL mice, a model of comorbid autism and epilepsy.

·        Sociability was improved and repetitive behaviors were reduced in female mice.

·        In males behavioral improvements were more limited.

·        Metabolic therapy may be especially beneficial in comorbid autism and epilepsy.

The core symptoms of autism spectrum disorder are poorly treated with current medications. Symptoms of autism spectrum disorder are frequently comorbid with a diagnosis of epilepsy and vice versa. Medically-supervised ketogenic diets are remarkably effective nonpharmacological treatments for epilepsy, even in drug-refractory cases. There is accumulating evidence that supports the efficacy of ketogenic diets in treating the core symptoms of autism spectrum disorders in animal models as well as limited reports of benefits in patients. This study tests the behavioral effects of ketogenic diet feeding in the EL mouse, a model with behavioral characteristics of autism spectrum disorder and comorbid epilepsy. Male and female EL mice were fed control diet or one of two ketogenic diet formulas ad libitum starting at 5 weeks of age. Beginning at 8 weeks of age, diet protocols continued and performance of each group on tests of sociability and repetitive behavior was assessed. A ketogenic diet improved behavioral characteristics of autism spectrum disorder in a sex- and test-specific manner; ketogenic diet never worsened relevant behaviors. Ketogenic diet feeding improved multiple measures of sociability and reduced repetitive behavior in female mice, with limited effects in males. Additional experiments in female mice showed that a less strict, more clinically-relevant diet formula was equally effective in improving sociability and reducing repetitive behavior. Taken together these results add to the growing number of studies suggesting that ketogenic and related diets may provide significant relief from the core symptoms of autism spectrum disorder, and suggest that in some cases there may be increased efficacy in females.

Ketogenic diet restores aberrant cortical motor maps and excitation-to-inhibition imbalance in the BTBR mouse model of autism spectrum disorder

·        The BTBR mouse has lower movement thresholds and larger motor maps relative to control mice.

·        The high-fat low-carbohydrate ketogenic diet raised movement thresholds and reduced motor map size in BTBR mice.

·        The ketogenic diet normalizes movement thresholds and motor map size to control levels.

Autism spectrum disorder (ASD) is an increasingly prevalent neurodevelopmental disorder characterized by deficits in sociability and communication, and restricted and/or repetitive motor behaviors. Amongst the diverse hypotheses regarding the pathophysiology of ASD, one possibility is that there is increased neuronal excitation, leading to alterations in sensory processing, functional integration and behavior. Meanwhile, the high-fat, low-carbohydrate ketogenic diet (KD), traditionally used in the treatment of medically intractable epilepsy, has already been shown to reduce autistic behaviors in both humans and in rodent models of ASD. While the mechanisms underlying these effects remain unclear, we hypothesized that this dietary approach might shift the balance of excitation and inhibition towards more normal levels of inhibition. Using high-resolution intracortical microstimulation, we investigated basal sensorimotor excitation/inhibition in the BTBR T + Itpr^tf/J (BTBR) mouse model of ASD and tested whether the KD restores the balance of excitation/inhibition. We found that BTBR mice had lower movement thresholds and larger motor maps indicative of higher excitation/inhibition compared to C57BL/6J (B6) controls, and that the KD reversed both these abnormalities. Collectively, our results afford a greater understanding of cortical excitation/inhibition balance in ASD and may help expedite the development of therapeutic approaches aimed at improving functional outcomes in this disorder.

Ketogenic diet modifies the gut microbiota in a murine model of autism spectrum disorder

Background

Gastrointestinal dysfunction and gut microbial composition disturbances have been widely reported in autism spectrum disorder (ASD). This study examines whether gut microbiome disturbances are present in the BTBR^T + tf/j (BTBR) mouse model of ASD and if the ketogenic diet, a diet previously shown to elicit therapeutic benefit in this mouse model, is capable of altering the profile.

Findings

Juvenile male C57BL/6 (B6) and BTBR mice were fed a standard chow (CH, 13 % kcal fat) or ketogenic diet (KD, 75 % kcal fat) for 10–14 days. Following diets, fecal and cecal samples were collected for analysis. Main findings are as follows: (1) gut microbiota compositions of cecal and fecal samples were altered in BTBR compared to control mice, indicating that this model may be of utility in understanding gut-brain interactions in ASD; (2) KD consumption caused an anti-microbial-like effect by significantly decreasing total host bacterial abundance in cecal and fecal matter; (3) specific to BTBR animals, the KD counteracted the common ASD phenotype of a low Firmicutes to Bacteroidetes ratio in both sample types; and (4) the KD reversed elevated Akkermansia muciniphila content in the cecal and fecal matter of BTBR animals.

Conclusions

Results indicate that consumption of a KD likely triggers reductions in total gut microbial counts and compositional remodeling in the BTBR mouse. These findings may explain, in part, the ability of a KD to mitigate some of the neurological symptoms associated with ASD in an animal model.

Effect of a ketogenic diet on autism spectrum disorder: A systematic review

·        We evaluated, throughout a systematic review, the studies with a relationship between autism and ketogenic diet.

·        Studies points to effects of KD on behavioral symptoms in ASD through the improve score in Childhood Autism Rating Scale (CARS).

·        Reviewed studies suggest effects of KD especially in moderate and mild cases of autism.

·        KD in prenatal VPA exposed rodents, as well in BTBR and Mecp2 mice strains, caused attenuation of some autistic-like features.

Autism spectrum disorder (ASD) is primarily characterized by impaired social interaction and communication, as well as restricted repetitive behaviours and interests. The utilization of the ketogenic diet (KD) in different neurological disorders has become a valid approach over time, and recently, it has also been advocated as a potential therapeutic for ASD. A MEDLINE, Scopus and Cochrane search was performed by two independent reviewers to investigate the relationship between ASD and the KD in humans and experimental studies. Of the eighty-one potentially relevant articles, eight articles met the inclusion criteria: three studies with animals and five studies with humans. The consistency between reviewers was κ = 0.817. In humans, the studies mainly focused on the behavioural outcomes provided by this diet and reported ameliorated behavioural symptoms via an improved score in the Childhood Autism Rating Scale (CARS). The KD in prenatal valproic acid (VPA)-exposed rodents, as well as in BTBR and Mecp2 mice strains, resulted in an attenuation of some autistic-like features. The limited number of reports of improvements after treatment with the KD is insufficient to attest to the practicability of the KD as a treatment for ASD, but it is still a good indicator that this diet is a promising therapeutic option for this disorder.

Conclusion

Since very many parents do not want to use drugs to treat autism, it is surprising more people do not try the ketogenic diet (KD) or at least the KD-lite, which is the Modified Atkins Diet (MAD).

I think you have to be pretty rigid about the MAD, if you go MAD-lite you will likely achieve little; rather like thinking you have a Mediterranean diet because you buy the occasional bottle of olive oil.

Many children with epilepsy who started out on the KD continue in adulthood with the Modified Atkins Diet (MAD).

There is anecdotal evidence that people with mitochondrial disease benefit from the KD.

All in all, it is hard to argue that the KD/MAD should not be the first choice for those choosing to treat autism by diet. It really does have science and clinical study to support it.

In some people with autism it appears that when you eat is as important as what you eat.  There can be strange behaviors just after eating, presumably caused by a spike in blood sugar, or for others before breakfast. 

In regressive autism (AMD) Dr Kelley, from Johns Hopkins, wrote that:- 

Another important clinical observation is that many children with mitochondrial diseases are more symptomatic (irritability, weakness, abnormal lethargy) in the morning until they have had breakfast, although this phenomenon is not as common in AMD as it is in other mitochondrial diseases.  In some children, early morning symptoms can be a consequence of compromised mitochondrial function, whereas, in others, a normal rise in epinephrine consequent to a falling blood glucose level in the early morning hours can elicit agitation, ataxia, tremors, or difficulty waking.  In children who normally sleep more than 10 hours at night, significant mitochondrial destabilization can occur by the morning and be evident in biochemical tests, although this is less common in AMD than in other mitochondrial disorders.  When early morning signs of disease are observed or suspected, giving uncooked cornstarch (1 g/kg; 1 tbsp = 10g) at bedtime effectively shortens the overnight fasting period.  Uncooked cornstarch, usually given in cold water, juice (other than orange juice), yogurt, or pudding, provides a slowly digested source of carbohydrate that, in effect, shortens overnight fasting by 4 to 5 hours.

I still find it rather odd that none of Dr Kelley's work on treating regressive autism has been published in any scientific or medical journal.  After all, he was a leading staff member at one of the world's leading hospitals.  He is no quack.  It is extremely wasteful of knowledge and clinical insights that could help improve the lives of something greater than 0.2% of the world's young children.  That is a lot of people.

Tideglusib, Repairing Dental Cavities, Wnt signaling, GSK-3 and Autism

Kings College in London seem to be more effective in dentistry than autism; they have just published research showing how they effectively regrew a tooth to repair a cavity.  That is rather clever.

Perhaps soon to be a thing of the past?

Using biodegradable collagen sponges to deliver the treatment, the team applied low doses of small molecule glycogen synthase kinase (GSK-3) inhibitors to the tooth. They found that the sponge degraded over time and that new dentine replaced it, leading to a complete, natural repair.

Natural tooth repair method, using Alzheimer's drug, could revolutionise dental treatments

The full paper is here:- 

Promotion of natural tooth repair by small molecule GSK3 antagonists

All very well, but what has this got to do with Autism?

As regular readers will be aware, autism turns out to be multigenic (it involves lots of different genes) and no single gene seems to account for more than one or two percent of cases.  A small number of any of hundreds of possible genes can be disturbed and then affect so-called signaling pathways  that control our bodies.  These pathways have evolved over millions of years and can seem quite unnecessarily complex.  The pathways overlap with each other and at certain critical points it seems like different genetic dysfunctions can lead to the same dysfunctional point, or nexus.  

We previously saw one such nexus, IPR3, suggested by Gargus:-

Is dysregulated IP3R calcium signaling a nexus where genes altered in ASD converge to exert their deleterious effect?

 but another one may be the Synaptic Wnt/GSK3β signaling hub. 

Synaptic Wnt/GSK3β Signaling Hub in Autism

We came across Wnt signaling in earlier posts.  Among other things, it relates to those RASopathies that often lead to cognitive dysfunction; but RAS dysfunction can also lead to common cancers, so called RAS-dependent cancers.

Wnt signaling is also involved in hair growth and hair greying, as one of our more adventurous readers experienced.  So using a PAK1 inhibitor to modulate the Wnt pathway may make your hair go grey.

BCL-2 is another autism gene that affects hair growth/loss.

It has been suggested by some of the very clever researchers (Chauhan and Chauhan) that the BDNF-Akt-Bcl2 anti-apoptotic signaling pathway is compromised in the brain of autistic subjects.

So while the gene Bcl-2 might be the dysfunction in one per cent of people, in more cases it is the pathway along which Bcl-2 lies, that is the problem.

There is also so called cross-talk between pathways connecting Bcl-2 to RAS.

Then you will see that some drugs affect both Bcl-2 and RAS.  So on the one hand things get much more complicated than just 20,000 different genes, but on the other hand the really good interventions will likely solve multiple dysfunctions. This is why we have talk about a nexus, or hub, where different dysfunctions lead to common points.

It makes sense to focus on identifying the limited number of these hubs, rather than getting lost in thousands of possibly dysfunctional genes. 

GSK-3 (Glycogen synthase kinase 3)

This area is very complex and really only a few people, mainly cancer researchers, and at least one dentist, understand it.

In essence, among other effects, GSK-3 inhibitors activate Wnt signaling. 

Glycogen synthase kinase 3 is a serine/threonine protein kinase that mediates the addition of phosphate molecules onto serine and threonine amino acid residues. First discovered in 1980 as a regulatory kinase for its namesake, Glycogen synthase ^]GSK-3 has since been identified as a kinase for over forty different proteins in a variety of different pathways.  In mammals GSK-3 is encoded by two known genes, GSK-3 alpha (GSK3A) and GSK-3 beta (GSK3B). GSK-3 has recently been the subject of much research because it has been implicated in a number of diseases, including Type II diabetes (Diabetes mellitus type 2), Alzheimer's Disease, inflammation, cancer, and bipolar disorder. 

Glycogen synthase kinase-3 (GSK3):regulation, actions, and diseases

Glycogen synthase kinase-3 (GSK3) may be the busiest kinase in most cells, with over 100 known substrates to deal with. How does GSK3 maintain control to selectively phosphorylate each substrate, and why was it evolutionarily favorable for GSK3 to assume such a large responsibility? GSK3 must be particularly adaptable for incorporating new substrates into its repertoire, and we discuss the distinct properties of GSK3 that may contribute to its capacity to fulfill its roles in multiple signaling pathways. The mechanisms regulating GSK3 (predominantly post-translational modifications, substrate priming, cellular trafficking, protein complexes) have been reviewed previously, so here we focus on newly identified complexities in these mechanisms, how each of these regulatory mechanism contributes to the ability of GSK3 to select which substrates to phosphorylate, and how these mechanisms may have contributed to its adaptability as new substrates evolved. The current understanding of the mechanisms regulating GSK3 is reviewed, as are emerging topics in the actions of GSK3, particularly its interactions with receptors and receptor-coupled signal transduction events, and differential actions and regulation of the two GSK3 isoforms, GSK3α and GSK3β. Another remarkable characteristic of GSK3 is its involvement in many prevalent disorders, including psychiatric and neurological diseases, inflammatory diseases, cancer, and others. We address the feasibility of targeting GSK3 therapeutically, and provide an update of its involvement in the etiology and treatment of several disorders.

GSK-3 and Autism

The good news is that the Alzheimer’s researchers have already developed a GSK-3 inhibitor, the current favourite is called Tideglusib.  This is also the one the clever dentists at King’s College used.

Researchers in Santiago, Chile, have proposed the role of GSK-3 in the onset and development of ASDs through direct modulation of Wnt/β-catenin signaling.

Synaptic Wnt/GSK3β Signaling Hub in Autism

 Figure 1: Wnt/β-catenin signaling in ASDs. Wnt binding to FZD-LRP5/6 complex receptor at the membrane recruits the destruction complex and inhibits GSK3β activity thus stabilizing β-catenin in the cytoplasm and nucleus. Activation of the Wnt/β-catenin pathway facilitates synaptic plasticity through the activation of voltage gated ion channels that allows activation of CAMK and CREB mediated transcription. Mutations in TSC associated with ASD prevent β-catenin degradation which results in a gain of function of the Wnt pathway. In the presynaptic terminal cadherin mediated cell adhesion between synapses is weakened by phosphorylation of β-catenin and synaptic vesicle clustering is enhanced through DVL1. Clustering is also dependent on NLGN/NRXN cell adhesion complexes. Both lithium (LiCl) and VPA activate Wnt/β-catenin signaling through inhibition of GSK3β activity. Conversely, in the absence of a Wnt ligand, activated GSK3β targets β-catenin for proteosome-mediated degradation. Mutations associated with DISC1 fail to inhibit GSK3β and thus activate Wnt/β-catenin pathway. In the presynaptic side Wnt signaling buffering of synaptic vesicles is inhibited and adherens junctions mediated by cadherins are strengthened.

This becomes more interesting because a clinical trial has already been put in motion to trial Tideglusib in autism.  I am not sure if the Canadian researchers are just trying an Alzheimer’s drug on the off-chance it might help autism, or whether they are really up to speed with their Wnt signaling pathway.  I suspect the former, but it does not really matter.

Tideglusib vs. Placebo in the Treatment of Adolescents  With Autism Spectrum Disorders (TIDE)

This might be of interest to our reader Alli in Switzerland.

Conclusion 

It pays to read the science reports that appear to have nothing to do with autism.

Enhancing the effect of Bumetanide in Autism

Many readers of this blog, and some of those who leave comments, are using the Bumetanide therapy proposed by Ben-Ari and Lemonnier.

At some point it should become an approved autism drug and Ben Ari has already patented it for use in Down Syndrome, so I guess that will come later on.

I have been developing my own add-on therapies that might help people for whom a high level of intracellular chloride is part of their autism, or indeed Down Sydrome.  If Bumetanide has a profound impact on your autism, this is almost certainly you.

Monty, aged 13 with ASD

After 4 years of Bumetanide, it continues to be effective and if Monty stops taking it there is a gradual cognitive decline over a few days, presumably as chloride concentration gradually increases.

In spite of an odd temporary Tourette’s type verbal tic that developed after an infection before Christmas, I have been getting plenty of feedback that Monty has got cleverer in 2017.  So it looks like some bumetanide add-on does indeed work.

The Colosseum

Monty’s big brother continues to be a fan of Lego and indeed Nanoblocks from Japan.  Nanoblocks is like extremely small Lego.

Having completed the Colossuem, his latest Nanoblocks model, he asked Monty “where is it?”.

Back came the answer, unprompted, “Italy”.

This was a big surprise.

That was not the answer big brother expected, he expected no answer or a silly answer like “over there”.

Add-ons

The first is potassium bromide (KBr) which was the original epilepsy therapy 150 years ago.  One of its effects is that the bromide (Br^-) part competes with chloride (Cl-) to enter neurons and bromide is known to be faster.  As a result some of the chloride inside cells is replaced by bromide.  Bromide is extremely similar to chloride, but is not reactive; this is why it can be used with any anti-epileptic drug (AED) without fear of negative interactions.

KBr has an extremely long half-life, meaning that if you take it every day it will take 4-6 weeks to reach its stable level in your body.

KBr is used for pediatric epilepsy in Germany and Austria and for epilepsy in pet dogs all over the world.  

A dose of 8mg/kg is far below the dose used for epilepsy, but does have a bumetanide enhancing effect in one 50kg boy.

The even more recent add-on is based on the experience of our reader Petra’s son with Asperger’s, who found that taking his bumetanide with Greek coffee seemed to make it more effective.

It turns out that dopamine is known to increase the effect of diuretics on the chloride cotransport NKCC2 in your kidneys.  There is a myth that coffee is a diuretic, but it is clear where this myth has come from.  Coffee will increase diuresis and so does caffeine.

In the brain it is the chloride cotransporter NKCC1 that is also blocked by bumetanide.  So it would be plausible that dopamine/coffee/caffeine it might have the same effect on NKCC1 as it does on the very similar NKCC2.

The cheap and widely available 50mg caffeine tablets do seem to serve as a proxy for a steaming cup of Greek coffee.  Indeed 50mg of caffeine is more like a weak cup of instant coffee.

I did much earlier propose the use of Diamox/ Acetazolamide to reduce chloride.  It seems that in some neurons 2/3 of the chloride enters via NKCC1 and 1/3 via the exchanger AE3.  Diamox/ Acetazolamide works via AE3.

Diamox has some other ion channel effects, making it useful in some epilepsy.

Some readers of this blog use Diamox, but in Monty it seems to cause reflux.

Caffeine is a very simple add-on to try.

Histidine for Allergy, but as an effective MTOR inhibitor?

Today’s post is likely to be of interest to those dealing with allergy and mast cell activation, but it may have broader implications for those with excess brain mTOR activity.

In the jargon, we are told that:

“enhanced mammalian target of rapamycin (mTOR) signaling in the brain has been implicated in the pathogenesis of autism spectrum disorder”.

I have discussed mTOR and mTOR inhibitors previously on this blog.

Amino acids, not just for body builders?

mTOR plays a key role in aging and many human diseases ranging from cancer, diabetes and obesity to autism and Alzheimer’s.

The greatest interest in mTOR seems to be in cancer care.  Many cancer genes and pathways are also involved in autism, so we can benefit from the cancer research.  Another autism gene that is also a cancer gene is PTEN.  PTEN is a tumor suppressor and in the most common male cancer, prostate cancer (PCa), what happens is that PTEN gets turned off and so the cancer continues to grow.  If you upregulate PTEN you slow the cancer growth and if you upregulated this gene in those people at risk of Pca perhaps they would never develop this cancer in the first place?  PTEN is upregulated by statin-type drugs and people already on this type of drug have better PCa prognoses.   The beneficial of effect of statins on PCa is known, but the mechanism being PTEN upregulation does not seem to have been noticed. No surprise there.

Inhibiting mTOR using cancer drugs is very expensive.

Other substances affecting mTOR include amino acids, growth factors, insulin, and oxidative stress.

The amino acid Leucine is an mTOR activator, we don’t need that.  We actually want the opposite effect and, at least in mice, we can get it from some of the other amino acids. 

Dietary interventions that reduce mTOR activity rescue autistic-like behavioral deficits in mice

          Highlights 

·        Amino acids, his, lys and thr, inhibited mTOR pathway in antigen-activated mast cells

·        Amino acids, his, lys and thr inhibited degranulation and cytokine production of mast cells

·        Amino acid diet reversed mTOR activity in the brain and behavioral deficits in allergic and BTBR mice.

Neuroprotective and anti-inflammatory diet reduced behavioral deficits only in allergic mice.

              Abstract

Enhanced mammalian target of rapamycin (mTOR) signaling in the brain has been implicated in the pathogenesis of autism spectrum disorder (ASD). Inhibition of the mTOR pathway improves behavior and neuropathology in mouse models of ASD containing mTOR-associated single gene mutations. The current study demonstrated that the amino acids histidine, lysine, threonine inhibited mTOR signaling and IgE-mediated mast cell activation, while the amino acids leucine, isoleucine, valine had no effect on mTOR signaling in BMMCs. Based on these results, we designed an mTOR-targeting amino acid diet (Active 1 diet) and assessed the effects of dietary interventions with the amino acid diet or a multi-nutrient supplementation diet (Active 2 diet) on autistic-like behavior and mTOR signaling in food allergic mice and in inbred BTBR T + Itpr3tf/J mice. Cow’s milk allergic (CMA) or BTBR male mice were fed a Control, Active 1, or Active 2 diet for 7 consecutive weeks. CMA mice showed reduced social interaction and increased self-grooming behavior. Both diets reversed behavioral impairments and inhibited the mTOR activity in the prefrontal cortex and amygdala of CMA mice. In BTBR mice, only Active 1 diet reduced repetitive self-grooming behavior and attenuated the mTOR activity in the prefrontal and somatosensory cortices. The current results suggest that activated mTOR signaling pathway in the brain may be a convergent pathway in the pathogenesis of ASD bridging genetic background and environmental triggers (food allergy) and that mTOR over-activation could serve as a potential therapeutic target for the treatment of ASD.

  

So in mice a combination of the three amino acids Histidine, Lysine and Threonine reduced brain mTOR activity and improved autism.

I did look at all three of these amino acids and their other effects and I choose Histidine. 

Histidine can be produced in adult humans in very small amounts, but in young children they need to obtain some from other sources, usually dietary.

Histidine is the precursor of histamine.  Histamine has both good and bad effects.

Histidine decarboxylase (HDC) is the enzyme that catalyzes the reaction that produces histamine from histidine with the help of vitamin B₆ as follows:

You can treat allergy by inhibiting HDC.

Tritoqualine, is an inhibitor of the enzyme histidine decarboxylase and therefore an atypical antihistamine,

You might think that having extra histidine would result in extra histamine, but this appears not to be the case.  There is a paradoxical reaction where increasing histadine actually seems to reduce the release of histamine from the mast cells that store it.  This may indeed be a case of feedback loops working in our favour.

So it seems that histidine may give two different benefits, it reduces IgE-mediated mast cell activation and it reduces mTOR signalling in the brain.

If the effect on mTOR is sufficient we would then benefit from an increase in autophagy, the cellular garbage disposal service that does not work well in autism.  We might eventually see a benefit from increased synaptic pruning which might be seen in improved cognition.  

Recap on mTOR and Synaptic Pruning

This has been covered in earlier posts.

In autism loss of mTOR-dependent macro-autophagy causes synaptic pruning deficits; this results in too many dendritic spines.

Source: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4159743/figure/F1/

A dendritic spine (or spine) is a small membranous protrusion from a neuron's dendrite that typically receives input from a single axon at the synapse. Dendritic spines serve as a storage site for synaptic strength and help transmit electrical signals to the neuron's cell body. The dendrites of a single neuron can contain hundreds to thousands of spines. In addition to spines providing an anatomical substrate for memory storage and synaptic transmission, they may also serve to increase the number of possible contacts between neurons.

A feature of autism is usually too many, but can be too few, dendritic spines.  In an earlier post we saw how the shape of individual spines affects their function.  The shape is constantly changing and can be influenced by external therapy. Wnt signaling affects dendritic spine morphology and so using this pathway you could fine-tune dendritic spine shape.  We did look at PAK1 inhibitors in connection with this.

Synaptic pruning is an ongoing process well into adolescence.

So it may be possible to improve synapse density and structure well after the onset of autism.

It should be noted that using Rapalogs, the usual mTOR inhibiting drugs, would have a negative effect in the minority of autism that feature hypo-active growth signalling.  That would be people born with small heads and small bodies.  So a child affected by the zika virus, might very likely exhibit autism and ID, but likely has too few dendritic spines and would then need more mTOR, rather than less.

Rapalog drugs like Everolimus are very expensive, but as in this recent paper do show effect in some autism. 

Everolimus improves neuropsychiatric symptoms in a patient with tuberous sclerosis carrying a novel TSC2 mutation

The mTOR pathway is a central regulator of mammalian metabolism and physiology, with important roles in the function of tissues including liver, muscle, white and brown adipose tissue, and the brain, and is dysregulated in human diseases, such as diabetes, obesity, depression, and certain cancers.

mTOR Complex 1 (mTORC1) is composed of MTOR, regulatory-associated protein of MTOR (Raptor), mammalian lethal with SEC13 protein 8 (MLST8) and the non-core components PRAS40 and DEPTOR. This complex functions as a nutrient/energy/redox sensor and controls protein synthesis. The activity of mTORC1 is regulated by rapamycin, insulin, growth factors, phosphatidic acid, certain amino acids and their derivatives (e.g., L-leucine and β-hydroxy β-methylbutyric acid), mechanical stimuli, and oxidative stress

Rapamycin inhibits mTORC1, and this appears to provide most of the beneficial effects of the drug (including life-span extension in animal studies). Rapamycin has a more complex effect on mTORC2.

How do amino acids affect mTOR?

This is not fully understood by anyone, but here is a relevant paper, for those interested.

The role of amino acid-induced mammalian target of rapamycin complex 1(mTORC1) signaling ininsulin resistance

Mammalian target of rapamycin (mTOR) controls cell growth and metabolism in response to nutrients, energy, and growth factors. Recent findings have placed the lysosome at the core of mTOR complex 1 (mTORC1) regulation by amino acids. Two parallel pathways, Rag GTPase-Ragulator and Vps34-phospholipase D1 (PLD1), regulate mTOR activation on the lysosome. This review describes the recent advances in understanding amino acid-induced mTOR signaling with a particular focus on the role of mTOR in insulin resistance.

We then discuss how mTORC1 activation by amino acids controls insulin signaling, a key aspect of body metabolism, and how deregulation of mTOR signaling can promote metabolic disease. 

Concluding remarks

Recent findings of new mediators and their regulatory mechanisms have broadened our understanding of amino acid-induced mTOR signaling. In addition to the role of the TSC1-TSC2-Rheb hub in transducing upstream signals from growth factors, stressors and energy to mTOR, the lysosomal regulation of mTOR functions as a platform to connect nutrient signals to the Rheb axis. Furthermore, two parallel pathways of amino acid signaling explain the diverse regulation of mTOR signaling. It is yet to be determined which regulators sense amino acids directly and whether the two pathways require separate amino acid sensing mechanisms. The identification of a direct amino acid sensor will shed light on these uncertainties.

A more integrated understanding of mTOR regulation in amino acid signaling will open the door for new therapeutic approaches for metabolic diseases, especially type 2 diabetes. Already, metformin, an antidiabetic drug, inhibits mTOR in an AMP-activated kinase (AMPK)-independent and Rag-dependent manner,⁶⁴ providing further support for the idea that the regulation of amino acid sensing could be a therapeutic target for diabetes.

How typical is the level of amino acids in autism?

Study of plasma amino acid levels in children with autism: An Egyptian sample

As regards essential amino acid levels, autistic children had significant lower plasma levels of leucine, isoleucine, phenylalanine, methionine and cystine than controls (P < 0.05),while there was no statistical difference in the level of tryptophan, valine, threonine, arginine, lysine and histidine (P > 0.05). In non-essential amino acid levels, phosphoserine was significantly raised in autistic children than in controls (P < 0.05). Autistic children had lower level of hydroxyproline, serine and tyrosine than controls (P < 0.05). On the other hand there was no significant difference in levels of taurin, asparagine, alanine, citrulline, GABA, glycine, glutamic acid, and ornithine (P > 0.05).

There was no significant difference between cases and controls as regards the levels of urea, ammonia, total proteins, albumin and globulins (alpha 1, alpha 2, beta and gamma) (P > 0.05).

  

Conclusion 

For the more common hyperactive pro growth signaling pathway types of autism, histidine should be a good amino acid, whereas for the hypoactive type, that might feature microcephaly, leucine should be a good choice.

Histidine is already used by some people to treat allergy.

Histidine does have numerous other functions and one relates to zinc, so it is suggested that people who supplement histidine add a little zinc. For this reason German histidine supplements thoughtfully all seem to include zinc.

Histidine also has some direct antioxidant effects and has an effect on Superoxide dismutase (SOD).

It is not clear how much histidine would be needed in humans to achieve the mTOR inhibiting effect found in mice.

The RDA for younger teenagers is histidine  850 mg and leucine 2450 mg.  What the therapeutic dose to affect mTOR in humans remains to be seen.

Histidine is also claimed to help ulcers, which is plausible.

For allergy some people are taking 1,500mg of histidine a day.

Neuroligins, Estradiol and Male Autism

Today’s post looks deeper into the biology of those people who respond to the drug bumetanide, which means a large sub-group of those with autism, likely those with Down Syndrome and likely some with schizophrenia.

It is a rather narrow area of science, but other than bumetanide treatment, there appears to be no research interest in further translating science into therapy.    So it looks like this blog is the only place to develop such ideas.

I did not expect this post would lead to a practical intervention, but perhaps it does. As you will discover, the goal would be to restore a hormone called estradiol to its natural higher level, perhaps by increasing an enzyme called aromatase, which appears to be commonly downregulated in autism.  This should increase expression of neuroligin 2, which should increase expression of the ion transporter KCC2; this will lower intracellular chloride and boost cognition.

It seems that those people using Atorvastatin may have already started this process, since this statin increases IGF-1 and insulin is one of the few things that increases the aromatise enzyme. 

This process is known as the testosterone-estradiol shunt.  In effect, by becoming slightly less male, you may be able to correct one of the key dysfunctions underlying autism. Options would include insulin, IGF-1, estradiol and a promoter of aromatase.




The testosterone – estradiol shunt

It would seem that this sub-group of autism is currently a little bit too male, which might be seen as early puberty and in other features. In this group the balance between testosterone and estradiol is affected not just in the brain, which is actually a good thing.  This should be measurable, if it is not visible.

  

NKCC1, KCC2 and AE3

As we have seen in earlier posts, some people with autism have too little of a transporter called KCC2 that takes chloride out of neurons and too much of NKCC1 that lets chloride in.  The result is an abnormally high level of chloride, which changes the way the GABA neurotransmitter functions.  This reduces cognitive function and increases the chance of seizures.

It is likely that a group may exist that has mis-expression of an ion exchanger called AE3. Potentially some have just an AE3 dysfunction and some may have AE3, KCC2 and NKCC1 mis-expression.  I will come back to this in a later post, but in case I forget, here is the link:

NKCC1 and AE3 Appear to Accumulate Chloride in Embryonic Motoneurons

“NKCC1 seems to be responsible for approximately two thirds of the steady-state chloride accumulation, whereas AE3 is responsible for the remaining third”

Genetic dysfunction of AE3 is not surprisingly associated with seizures and should respond to treatment with Diamox/Acetazolamide.

Block NKCC1 with Bumetanide and/or increase KCC2 expression

I was recently updating the Bumetanide researchers about my son’s near four years of therapy with their drug and my ideas to take things further.

My plan is to apply other methods to reduce intracellular chloride levels.  I think that over time, blocking NKCC1 with bumetanide may trigger a feedback loop that leads to a further increase in NKCC1 expression.  So bumetanide continues to work, but the effect is reduced. One way to further reduce intracellular chloride levels is to increase expression of KCC2, the transport that takes chloride out of neurons.

The best way to do this would be to understand why KCC2 is down regulated in the first place. I have touched on this in earlier posts, where I introduced neuroligin 2.

Today’s post will look at neuroligins in autism and how they are connected to the female hormone Estradiol.  We will also look at how estrogen receptor expression may help explain why more males have autism. Taken together this suggests that an  estrogen receptor agonist might be an effective autism therapy in this sub-group.

The difficulty with hormones is that, due to evolution, each one performs numerous different functions in different parts of the body and they react with each other.  So a little extra estradiol/estrogen might indeed increase neuroligin 2 expression and hence increase KCC2 expression in the brain, but it would have other effects elsewhere.  In female hormone replacement therapy care is usually taken to direct estradiol/estrogen to where it is needed, rather than sending it everywhere.

I suspect that in this subgroup of autism the lack of estradiol is body-wide, not just in the brain.  If not you would either need an estrogen receptor agonist that is cleverly developed to be brain specific, or take the much easier route of delivering an existing agonist direct to the brain, which may also be possible.

In the paper below NL2 and neuroligin-2 mean the same thing. 

An unexpected role of neuroligin-2 in regulating KCC2 and GABA functional switch

Background

GABA_A receptors are ligand-gated Cl^- channels, and the intracellular Cl^- concentration governs whether GABA function is excitatory or inhibitory. During early brain development, GABA undergoes functional switch from excitation to inhibition: GABA depolarizes immature neurons but hyperpolarizes mature neurons due to a developmental decrease of intracellular Cl^- concentration. This GABA functional switch is mainly mediated by the up-regulation of KCC2, a potassium-chloride cotransporter that pumps Cl^- outside neurons. However, the upstream factor that regulates KCC2 expression is unclear.

Results

We report here that KCC2 is unexpectedly regulated by neuroligin-2 (NL2), a cell adhesion molecule specifically localized at GABAergic synapses. The expression of NL2 precedes that of KCC2 in early postnatal development. Upon knockdown of NL2, the expression level of KCC2 is significantly decreased, and GABA functional switch is significantly delayed during early development. Overexpression of shRNA-proof NL2 rescues both KCC2 reduction and delayed GABA functional switch induced by NL2 shRNAs. Moreover, NL2 appears to be required to maintain GABA inhibitory function even in mature neurons, because knockdown NL2 reverses GABA action to excitatory. Gramicidin-perforated patch clamp recordings confirm that NL2 directly regulates the GABA equilibrium potential. We further demonstrate that knockdown of NL2 decreases dendritic spines through down-regulating KCC2.

Conclusions

Our data suggest that in addition to its conventional role as a cell adhesion molecule to regulate GABAergic synaptogenesis, NL2 also regulates KCC2 to modulate GABA functional switch and even glutamatergic synapses. Therefore, NL2 may serve as a master regulator in balancing excitation and inhibition in the brain.

  

Neuroligins and Neurexins

The following paper has an excellent explanation of neuroligins, neurexins and their role in autism.  It does get complicated.

Neuroligins and Neurexins Link Synaptic Function to Cognitive Disease

Neurexins (Nrxns) and neuroligins (Nlgns) are arguably the best characterized synaptic cell-adhesion molecules, and the only ones for which a specifically synaptic function was established^8,9. In the present review, we will describe the role of Nrxns and Nlgns as synaptic cell-adhesion molecules that act in an heretofore unanticipated fashion. We will show that they are required for synapse function, not synapse formation; that they affect trans-synaptic activation of synaptic transmission, but are not essential for synaptic cohesion of the pre- and postsynaptic specializations; and that their dysfunction impairs the properties of synapses and disrupts neural networks without completely abolishing synaptic transmission as^10–12. As cell-adhesion molecules, Nrxns and Nlgns probably function by binding to each other and by interacting with intracellular proteins, most prominently PDZ-domain proteins, but the precise mechanisms involved and their relation to synaptic transmission remain unclear. The importance of Nrxns and Nlgns for synaptic function is evident from the dramatic deficits in synaptic transmission in mice lacking Nrxns or Nlgns.

As we will describe, the role of Nrxns and Nlgns in synaptic function almost predestines them for a role in cognitive diseases, such as schizophrenia and autism spectrum disorders (ASDs), that have been resistant to our understanding. One reason for the difficulties in understanding cognitive diseaseas is that they may arise from subtle changes in a subset of synapses in a neural circuit, as opposed to a general impairment of all synapses in all circuits. As a result, the same molecular alteration may produce different circuit changes and neurological symptoms that are then classified as distinct cognitive diseases. Indeed, recent studies have identified mutations in the genes encoding Nrxns and Nlgns as a cause for ASDs, Tourette syndrome, mental retardation, and schizophrenia, sometimes in patients with the same mutation in the same family^13–27. Viewed as a whole, current results thus identify Nrxns and Nlgns as trans-synaptic cell-adhesion molecules that mediate essential signaling between pre- and postsynaptic specializations, signaling that performs a central role in the brain’s ability to process information and that is a key target in the pathogenesis of cognitive diseases.

Neuroligins and neurexins in autism

ASDs are common and enigmatic diseases. ASDs comprise classical idiopathic autism, Asperger’s syndrome, Rett syndrome, and pervasive developmental disorder not otherwise specified^73,74. Moreover, several other genetic disorders, such as Down syndrome, Fragile-X Mental Retardation, and tuberous sclerosis, are frequently associated with autism. Such syndromic forms of autism and Rett syndrome are usually more severe due to the nature of the underlying diseases. The key features of ASDs are difficulties in social interactions and communication, language impairments, a restricted pattern of interests, and/or stereotypic and repetitive behaviors. Mental retardation (~70% of cases) and epilepsy (~30% of cases) are frequently observed; in fact, the observation of epilepsy in patients with ASDs has fueled speculation that autism may be caused by an imbalance of excitatory vs. inhibitory synaptic transmission. In rare instances, idiopathic autism is associated with specialized abilities, for example in music, mathematics, or memory. The relation of ASDs to other cognitive diseases such as schizophrenia and Tourette’s syndrome is unclear. As we will see below with the phenotypes caused by mutations in Nlgns and Nrxns, the boundaries between the various disorders may not be as real as the clinical manifestations suggest.

A key feature of ASDs is that they typically develop before 2–3 years of age^73,74. ASDs thus affect brain development relatively late, during the time of human synapse formation and maturation. Consistent with this time course, few anatomical changes are associated with ASDs⁷⁵. An increase in brain size was repeatedly reported⁷⁶, but is not generally agreed upon⁷⁵. Thus, similar to other cognitive diseases, ASDs are not a disorder of brain structure but of brain function. Among cognitive diseases, ASDs are the most heritable (~ 80%), suggesting that they are largely determined by genes and not the environment. ASDs exhibit a male:female ratio of approximately 4:1, indicating that ASDs involve the X-chromosome directly, or that the penetrance of pathogenic genes is facilitated in males^73,74.

Mutations in many genes have been associated with familial ASDs. A consistent observation emerging from recent studies is the discovery of mutations in the genes encoding Nrxn1, Nlgn3, and Nlgn4. Specifically, seven point mutations, two distinct translocation events, and four different large-scale deletions in the Nrxn1 gene were detected in autistic patients^13–18. Ten different mutations in the Nlgn4 gene were observed (2 frameshifts, 5 missense mutations, and 3 internal deletions), and a single mutation in the Nlgn3 gene (the R451C substitution)^21–24. Besides these mutations, five different larger deletions of X-chromosomal DNA that includes the Nlgn4 locus (referred to as copy-number variations) were detected in autism patients^18,25–27.

In addition to the Nrxn/Nlgn complex, mutations in the gene encoding Shank3 – an intracellular scaffolding protein that binds indirectly to Nlgns via PSD-95 and GKAP (Fig. 1)⁶⁶ – may also be a relatively frequent occurrence in ASDs. An astounding 18 point mutations were detected in the Shank3 gene in autistic patients, in addition to several cases containing CNVs that cover the gene^18,77–82. Indeed, the so-called terminal 22q deletion syndrome is a relatively frequent occurrence that exhibits autistic features, which have been correlated with the absence of the Shank3 gene normally localized to this chromosome section. Shank3 is particularly interesting because it not only indirectly interacts with Nlgns, but also directly binds to CIRL/Latrophilins which in turn constitute α-latrotoxin receptors similar to Nrxns, suggesting a potential functional connection between Shank3 and Nrxns⁸³.

Overall, the description of the various mutations in the Nrxn/Nlgn/Shank3 complex appears to provide overwhelming evidence for a role of this complex in ASDs, given the fact that in total, these mutations account for a significant proportion of autism patients. It should be noted, however, that two issues give rise to skepticism to the role of this complex in ASDs.

First, at least for some of the mutations in this complex, non-symptomatic carriers were detected in the same families in which the patients with the mutations were found. Whereas the Nlgn3 and Nlgn4 mutations appear to be almost always penetrant in males, and even female carriers with these mutations often have a phenotype, the Shank3 point mutations in particular were often observed in non-symptomatic siblings^77,78. Thus, these mutations may only increase the chance of autism, but not actually cause autism.

Second, the same mutations can be associated with quite different phenotypes in different people. For example, a microdeletion in Nlgn4 was found to cause severe autism in one brother, but Tourette’s syndrome in the other²⁶. This raises the issue whether the ‘autism’ observed in patients with mutations in these genes is actually autism, an issue that could also be rephrased as the question of whether autism is qualitatively distinct from other cognitive diseases, as opposed to a continuum of cognitive disorders. In support of the latter idea, two different deletions of Nrxn1α have also been observed in families with schizophrenia^19,20, indicating that there is a continuum of disorders that involves dysfunctions in synaptic cell adhesion and manifests in different ways. Conversely, very different molecular changes may produce a similar syndrome, as exemplified by the quite different mutations that are associated with ASDs⁸⁴.

At present, the relation between the Nrxn/Nlgn synaptic cell-adhesion complex and ASDs is tenuous. On one hand, many of the mutations observed in familial ASD are clearly not polymorphisms but deleterious, as evidenced by the effect of these mutations on the structure or expression of the corresponding genes, and by the severe autism-like phenotypes observed in Nlgn3 and Nlgn4 mutant mice^85–87. On the other hand, the nonlinear genotype/phenotype relationship in humans, evident from the only 70–80% heritability and from the occasional presence of mutations in non-symptomatic individuals, requires explanation. Elucidating the underlying mechanisms for this incomplete genotype/phenotype relationship is a promising avenue to insight into the genesis of autism. Furthermore, in addition to the link of Nrxn1α mutations to schizophrenia^19,20, linkage studies have connected Nrxn3 to different types of addiction^88,89. It is possible that because of the nature of their function, mutations in genes encoding Nrxns and Nlgns constitute hotspots for human cognitive diseases.

  

As you will have seen from the above paper, whose author seems to be very well informed of the broader picture (a continuum of disorders that involves dysfunctions in synaptic cell adhesion, and even the link to addiction), neuroligins and neurexins are very relevant to autism and other cognitive disease.

Let’s get back on subject and focus on Neuroligin 2 

The very recent paper below mentions sensory processing defects and NLG2 alongside what we already have figured out so far.

Neuroligin 2 nonsense variant associated with anxiety, autism, intellectual disability, hyperphagia, and obesity

Abstract

Neuroligins are post-synaptic, cellular adhesion molecules implicated in synaptic formation and function. NLGN2 is strongly linked to inhibitory, GABAergic signaling and is crucial for maintaining the excitation-inhibition balance in the brain. Disruption of the excitation-inhibition balance is associated with neuropsychiatric disease. In animal models, altered NLGN2 expression causes anxiety, developmental delay, motor discoordination, social impairment, aggression, and sensory processing defects. In humans, mutations in NLGN3 and NLGN4 are linked to autism and schizophrenia; NLGN2 missense variants are implicated in schizophrenia. Copy number variants encompassing NLGN2 on 17p13.1 are associated with autism, intellectual disability, metabolic syndrome, diabetes, and dysmorphic features, but an isolated NLGN2 nonsense variant has not yet been described in humans. Here, we describe a 15-year-old male with severe anxiety, obsessive-compulsive behaviors, developmental delay, autism, obesity, macrocephaly, and some dysmorphic features. Exome sequencing identified a heterozygous, de novo, c.441C>A p.(Tyr147Ter) variant in NLGN2 that is predicted to cause loss of normal protein function. This is the first report of an NLGN2 nonsense variant in humans, adding to the accumulating evidence that links synaptic proteins with a spectrum of neurodevelopmental phenotypes

After some investigation I learned that both estradiol/estrogen and progesterone increase expression of neuroligin 2, at least in rats.

Increasing neuroligin 2/NLGN2/NL2 looks a promising strategy.

Gene expression analysis of the pro-oestrous-stage rat uterus reveals neuroligin 2 as a novel steroid-regulated gene

In addition, neuroligin 2 mRNA levels were increased by both 17beta-oestradiol (E(2)) and P(4), although P(4) administration upregulated gene expression to a greater extent than injection of E(2). These results indicate that neuroligin 2 gene expression in the rat uterus is under the control of both E(2) and P(4), which are secreted periodically during the oestrous cycle.[1]

So a female steroid-regulated gene is down-regulated in male-dominated autism.  Another example of the protective nature of female hormones?  I think it is.

Estrogens Suppress a Behavioral Phenotype in Zebrafish Mutants of the Autism Risk Gene, CNTNAP2

Highlights

·         Zebrafish mutants of the autism risk gene cntnap2 have GABAergic neuron deficits

·         High-throughput behavioral profiling identifies nighttime hyperactivity in mutants

·         cntnap2 mutants exhibit altered responses to GABAergic and glutamatergic compounds

·         Estrogenic compounds suppress the cntnap2 mutant behavioral phenotype

Summary

Autism spectrum disorders (ASDs) are a group of devastating neurodevelopmental syndromes that affect up to 1 in 68 children. Despite advances in the identification of ASD risk genes, the mechanisms underlying ASDs remain unknown. Homozygous loss-of-function mutations in Contactin Associated Protein-like 2 (CNTNAP2) are strongly linked to ASDs. Here we investigate the function of Cntnap2 and undertake pharmacological screens to identify phenotypic suppressors. We find that zebrafish cntnap2 mutants display GABAergic deficits, particularly in the forebrain, and sensitivity to drug-induced seizures. High-throughput behavioral profiling identifies nighttime hyperactivity in cntnap2 mutants, while pharmacological testing reveals dysregulation of GABAergic and glutamatergic systems. Finally, we find that estrogen receptor agonists elicit a behavioral fingerprint anti-correlative to that of cntnap2 mutants and show that the phytoestrogen biochanin A specifically reverses the mutant behavioral phenotype. These results identify estrogenic compounds as phenotypic suppressors and illuminate novel pharmacological pathways with relevance to autism.

Estrogen receptor expression may help explain why more males have autism

Estrogen is known to help protect premenopausal women from maladies such as stroke and impaired cognition. Exposure to high levels of the male hormone testosterone during early development has been linked to autism, which is five times more common in males than females.

The new findings of reduced expression of estrogen receptor beta as well as that of an enzyme that converts testosterone to estrogen could help explain the high testosterone levels in autistic individuals and higher autism rates in males, Pillai said.

It was the 5-to-1 male-to-female ratio along with the testosterone hypothesis that led Pillai and his colleagues to pursue whether estrogen might help explain the significant gender disparity and possibly point toward a new treatment.

"The testosterone hypothesis is already there, but nobody had investigated whether it had anything to do with the female hormone in the brain," Pillai said. "Estrogen is known to be neuroprotective, but nobody has looked at whether its function is impaired in the brain of individuals with autism. We found that the children with autism didn't have sufficient estrogen receptor beta expression to mediate the protective benefits of estrogen."

Comparing the brains of 13 children with and 13 children without autism spectrum disorder, the researchers found a 35 percent decrease in estrogen receptor beta expression as well as a 38 percent reduction in the amount of aromatase, the enzyme that converts testosterone to estrogen.

Levels of estrogen receptor beta proteins, the active molecules that result from gene expression and enable functions like brain protection, were similarly low. There was no discernable change in expression levels of estrogen receptor alpha, which mediates sexual behavior.

Estrogen receptor expression may help explain why more males have autism

The new findings of reduced expression of estrogen receptor beta as well as that of an enzyme that converts testosterone to estrogen could help explain the high testosterone levels in autistic individuals and higher autism rates in males

They also plan to give an estrogen receptor beta agonist -- which should increase receptor function -- to a mouse with generalized inflammation and signs of autism to see if it mitigates those signs. Inflammation is a factor in many diseases of the brain and body, and estrogen receptor beta agonists already are in clinical trials for schizophrenia.

The following trial was run by a psychiatrist; when I looked at why he thought estrogen might improve schizophrenia, there was no biological explanation.  He is trying to avoid the possible side effects by using of a selective estrogen receptor agonist.  I hope the trial successful.  The question is whether his subjects are starting out as extreme male or just male.

The Efficacy and Safety of a Selective Estrogen Receptor Beta Agonist (LY500307) for Negative Symptoms and Cognitive Impairment Associated With Schizophrenia (Beta)

http://grantome.com/grant/NIH/UH2-TR000955-01

Several lines of investigation have supported the potential therapeutic effects of estrogen for negative and cognitive symptoms in schizophrenia. However, estrogen has had limited therapeutic application for male and premenopausal patients with schizophrenia because of tolerability concerns including uterine cancer liability, and heart disease and feminization effects in men. Selective Estrogen Receptor Beta (ER beta) agonists are a new class of treatments that are relatively free of estrogen's primary side effects and yet have demonstrated estrogen-like effects in brain including improvement in cognitive performance and an association to extremes in social behavior. Thus, these agents may have a therapeutic role for cognitive and negative symptoms in schizophrenia. The primary objectives of this application are to determine if the selective ER beta agonist LY500307 significantly improves negative and cognitive symptoms in patients with schizophrenia. Secondary aims include assessing LY500307 effects on cerebral blood flow during working and episodic memory tasks with fMRI, and electrophysiological indices of auditory sensory processing and working memory. A single seamless phase 1b/2a adaptive design will be used to evaluate two LY500307 doses (25 mg/day and 75 mg/day) in the first stage of the trial (year 1 of the application) to determine which dose should be advanced to stage 2 (years 2and 3 of the application) or if the trial should be discontinued.

More generally:-

Learning and memory: Steroids and epigenetics

Highlights

Steroid hormones exert a considerable influence on several aspect of cognition.

Estrogens and androgens exert positive effects on cognitive functions.

Progesterone and allopregnanolone have variable effects on cognitive functions.

Glucocorticoids act to encode and store information of the emotional events.

Epigenetic modifications are a powerful mechanism of memory regulation.

Conclusion

More female hormones and less male hormones? Seems a good idea.

More of the aromatase enzyme ?  There are numerous drugs to reduce/inhibit aromatase but not specifically to increase it.

Insulin does increase aromatase, as does alcohol and being overweight.

The clever thing to do would be to just correct the reduced level of aromatase, or wait for a selective estrogen receptor beta agonist like LY500307 to come to the market.

In those who are extreme male, a little estradiol might be the simple solution, but not the amount that is currently taken by those that abuse it.  Yes people abuse estradiol – males who want to be females.

Antonio Hardan at Stanford did trial high dose pregnenolone, another hormone mainly found in females, that should increase progesterone.

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

Overall, pregnenolone was modestly effective and well-tolerated in individuals with ASD.

This steroid should increase the level of progesterone and so might be expected to cause some side effects in males. You would expect it to have an effect on anxiety, but as we saw in an earlier post it should be quite dose specific.

Why Low Doses can work differently, or “Biphasic, U-shaped actions at the GABAa receptor”

So Hardan may have just picked the "wrong dose".

If he would like to trial 0.3mg of oral estradiol in adults with autism, I think he might find a positive response.