Treatment of Autism with low-dose Phenytoin, yet another AED

I do like coincidences and I do like not struggling to find a picture for my posts. 

Phenytoin (Dilantin) is a drug that appeared in the novel and film, One Flew Over the Cuckoo's Nest, but then it was not used in low-doses.

Today’s post follows from a comment I received about using very low doses of anti-epileptic drugs (AEDs) in autism.

First of all a quick recap.

Clonazepam was discovered by Professor Catterall, over in Seattle, to have the effect of modifying the action of the neurotransmitter GABA to make it inhibitory, at tiny doses that would be considered to be sub-clinical (i.e. ineffective).

Valproate, another AED, was discovered by one of this blog’s readers also to have an “anti-autism” effect in tiny doses of 1 mg/kg.

A psychiatrist from Australia, Dr Bird, specialized in adults with ADHD has just published a paper about the benefit of low-dose phenytoin in adult autism.  The same psychiatrist has also earlier encountered the effect of low dose valproate in ADHD (autism lite).

The treatment of autism with low-dose phenytoin: a case report

Significantly, this beneficial effect of sodium valproate appeared to have a narrow therapeutic window, with the optimal range between 50 and 200mg daily. A complete loss of efficacy frequently occurred above a dose of 400mg.

Case presentation

My patient was a 19-year-old man diagnosed in early childhood with ADHD and ASD

a sublingual test dose of approximately 2mg phenytoin was administered

Within 10 minutes of taking the sublingual phenytoin he reported a reduction in the effort required to contribute to conversation and was able to sustain eye contact both when listening and speaking. He was surprised about the effortless nature of his eye gaze and also commented that he had never done this before.

The following day he started taking compounded 2mg phenytoin capsules in the morning in conjunction with his methylphenidate.

After two weeks both he and his mother stated that his communication with the family had improved and there had been no aggressive outbursts.

Over the next four weeks he became inconsistent in taking the phenytoin, and then ceased altogether. His behavior reverted to the previous pattern of poor social interaction; he became oppositional with outbursts of anger and physical violence.

Nine months later he resumed taking the phenytoin, this time as a single 4mg capsule in the morning. After his first dose there was an improvement of his social behavior similar to his previous response, although there was an apparent deterioration in the late afternoon. The dose was increased from 4mg to 5mg and a larger capsule formulated to try and prolong the release of the phenytoin. This appeared to achieve a more consistent improvement in behavior throughout the day, evident both at home and at work. Increases in the dose above 5mg were not associated with any additional benefit. He remained on the 5mg dose of phenytoin for over 18 months and reported that his work performance had consistently improved sufficient to increase his working hours and his level of responsibility. The violence and destruction at home abated. His confidence improved and for the first time he has established and sustained peer-appropriate friendships.

I hypothesize that, in a similar mechanism to the low-dose clonazepam in this animal model of autism, low-dose phenytoin may enhance GABA neurotransmission, thereby correcting the imbalance between the GABAergic and glutaminergic systems.

Phenytoin

Now let us look at Phenytoin and see if we agree with Dr Bird's hypothesis that the mechanism is the same as low dose clonazepam. 

The accepted method of action is that working as a voltage gate sodium channel blocker.  GABA is not mentioned.

Phenytoin, by acting on the intracellular part of the voltage-dependent sodium channels, decreases the sodium influx into neurons and thus decreases excitability.

The antiepileptic activity of phenytoin was found during systematic research in animals: it suppresses the tonic phase but not the clonic phase elicited by an electric discharge and is not very active against the attacks caused by pentylenetetrazol.

Phenytoin was the first non-sedative antiepileptic to be used in therapeutics.

It decreases the intensity of facial neuralgia and has an antiarrhythmic effect.

 But as I dug a little deeper, I found from 1995:-

Modulation of the gamma-aminobutyric acid type A receptor by the antiepileptic drugs carbamazepine and phenytoin

 Abstract

We report here that carbamazepine and phenytoin, two widely used antiepileptic drugs, potentiate gamma-aminobutyric acid (GABA)-induced Cl- currents in human embryonic kidney cells transiently expressing the alpha 1 beta 2 gamma 2 subtype of the GABAA receptor and in cultured rat cortical neurons. In cortical neuron recordings, the current induced by 1 microM GABA was enhanced by carbamazepine and phenytoin with EC50 values of 24.5 nM and 19.6 nM and maximal potentiations of 45.6% and 90%, respectively. The potentiation by these compounds was dependent upon the concentration of GABA, suggesting an allosteric modulation of the receptor, but was not antagonized by the benzodiazepine (omega) modulatory site antagonist flumazenil. Carbamazepine and phenytoin did not modify GABA-induced currents in human embryonic kidney cells transiently expressing binary alpha 1 beta 2 recombinant GABAA receptors. The alpha 1 beta 2 recombinant is known to possess functional barbiturate, steroid, and picrotoxin sites, indicating that these sites are not involved in the modulatory effects of carbamazepine and phenytoin. When tested in cells containing recombinant alpha 1 beta 2 gamma 2, alpha 3 beta 2 gamma 2, or alpha 5 beta 2 gamma 2 GABAA receptors, carbamazepine and phenytoin potentiated the GABA-induced current only in those cells expressing the alpha 1 beta 2 gamma 2 receptor subtype. This indicates that the nature of the alpha subunit isoform plays a critical role in determining the carbamazepine/phenytoin pharmacophore. Our results therefore illustrate the existence of one or more new allosteric regulatory sites for carbamazepine and phenytoin on the GABAA receptor. These sites could be implicated in the known anticonvulsant properties of these drugs and thus may offer new targets in the search for novel antiepileptic drugs.

So not only is it possible that phenytoin can modulate the behaviour of the GABA_A receptor like Dr Catterall did with Clonazepam, but carbamazepine is yet another known AED with this effect.

So I expect someone will also go and patent low-dose carbamazepine for autism.

We potentially now have a wide range of low dose AEDs for autism.

·        Valproate (1000 to 2000 mg for adults as AED) at a dose of 1-2 mg/kg

·        Clonazepam (up to 20 mg for adults as an AED)   at a dose of 1.7mcg/kg

·        Phenytoin (up to 600 mg for adults as an AED) at a dose of 0.05 mg/kg

·        Carbamazepine (up to 1,200 mg for adults as an AED) no data for the low dose!

We also have two other drugs that are used as AEDs in high doses and have been used in autism with much lower doses.  I do not have any evidence to show that they affect GABA_A receptors.  I think their method of action is unrelated to GABA, or sodium channels.

  

·        Piracetam (up to 24 g as an AED) at a dose of 400 to 800 mg

·        Vinpocetine (up to 45mg for adults as an AED)  at a dose of 1 to 5 mg

Both Piracetam and Vinpocetine are classed as drugs in Europe and supplements in the US.  Both are also used as cognitive enhancers. Both have numerous possible modes of action.  They may not help with behavioral problems, but may well improve cognition.

Interestingly, a clinical trial is underway to look at the cognitive effect of moderate doses of Vinpocetine in epilepsy.

Cognitive Effects of Vinpocetine in Healthy Adults and Patients With Epilepsy

Modified Use of Anti-Epileptic Drugs (AEDs) at Low Doses in Autism

As readers will be aware, many people with more severe autism are also affected by epilepsy.  Siblings of those with autism also seem to be at greater risk of epilepsy.

There are frequent comments that once starting on AEDs (Anti-Epileptic Drugs) aspects of autism also seem to improve.  This should not be surprising given the suggested action of these drugs and the overlapping causes of epilepsy and autism.

Today’s post is prompted by the observation that in very low, apparently sub-therapeutic, doses some AEDs seem to improve autism in some cases.  This is relevant because the usual high doses of these drugs are associated with some side effects and indeed a small number can be habit forming.

What is epilepsy?

The cause of most cases of epilepsy is unknown.

Genetics is believed to be involved in the majority of cases, either directly or indirectly. Some epilepsies are due to a single gene defect (1–2%); most are due to the interaction of multiple genes and environmental factors.  Each of the single gene defects is rare, with more than 200 in all described.  Most genes involved affect ion channels, either directly or indirectly. These include genes for ion channels themselves, enzymes, GABA, and G protein-coupled receptors.

Much of the above applies equally to autism, including the genetic dysfunctions associated with GABA.  The ion channel dysfunctions in epilepsy are thought to be mainly sodium channels, like Nav1.1.  We previously came across this channel when looking at Dravet Syndrome.

Dravet Syndrome

Dravet Syndrome is rare form of epilepsy, but is highly comorbid with autism.  It is cause by dysfunctions of the SCN1A gene, which encodes the sodium ion channel Nav1.1.  There is a mouse model of this condition, used in autism research.  Dravet Syndrome is known to cause a down-regulation of GABA (the neurotransmitter) signaling.  We saw how tiny doses of Clonazepam corrected this dysfunction in mice.

Known ASD-associated mutations occur in the genes CACNA1C, CACNA1F, CACNA1G, and CACNA1H, which encode the L-type calcium channels Cav1.2 and Cav1.4 and the T-type calcium channels Cav3.1 and Cav3.2, respectively; the sodium channel genes SCN1A and SCN2A, which encode the channels Nav1.1 and Nav1.2, respectively; and the potassium channel genes KCNMA1 and KCNJ10, which encode the channels BKCa and Kir4.1, respectively.

Channelopathies in Autism - Treating Nav1.1 with Clonazepam

Dr Catterall, the researcher, then went on to test low dose clonazepam in a different mouse of autism model and found it equally effective.  It also appears to work in some human forms of autism.

Sodium Valproate

Valproate is a long established epilepsy drug that has also been used widely as a mood stabilizer and particularly to treat Bipolar Disorder.

One side effect can be hair loss.  Hair loss/growth and also hair greying are frequently connected with drugs and genes linked to autism (BCL-2, biotin, TRH etc).

One regular reader of this blog has pointed out that a tiny dose of Valproate, when combined with Bumetanide, appeared to have a significant and positive effect.  We know that bumetanide works via NKCC1 and the GABA_A receptor to make GABA more inhibitory.

Many modes of action are proposed for Valproate, but the most mentioned one is that it increases GABA “turnover”; so it would make sense that having shifted the balance from excitatory to inhibitory, a stimulation to increase GABA signaling might be beneficial.

What is odd is that this is happening at a dose 20 times less than used in epilepsy, bipolar or mood disorders.

The use of Clonazepam, discovered by Dr Catterall, is also at a dose 20 to 50 times less than the typical dose.

Clonazepam and Valproate are both AEDs.  There are not so many of these drugs and while using them at high doses, without dire need, might be highly questionable, their potential effectiveness at tiny doses is very interesting.

Clonazepam is a Benzodiazepine in the table below.

The above table is from the following paper:-

 Mechanisms of action of antiepileptic drugs

Low Dose Clonazepam

Low dose Clonazepam was shown to be effective by its action of modulating the GABA_A receptor to make it more inhibitory.  There are different types of GABA_A receptor and the low dose effect was sub-unit specific.  Other benzodiazepine drugs were found to have the opposite effect.

The mouse research showed that the effect only appeared with a narrow range of low dosages.

Low Dose Valproate

Valproate is known to affect sodium channels like Nav1.1, but also some calcium channels.

For an insight into some known potential effects of Valproate, here is a paper from the US National Institute of Mental Health:-

Therapeutic Potential of MoodStabilizers Lithium and Valproic Acid: Beyond Bipolar Disorder

In the paper it highlights the less well known effects of Valproate:-

inhibits HDACs

Modulates Neurotrophic and Angiogenic Factors (BDNF, GDNF, VEGF)

PI3K/Akt Pathway

Wnt/β-Catenin Pathway

MEK/ERK Pathway

Oxidative Stress Pathways

Enhanced Neuroprotection

Enhancing the Homing and Migratory Capacity of Stem Cells

Here is a list of the suggested new applications of Valproate, many highly appropriate to many types of autism:-

       Repurposing Mood Stabilizers for CNS Disorders Beyond BD

       A. Stroke

       1. Lithium-Induced Effects in Experimental Stroke Models

       a. Neuroprotection and behavioral improvement

       b. Anti-excitotoxic and anti-apoptotic effects

       c. Anti-inflammation

       d. Angiogenesis

       e. Neurogenesis

       f. Effects on MSC migration after transplantation

       2. VPA-Induced Effects in Experimental Stroke Models

       a. Neuroprotective effects and behavioral benefits

       b. Anti-inflammation

       c. BBB protection

       d. Angiogenesis

       e. Neurogenesis

       B. TBI

       1. Lithium-Induced Effects on Neurodegeneration, Neuroinflammation, Behavioral Improvement, and Aβ Accumulation in Models of TBI

       2. VPA-Induced Effects on Neurodegeneration, Neuroinflammation, and Functional Recovery in Models of TBI

       3. Clinical Trials of VPA Treatment in TBI

Having read that paper I am now not surprised that a tiny dose of valproate can have a positive behavioral effect in autism.  What would be interesting to know is how the effects and dominant modes of action vary with dosage.  I presume the dosage has been optimized to control/prevent seizures.

Valproate is a cheap drug and is available as a liquid, so accurate low dosing is possible.  It has been shown to be neuro-protective, even shown promise as a treatment for traumatic brain injury.

While not written about autism, some of you may find the following collection of research interesting:-

Brain Protection in Schizophrenia, Mood and Cognitive Disorders

It does talk about the wider potential use of Valproate, but not at tiny doses.

Stiripentol

Interestingly, an orphan drug was developed in the European Union to treat Dravet Syndrome.  It is included on the list of AEDs above.

Even though that drug, Stiripentol, is not approved by the FDA, most sufferers in the US are able to acquire it under the FDA’s Personal Importation Policy(PIP).

So it is indeed possible to acquire drugs prior to approval in your home country.

Hopefully, once Bumetanide is approved for autism in Europe, similarly people will be able to access it easily in the US.

I wonder if anybody with Dravet Syndrome has tried low dose Clonazepam.  In theory it should be helpful.

GABA A Receptors in Autism – How and Why to Modulate Them

This post will get complicated, since it will look at many aspects of the GABA _A receptor, rather than just a small fraction that usually appear in the individual pieces of the scientific literature. 

It was prompted by comments I have received from regular readers, regarding Bumetanide, Clonazepam, epilepsy and whether there might be alternatives with the same effect.  So it is really intended to answer some complex issues. 

There are some new interesting facts/observations that may be of wider interest, just skip the parts that too involved.

Regarding today’s picture, most readers of this blog are female and by the way, while the US is the most common location by far,  a surprisingly high number of page views come from France, Hong Kong, South Africa and Poland.

GABA

We have seen that GABA is one of the brain's most important neurotransmitters and we know that various forms of GABA dysfunction are associated with autism, epilepsy and indeed schizophrenia.

One recurring aspect in the research is the so-called excitatory-inhibitory balance of GABA.

The way the brain is understood to function assumes that GABA should be inhibitory and NMDA should be excitatory.

What makes GABA inhibitory is the level of the electrolyte chloride within the cells.  If the level is “wrong”, then GABA may be excitatory and the fine balance required with the NMDA receptor is lost.  The brain then cannot function as intended.

Source: Sage Therapeutics, a company that is developing new drugs that target GABA_A and NMDA receptors

To understand what is going wrong in autism and how to treat it we need to take a detailed look at the GABA_A receptor and all the anion transport mechanism associated with it.  Most research looks at either the receptor OR the transporters and exchangers.

Anion Transport Mechanisms of the GABA_A receptor

You will either need to be a doctor, scientist or very committed to keep reading here.

We know that level of chloride within the cells is critical to whether GABA behaves as excitatory or inhibitory.  This has all been established in the laboratory.

The usual target in autism is the NKCC1 transporter that lets chloride INTO cells, but as you can see in the two figures below, there are other ways to affect the concentration of chloride.  

·        The KCC2 transporter lets chloride out of the cells

·        The sodium dependent anion exchanger (NDAE) lets chloride out of the cells

·        The sodium independent anion exchanger 3 (AE3), lets chloride in.  It extrudes intracellular HCO₃^- in exchange for extracellular Cl^-.

All this does actually matter since we will be able to link it back to a known genetic dysfunction and it would suggest alternative therapeutic avenues.  We can also see how epilepsy fits into the picture.

Source: Two types of chloride transporters are required for GABA_A receptor-mediated inhibition in C. elegans

 Source:- InhibitoryRegulation of Excitatory Neurotransmission

NKCC1 in Autism

Without doubt, the transporter that controls the flow of chloride into the brain is the expert field of Ben Ari.

His recent summary paper is below:-

The GABA excitatory /inhibitory developmental sequence: a personal journey

He showed that by reducing the level of chloride in the autistic brain using the common diuretic Bumetanide, a marked improvement in many peoples’ autism could be achieved

This post is really about expanding more on what he does not tell us.

KCC2 in Autism

In typical people, very early in life the KCC2 transporter develops and as a result level of chloride falls inside the cells, since the purpose of the transporter is to extrude chloride.

It appears that in autism this mechanism has been disrupted.  The existing science can show us what has gone wrong.

The following study shows that KCC2 is itself regulated by neuroligin-2 (NL2), a cell adhesion molecule specifically localized at GABAergic synapses.

It gets more interesting because the scientists looking for genetic causes of autism have already identified the gene that encodes NL2, which they call NLGN2 (neuroligin 2) as being associated with autism and schizophrenia (adult onset autism).

GeneCards – the human gene compendium

  

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

Abstract

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.

KCC2 in Peripheral nerve injury (PNI)

Autism is not the only diagnosis associated with reduced function of the KCC2 transporter; Peripheral nerve injury (PNI) is another.

In this condition researchers sought to counter the failure of KCC2 to remove chloride from within the cell by increasing the flow chloride through the Cl^-/HCO₃^- anion exchanger known as AE3.

Inhibition of carbonic anhydrase augments GABAA receptor-mediated analgesia via a spinal mechanism of action.

Abstract

Peripheral nerve injury (PNI) negatively influences spinal gamma-aminobutyric acid (GABA)ergic networks via a reduction in the neuron-specific potassium-chloride (K(+)-Cl(-)) cotransporter (KCC2). This process has been linked to the emergence of neuropathic allodynia. In vivo pharmacologic and modeling studies show that a loss of KCC2 function results in a decrease in the efficacy of GABAA-mediated spinal inhibition. One potential strategy to mitigate this effect entails inhibition of carbonic anhydrase activity to reduce HCO3(-)-dependent depolarization via GABAA receptors when KCC2 function is compromised. We have tested this hypothesis here. Our results show that, similarly to when KCC2 is pharmacologically blocked, PNI causes a loss of analgesic effect for neurosteroid GABAA allosteric modulators at maximally effective doses in naïve mice in the tail-flick test. Remarkably, inhibition of carbonic anhydrase activity with intrathecal acetazolamide rapidly restores an analgesic effect for these compounds, suggesting an important role of carbonic anhydrase activity in regulating GABAA-mediated analgesia after PNI. Moreover, spinal acetazolamide administration leads to a profound reduction in the mouse formalin pain test, indicating that spinal carbonic anhydrase inhibition produces analgesia when primary afferent activity is driven by chemical mediators. Finally, we demonstrate that systemic administration of acetazolamide to rats with PNI produces an antiallodynic effect by itself and an enhancement of the peak analgesic effect with a change in the shape of the dose-response curve of the α1-sparing benzodiazepine L-838,417. Thus, carbonic anhydrase inhibition mitigates the negative effects of loss of KCC2 function after nerve injury in multiple species and through multiple administration routes resulting in an enhancement of analgesic effects for several GABAA allosteric modulators. We suggest that carbonic anhydrase inhibitors, many of which are clinically available, might be advantageously employed for the treatment of pathologic pain states.

PERSPECTIVE:

Using behavioral pharmacology techniques, we show that spinal GABAA-mediated analgesia can be augmented, especially following nerve injury, via inhibition of carbonic anhydrases. Carbonic anhydrase inhibition alone also produces analgesia, suggesting these enzymes might be targeted for the treatment of pain

Acetazolamide and midazolam act synergistically to inhibit neuropathic pain

Treatment of neuropathic pain is a major clinical challenge that has been met with minimal success. After peripheral nerve injury, a decrease in the expression of the K–Cl cotransporter KCC2, a major neuronal Cl⁻ extruder, leads to pathologic alterations in GABA_A and glycine receptor function in the spinal cord. The down-regulation of KCC2 is expected to cause a reduction in Cl⁻ extrusion capacity in dorsal horn neurons, which, together with the depolarizing efflux of HCO−3 anions via GABA_A channels, would result in a decrease in the efficacy of GABA_A-mediated inhibition. Carbonic anhydrases (CA) facilitate intracellular HCO−3 generation and hence, we hypothesized that inhibition of CAs would enhance the efficacy of GABAergic inhibition in the context of neuropathic pain. Despite the decrease in KCC2 expression, spinal administration of benzodiazepines has been shown to be anti-allodynic in neuropathic conditions. Thus, we also hypothesized that spinal inhibition of CAs might enhance the anti-allodynic effects of spinally administered benzodiazepines. Here, we show that inhibition of spinal CA activity with acetazolamide (ACT) reduces neuropathic allodynia. Moreover, we demonstrate that spinal co-administration of ACT and midazolam (MZL) act synergistically to reduce neuropathic allodynia after peripheral nerve injury. These findings indicate that the combined use of CA inhibitors and benzodiazepines may be effective in the clinical management of neuropathic pain in humans.

In conclusion, the major finding of the present work is that ACT and MZL act synergistically to inhibit neuropathic allodynia. In light of the available in vitro data reviewed above, a parsimonious way to explain this synergism is that CA inhibition blocks an HCO−3 -dependent positive shift in the E_r of GABA and/or glycine-mediated currents and the consequent tonic excitatory drive mediated by extrasynaptic GABA_A receptors, while preserving shunting inhibition that is augmented by benzodiazepine actions at postsynaptic GABA_A receptors. Obviously, further work is needed at the in vitro level in order to directly examine the cellular and synaptic basis of the ACT-MZL synergism and clinical studies are required to determine the safety of intrathecally applied CA inhibitors in humans. Since MZL and ACT, as well as several other inhibitors of CA [37], are clinically approved, we propose that their use in combination opens up a novel approach for the treatment of chronic neuropathic pain

Midazolam and Acetazolamide

The therapeutic as well as adverse effects of midazolam are due to its effects on the GABA_A receptors; midazolam does not activate GABA_A receptors directly but, as with other benzodiazepines, it enhances the effect of the neurotransmitter GABA on the GABA_A receptors (↑ frequency of Cl− channel opening) resulting in neural inhibition. Almost all of the properties can be explained by the actions of benzodiazepines on GABA_A receptors. This results in the following pharmacological properties being produced: sedation, hypnotic, anxiolytic, anterograde amnesia, muscle relaxation and anti-convulsant.

Acetazolamide, usually sold under the trade name Diamox in some countries.  Acetazolamide is a diuretic, and it is available as a (cheap) generic drug.

It is a carbonic anhydrase inhibitor that is used for the medical treatment of glaucoma, epileptic seizure, idiopathic intracranial hypertension, altitude sickness, cystinuria, periodic paralysis, central sleep apnea, and dural ectasia.

In epilepsy, the main use of acetazolamide is in menstrual-related epilepsy and as an adjunct in refractory epilepsy.

Acetazolamide is not an immediate cure for acute mountain sickness; rather, it speeds up part of the acclimatization process which in turn helps to relieve symptoms.  I am pretty sure, many years ago, it was Diamox that I took with me when crossing the Himalayas from Nepal into Tibet.  We did not have any problems with mountain sickness.

If periodic paralysis above rings some bells it should.  Two forms already mentioned in this blog are Hypokalemic periodic paralysis and Andersen Tawil syndrome.  We even referred to a paper suggesting the use of Bumetanide.

Bumetanide prevents transient decreases in muscle force in murine hypokalemic periodic paralysis.

Acetazolamide is a carbonic anhydrase inhibitor, hence causing the accumulation of carbonic acid Carbonic anhydrase is an enzyme found in red blood cells that catalyses the following reaction:

hence lowering blood pH, by means of the following reaction that carbonic acid undergoes

Anion exchanger 3 (AE3) in autism

Anion exchange protein 3 is a membrane transport protein that in humans is encoded by the SLC4A3 gene. It exchanges chloride for bicarbonate ions.  It increases chloride concentration within the cell.  AE3 is an anion exchanger that is primarily expressed in the brain and heart

Its activity is sensitive to pH. AE3 mutations have been linked to seizures

Characterization of anEpilepsy-associated variant of the AE3 Cl-/HCO3-exchanger

Bicarbonate (HCO₃^-) transport mechanisms are the principal regulators of pH in animal cells. Such transport also plays a vital role in acid-base movements in the stomach, pancreas, intestine, kidney, reproductive organs and the central nervous system.

Two types of chloride transporters are required for GABA_A receptor-mediated inhibition in C. elegans

Abstract

Chloride influx through GABA-gated Cl⁻ channels, the principal mechanism for inhibiting neural activity in the brain, requires a Cl⁻ gradient established in part by K⁺–Cl⁻ cotransporters (KCCs). We screened for Caenorhabditis elegans mutants defective for inhibitory neurotransmission and identified mutations in ABTS-1, a Na⁺-driven Cl⁻–HCO₃⁻ exchanger that extrudes chloride from cells, like KCC-2, but also alkalinizes them. While animals lacking ABTS-1 or the K⁺–Cl⁻ cotransporter KCC-2 display only mild behavioural defects, animals lacking both Cl⁻ extruders are paralyzed. This is apparently due to severe disruption of the cellular Cl⁻ gradient such that Cl⁻ flow through GABA-gated channels is reversed and excites rather than inhibits cells. Neuronal expression of both transporters is upregulated during synapse development, and ABTS-1 expression further increases in KCC-2 mutants, suggesting regulation of these transporters is coordinated to control the cellular Cl⁻ gradient. Our results show that Na⁺-driven Cl⁻–HCO₃⁻ exchangers function with KCCs in generating the cellular chloride gradient and suggest a mechanism for the close tie between pH and excitability in the brain.

NKCC1 and AE3 Appear to Accumulate Chloride in Embryonic Motoneurons

Abstract

During early development, γ-aminobutyric acid (GABA) depolarizes and excites neurons, contrary to its typical function in the mature nervous system. As a result, developing networks are hyperexcitable and experience a spontaneous network activity that is important for several aspects of development. GABA is depolarizing because chloride is accumulated beyond its passive distribution in these developing cells. Identifying all of the transporters that accumulate chloride in immature neurons has been elusive and it is unknown whether chloride levels are different at synaptic and extrasynaptic locations. We have therefore assessed intracellular chloride levels specifically at synaptic locations in embryonic motoneurons by measuring the GABAergic reversal potential (E_GABA) for GABA_A miniature postsynaptic currents. When whole cell patch solutions contained 17–52 mM chloride, we found that synaptic E_GABA was around −30 mV. Because of the low HCO₃⁻ permeability of the GABA_A receptor, this value of E_GABA corresponds to approximately 50 mM intracellular chloride. It is likely that synaptic chloride is maintained at levels higher than the patch solution by chloride accumulators. We show that the Na⁺-K⁺-2Cl⁻ cotransporter, NKCC1, is clearly involved in the accumulation of chloride in motoneurons because blocking this transporter hyperpolarized E_GABA and reduced nerve potentials evoked by local application of a GABA_A agonist. However, chloride accumulation following NKCC1 block was still clearly present. We find physiological evidence of chloride accumulation that is dependent on HCO₃⁻ and sensitive to an anion exchanger blocker. These results suggest that the anion exchanger, AE3, is also likely to contribute to chloride accumulation in embryonic motoneurons.

Sodium dependent anion exchanger (NDAE)

Not much has been written about these exchangers, outside of very technical literature.

Anion transport and GABA signaling

Sodium-coupled anion exchange is activated by intracellular acidification (Schwiening and Boron, 1994), suggesting that regulation of the chloride gradient by NDAEs may be closely linked to the regulation of cellular pH. As prolonged neuronal activity can cause neuronal acidification by efflux of bicarbonate through GABA_A receptors (Kaila and Voipio, 1987), sodium-coupled anion exchange may help to maintain a hyperpolarizing chloride reversal potential and thus promote the inhibitory action of GABA. Thus activation of sodium-coupled anion exchange by acidosis may also contribute to seizure termination by promoting a more negative chloride reversal potential and thus promoting the inhibitory effects of GABA.

The GABA_A receptor  (background is cut and paste from Wikipedia)

In order for GABA_A receptors to be sensitive to the action of benzodiazepines they need to contain an α and a γ subunit, between which the benzodiazepine binds. Once bound, the benzodiazepine locks the GABA_A receptor into a conformation where the neurotransmitter GABA has much higher affinity for the GABA_A receptor, increasing the frequency of opening of the associated chloride ion channel and hyperpolarizing the membrane. This potentiates the inhibitory effect of the available GABA leading to sedative and anxiolytic effects.

Structure and function

Schematic diagram of a GABA_A receptor protein ((α1)₂(β2)₂(γ2)) which illustrates the five combined subunits that form the protein, the chloride (Cl^-) ion channel pore, the two GABA active binding sites at the α1 and β2 interfaces, and the benzodiazepine (BDZ) allosteric binding site

The receptor is a pentameric transmembrane receptor that consists of five subunits arranged around a central pore. Each subunit comprises four transmembrane domains with both the N- and C-terminus located extracellularly. The receptor sits in the membrane of its neuron, usually localized at a synapse, postsynaptically. However, some isoforms may be found extrasynaptically. The ligand GABA is the endogenous compound that causes this receptor to open; once bound to GABA, the protein receptor changes conformation within the membrane, opening the pore in order to allow chloride anions (Cl⁻) to pass down an electrochemical gradient. Because the reversal potential for chloride in most neurons is close to or more negative than the resting membrane potential, activation of GABA_A receptors tends to stabilize or hyperpolarise the resting potential, and can make it more difficult for excitatory neurotransmitters to depolarize the neuron and generate an action potential. The net effect is typically inhibitory, reducing the activity of the neuron. The GABA_A channel opens quickly and thus contributes to the early part of the inhibitory post-synaptic potential (IPSP).

Subunits

GABA_A receptors are members of the large "Cys-loop" super-family of evolutionarily related and structurally similar ligand-gated ion channels that also includes nicotinic acetylcholine receptors, glycine receptors, and the 5HT₃ receptor. There are numerous subunit isoforms for the GABA_A receptor, which determine the receptor's agonist affinity, chance of opening, conductance, and other properties.
In humans, the units are as follows:

• six types of α subunits (GABRA1, GABRA2, GABRA3, GABRA4, GABRA5, GABRA6)
• three βs (GABRB1, GABRB2, GABRB3)
• three γs (GABRG1, GABRG2, GABRG3)
• as well as a δ (GABRD), an ε (GABRE), a π (GABRP), and a θ (GABRQ)

There are three ρ units (GABRR1, GABRR2, GABRR3), however these do not coassemble with the classical GABA_A units listed above,^[18] but rather homooligomerize to form GABA_A-ρ receptors (formerly classified as GABA_C receptors but now this nomenclature has been deprecated^[19] ).
Five subunits can combine in different ways to form GABA_A channels. The minimal requirement to produce a GABA-gated ion channel is the inclusion of both α and β subunits, but the most common type in the brain is a pentamer comprising two α's, two β's, and a γ (α₂β₂γ)
The receptor binds two GABA molecules, at the interface between an α and a β subunit



The important subunits for this post are:-

GABRA2,

Very little is written about this subunit.

GABRA3

While the effect of editing on protein function is unknown, the developmental increase in editing does correspond to changes in function of the GABA_A receptor. GABA binding leads to chloride channel activation, resulting in rapid increase in concentration of the ion. Initially, the receptor is an excitatory receptor, mediating depolarisation (efflux of Cl^- ions) in immature neurons before changing to an inhibitory receptor, mediating hyperpolarization(influx of Cl^- ions) later on. GABA_A converts to an inhibitory receptor from an excitatory receptor by the upregulation of KCC2 cotransporter. This decreases the concentration of Cl^- ion within cells. Therefore, the GABA_A subunits are involved in determining the nature of the receptor in response to GABA ligand. These changes suggest that editing of the subunit is important in the developing brain by regulating the Cl^- permeability of the channel during development. The unedited receptor is activated faster and deactivates slower than the edited receptor.

Editing modifies the GABAA receptor subunit α3

Editing of the I/M site is developmentally regulated

A switch in the GABA response from excitatory to inhibitory post-synaptic potentials occurs during early development where an efflux of chloride ions takes place in immature neurons, while there is an influx of chloride ions in mature neurons (Ben-Ari 2002). GABA switches from being excitatory to inhibitory by an up-regulation of the cotransporter KCC2 that decreases the chloride concentration in the cell. However, if GABA itself promotes the expression of KCC2 is still under debate (Ganguly et al. 2001; Ludwig et al. 2003; Titz et al. 2003). Further, the α subunits are critical elements in determining the nature of the GABA_A receptor response to GABA (Böhme et al. 2004). The α3 mRNA (Gabra-3) is present at high levels in several forebrain regions at birth with a major decline after post-natal day 12 (P12), when the expression of α1 is going up (Laurie et al. 1992). The change from α3 to α1 may cause the switch in GABA behavior from excitatory to inhibitory post-synaptic potentials during development.

GABA_A receptors respond to anxiolytic drugs such as benzodiazepines and are thus important drug targets. The benzodiazepine binding site is located at the interface of the α and γ2 subunits (Cromer et al. 2002). Antagonists that bind to this site enhance the effect of GABA by increasing the frequency of GABA-induced channel opening events. Post-transcriptional modifications of the α3 subunit, such as the I/M editing described here, could be important in determining the mechanistic features that are responsible for the diversity of GABA_A receptors and the variability in sensitivity to drugs

Ligands

A number of ligands have been found to bind to various sites on the GABA_A receptor complex and modulate it besides GABA itself.

Types

• Agonists: bind to the main receptor site (the site where GABA normally binds, also referred to as the "active" or "orthosteric" site) and activate it, resulting in increased Cl⁻ conductance.
• Antagonists: bind to the main receptor site but do not activate it. Though they have no effect on their own, antagonists compete with GABA for binding and thereby inhibit its action, resulting in decreased Cl⁻ conductance.
• Positive allosteric modulators: bind to allosteric sites on the receptor complex and affect it in a positive manner, causing increased efficiency of the main site and therefore an indirect increase in Cl⁻ conductance.
• Negative allosteric modulators: bind to an allosteric site on the receptor complex and affect it in a negative manner, causing decreased efficiency of the main site and therefore an indirect decrease in Cl⁻ conductance.
• Open channel blockers: prolong ligand-receptor occupancy, activation kinetics and Cl ion flux in a subunit configuration-dependent and sensitization-state dependent manner.
• Non-competitive channel blockers: bind to or near the central pore of the receptor complex and directly block Cl^- conductance through the ion channel.

The GABA_A receptor include a site where benzodiazepine can bind.  These are drugs that include like valium. Binding at this site increase the effect of GABA.  Since this receptor is meant to be inhibitory, giving valium should make it strong inhibitory, ie calming. 

It was noted that in autism the effect of valium was often the reversed, instead of calming it further increased anxiety.

The Valium is working just fine, it is magnifying the effect the effect of GABA, the problem is that the receptor is functioning as excitatory, the Valium is making it over-excitatory.  Now we come to the reason why.

We know that the excitatory-inhibitory balance is set by the chloride concentration within the cells.  We also know that exact mechanism that determines this level.

Enhancement of Inhibitory Neurotransmission by GABAA ReceptorsHaving α2,3-Subunits Ameliorates Behavioral Deficits in a Mouse Modelof Autism

 Highlights

•BTBR mice have reduced spontaneous GABAergic inhibitory transmission

•Nonsedating doses of benzodiazepines improved autism-related deficits in BTBR mice

•Impairment of GABAergic transmission reduced social interaction in wild-type mice

•Behavioral rescue by low-dose benzodiazepine is GABA_A receptor α_2,3-subunit specific

Summary

Autism spectrum disorder (ASD) may arise from increased ratio of excitatory to inhibitory neurotransmission in the brain. Many pharmacological treatments have been tested in ASD, but only limited success has been achieved. Here we report that BTBR T⁺ Itpr3^tf/J (BTBR) mice, a model of idiopathic autism, have reduced spontaneous GABAergic neurotransmission. Treatment with low nonsedating/nonanxiolytic doses of benzodiazepines, which increase inhibitory neurotransmission through positive allosteric modulation of postsynaptic GABA_A receptors, improved deficits in social interaction, repetitive behavior, and spatial learning. Moreover, negative allosteric modulation of GABA_A receptors impaired social behavior in C57BL/6J and 129SvJ wild-type mice, suggesting that reduced inhibitory neurotransmission may contribute to social and cognitive deficits. The dramatic behavioral improvement after low-dose benzodiazepine treatment was subunit specific—the α_2,3-subunit-selective positive allosteric modulator L-838,417 was effective, but the α₁-subunit-selective drug zolpidem exacerbated social deficits. Impaired GABAergic neurotransmission may contribute to ASD, and α_2,3-subunit-selective positive GABA_A receptor modulation may be an effective treatment.

  

These results indicate that different subtypes of GABAA receptors may have opposite roles in social behavior, with activation of GABAA receptors containing α_2,3 subunits favoring and of GABAA receptors with α₁  subunits reducing social interaction, respectively.

Because of their broad availability and safety, benzodiazepines and other positive allosteric modulators of GABAA receptors administered at low nonsedating, nonanxiolytic doses that do not induce tolerance deserve consideration as a near-term strategy to improve the core social interaction deficits and repetitive behaviors in ASD.

These results are most consistent with the hypotheses that reduced inhibitory neurotransmission is sufficient to induce autistic-like behaviors in mice and that enhanced inhibitory neurotransmission can reverse autistic-like behaviors.

Epilepsy

I have received various comments about epilepsy.  Epilepsy has many variants, just like autism.  Epilepsy is often comorbid with autism.  GABA dysfunction is known to be closely involved in some types of autism and some types of epilepsy.

It is known that Bumetanide has very different effects in different types of epilepsy.

The question that naturally arises is whether you can give Bumetanide to someone who has autism and epilepsy and if you cannot, is there an alternative with the same desired effect?

Well it appears that any method that changes chloride levels is likely to affect epilepsy.  It appears that all three methods (NKCC1, KCC2 and AE3) would likely have the same impact on epilepsy.

But would it be a good effect or a bad effect?

Would it interact with any existing anti-epilepsy drugs?

I suspect that Bumetanide might be an effective anti-epileptic in people with autism and that other GABA related drugs might no longer be needed.  Quite likely the effect of Bumetanide and the anti-epileptic targeting GABA might be too much.  So the blog reader that pointed out that the bumetanide clinical trial excluded children with epilepsy has highlighted an important point.

While epilepsy is not fully understood and there are various variants, it would seem plausible that the epilepsy common in core classic autism and early regressive autism is the same type and that it is linked to the same excitatory/inhibitory dysfunction.

You may be wonder if other diuretics have anti-epileptic properties. Here is a paper by a Neurologist from Denver on the subject:-

Diuretics as anti-epileptic drugs – Should we go with the Flow

Why is there an excitatory/inhibitory dysfunction in Autism?

People are writing entire books on the GABA excitatory/inhibitory balance.  I was curious as to why this dysfunction exists at all in autism. 

We learnt from Ben-Ari in earlier posts all about this switch from excitatory to inhibitory that is supposed to occur very early on in life, we now have two reasons why this may fail to happen in autism:-

1.     Editing modifies the GABA_A receptor subunit α₃.  The change from α₃ to α₁ may cause the switch in GABA behavior from excitatory to inhibitory post-synaptic potentials during development.  This change appears not to occur in some types of autism.  We see from the Clonazepam research that α₃ and  α₁ have opposite effects in autism.   In autism, activation of GABA_A receptors containing α_2,3 subunits favours social interaction  and activation of α₁  subunits reduces social interaction.

And/Or

2.     The GABA functional switch is mainly mediated by the up-regulation of KCC2, a potassium-chloride cotransporter that pumps Cl^- outside neurons.  NL2 also regulates KCC2 to modulate GABA functional switch. Therefore, NL2 may serve as a master regulator in balancing excitation and inhibition in the brain.  The gene that encodes NL2 is called NLGN2 (neuroligin 2).  Dysfunction in gene NLGN2 is known to occur in both autism and schizophrenia (adult onset autism).

Conclusion

We came full circle back to Bumetanide and Clonazepam as most likely the safest and most effective therapy to adjust the E/I (excitatory/inhibitory) balance in autism. KCCI agonists do not seem to exist.  The bicarbonate exchanger agonist Acetazolamide/Diamox is another common diuretic and I see no reason why it would not also be effective, but we would then affect bicarbonate levels.  Since these ions play a role in controlling pH levels, I think we might risk seeing some unintended effects.  We know that Bumetanide is safe in long term use.  We know that all diuretics that change chloride level within the cell and will affect epilepsy; so it is a case of “better the devil you know”. 

I finally understood exactly why tiny dose of Clonazepam are effective and how this fits in with the changes the Bumetanide has produced.  Thankfully, such tiny doses are free of the typical side effects expected from benzodiazepines.  One tablet lasts 10 days.

It also answers somebody else’s question about starting with Clonazepam before the Bumetanide.  If you did that you might well make things much worse, you would magnify the unwanted excess brain cell firing.  Once you added bumetanide things would then reverse and brain cell firing would be inhibited.

I rather like the parallel with neuropathic pain, the other condition we looked at with reduced KCC2 transporter function, the researchers there proposed the combination of a diuretic (Acetazolamide) to lower cellular chloride (via exchanger AE3) and a benzodiazepine (Midazolam) as a positive allosteric modulator.  This is extremely similar to Ben Ari’s bumetanide (diuretic affecting transporter NKCC1) plus Catterall’s tiny doses of clonazepam (benzodiazepine) as a positive allosteric modulator.

As for epilepsy and bumetanide, we know that bumetanide has different effects on different types of autism. It seems plausible that people with autism might tend to have the same type of epilepsy.  In any case Monty, aged 11 with ASD, does not have epilepsy/seizures and I suspect taking bumetanide has decreased the chance he ever will.  Of course I cannot prove this, it is just conjecture.