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Showing posts with label Kv7.1. Show all posts
Showing posts with label Kv7.1. Show all posts

Friday, 24 May 2024

Cilantro (Coriander leaves) for sound sensitivity? cGPMax for some Pitt Hopkins and Rett syndrome. Plus, microdeletion of 2P16.3 NRXN1 and mutations in GPC5

 


Today’s post combines a very simple therapy for sound sensitivity that landed in my inbox from New Zealand with two more genes that I was recently asked about.

Before I get started I would like to thank our reader Daniel who is trying to spread that word that the IGF-1 targeting therapy cGPMax works in some Rett syndrome (half a capsule daily). I did go into the science of IGF-1 related therapies at the recent conference in Abu Dhabi. In that presentation I pointed out that the cGPMax therapy might well be helpful in Pitt Hopkins syndrome. I saw today that Soko, an 8 year old girl with Pitt Hopkins, had already made a trial and her parents are impressed:-

“Equally significant has been the positive shift in Soko's emotional well-being. Her struggles with irritability and mood fluctuations feel like are not as frequent and we feel like there is more often a sense of calm and emotional regulation. This has had a profound ripple effect on our little family and our stress levels.

Perhaps most striking has been the accelerated rate at which Soko acquires new skills. CGP Max has seemingly unlocked hidden potentials within her. This rapid skill acquisition has been very exciting for us. In the last year she has gone from being unable to walk to walking unassisted and even tackling steps no handed!”

I did some checking and some other parents have tried cGPMax for Pitt Hopkins. For Rett syndrome Daniel found that a lower dose was more beneficial than a higher dose. It is always best to start with low doses and gradually increase them.

This does link to today’s post because a  microdeletion of NRXN1 can cause Pitt Hopkins Like Syndrome 2 (PHLS2). In theory all these syndromes are untreatable, but try telling that to Soko’s parents.

 

Back to sound sensitivity

Today’s sound sensitivity is the type that is moderated by Ponstan (mefenamic acid) and indeed Diclofenac. It might well include those whose sound sensitivity responds to a simple potassium supplement.

If you want to look into the details, you can see from previous posts how potassium and potassium ion channels play a fundamental role in both hearing and its sensory processing. They also play a key role in excitability of neurons and so can play a key role in some epilepsy and some intellectual disability.

It turns out that Cilantro/Coriander leaves contains a chemical that activates the ion channels  KCNQ2 (Kv7.2) and KCNQ3 (Kv7.3). This effect is shared by Ponstan and Diclofenac.

In the case of Andy from New Zealand the effect of a 425mg Cilantro supplement lasts very much longer than taking a low dose of Ponstan or Diclofenac.

So, if your child responds well to Ponstan and can then happily take off his/her ear defenders, but you do not want to medicate every day, then a trial of Cilantro could be interesting.

I was curious as to why the effect would last so much longer than Ponstan/Diclofenac.  All of these drugs lower potassium levels within neurons.  Is the beneficial effect coming from lowering potassium levels and so reducing neuronal excitability?  Or, is the effect coming directly from a specific ion channel?

Nobody can tell you the half-life of the active component of cilantro,  (E)-2-dodecenal, in humans.  Andy thinks it must have a long half-life.

 

Cilantro (Coriander leaves)

If you live in North America you will know what cilantro is, for everyone else it means coriander leaves. Coriander seeds are the dried fruit of the coriander plant and, confusingly, in American English coriander means coriander seeds.

The medicinal properties of the leaves and seeds are not the same.

Cilantro leaves contain a compound called (E)-2-dodecenal, which has been shown to activate a specific family of potassium ion channel called KCNQ, otherwise known as Kv7 . These channels are found in neurons, and they play an important role in regulating the electrical activity of the brain.

When (E)-2-dodecenal binds to KCNQ/Kv7 channels, it causes them to open, which allows potassium ions to flow out of the neuron. This outflow of potassium ions helps to stabilize the neuron's membrane potential and makes it less likely to fire an action potential.

The level of potassium inside neurons is much higher than the level outside. Having it too high, or indeed too low, would affect the excitability of the neuron.

I am wondering if the problem with potassium is mirroring the problem we have with chloride; perhaps both are elevated inside neurons. That would be nice and simple.

The discovery that cilantro can activate KCNQ channels helps to explain its potential anticonvulsant properties.  KCNQ channel dysfunction has been linked to certain types of epilepsy, and drugs that activate these channels are being investigated as potential treatments for these conditions.

Research suggests cilantro's active compound, (E)-2-dodecenal, targets multiple KCNQ channels, particularly:

  • KCNQ2/KCNQ3: This is the most common type of KCNQ channel found in neurons.
  • KCNQ1 in complex with KCNE1: This form is mainly present in the heart. KCNE1 acts as a regulatory subunit that influences KCNQ1 channel function.

 

Cilantro leaf harbors a potent potassium channel-activating anticonvulsant

Herbs have a long history of use as folk medicine anticonvulsants, yet the underlying mechanisms often remain unknown. Neuronal voltage-gated potassium channel subfamily Q (KCNQ) dysfunction can cause severe epileptic encephalopathies that are resistant to modern anticonvulsants. Here we report that cilantro (Coriandrum sativum), a widely used culinary herb that also exhibits antiepileptic and other therapeutic activities, is a highly potent KCNQ channel activator. Screening of cilantro leaf metabolites revealed that one, the long-chain fatty aldehyde (E)-2-dodecenal, activates multiple KCNQs, including the predominant neuronal isoform, KCNQ2/KCNQ3 [half maximal effective concentration (EC50), 60 ± 20 nM], and the predominant cardiac isoform, KCNQ1 in complexes with the type I transmembrane ancillary subunit (KCNE1) (EC50, 260 ± 100 nM). (E)-2-dodecenal also recapitulated the anticonvulsant action of cilantro, delaying pentylene tetrazole-induced seizures. In silico docking and mutagenesis studies identified the (E)-2-dodecenal binding site, juxtaposed between residues on the KCNQ S5 transmembrane segment and S4-5 linker. The results provide a molecular basis for the therapeutic actions of cilantro and indicate that this ubiquitous culinary herb is surprisingly influential upon clinically important KCNQ channels

Activation of KCNQ5 by cilantro could also contribute to its gut stimulatory properties, as KCNQ5 is also expressed in gastrointestinal smooth muscle, and its activation might therefore relax muscle, potentially being therapeutic in gastric motility disorders such as diabetic gastroparesis.

The KCNQ activation profile of (E)-2-dodecenal bears both similarities and differences to that of other KCNQ openers. We recently found that mallotoxin, from the shrub Mallotus oppositifolius that is used in African folk medicine, also activates KCNQ1-5 homomers, prefers KCNQ2 over KCNQ3, and in docking simulations binds in a pose reminiscent to that predicted for (E)-2-dodecenal, between (KCNQ2 numbering) R213 and W236 In addition to the widespread use of cilantro in cooking and as an herbal medicine, (E)-2-dodecenal itself is in broad use as a food flavoring and to provide citrus notes to cosmetics, perfumes, soaps, detergents, shampoos, and candles (59).

Our mouse seizure studies suggest it readily accesses the brain, and it is likely that its consumption as a food or herbal medicine (in cilantro) or as an added food flavoring would result in KCNQ-active levels in the human body; we found the 1% cilantro extract an efficacious KCNQ activator, and (E)-2-dodecenal itself showed greater than half-maximal opening effects on KCNQ2/3 at 100 nM (.10 mV shift at this concentration) (EC50, 60 6 20 nM). We anticipate that its activity on KCNQ channels contributes significantly to the broad therapeutic spectrum attributed to cilantro, which has persisted as a folk medicine for thousands of years throughout and perhaps predating human recorded history.

 

From the University of California: 


How cilantro works as a secret weapon against seizures

In a new study, researchers uncovered the molecular action that enables cilantro to effectively delay certain seizures common in epilepsy and other diseases.

The study, published in FASEB Journal, explains the molecular action of cilantro (Coriandrum sativum) as a highly potent KCNQ channel activator. This new understanding may lead to improvements in therapeutics and the development of more efficacious drugs.

“We discovered that cilantro, which has been used as a traditional anticonvulsant medicine, activates a class of potassium channels in the brain to reduce seizure activity,” said Geoff Abbott, Ph.D., professor of physiology and biophysics at the UC Irvine School of Medicine and principal investigator on the study.

“Specifically, we found one component of cilantro, called dodecenal, binds to a specific part of the potassium channels to open them, reducing cellular excitability.”

 

KCNQ channels and autism

There is a growing body of research suggesting a connection between KCNQ channels and autism.

·        KCNQ channel mutations: Genetic studies have identified mutations in several KCNQ channel genes (including KCNQ2, KCNQ3) in individuals with ASD. These mutations might disrupt the normal function of KCNQ channels, leading to abnormal brain activity.

  • Neuronal excitability: KCNQ channels help regulate the electrical activity of neurons by controlling the flow of potassium ions. Mutations or dysfunction in KCNQ channels could lead to increased neuronal excitability, which has been implicated in ASD. 
  • Shared features: Epilepsy is a common comorbidity with autism. Interestingly, KCNQ channel dysfunction is also linked to certain types of epilepsy. This suggests some shared mechanisms between these conditions.

 

KCNQ Dysfunction and Intellectual Disability

Mutations in certain KCNQ genes can lead to malfunctions in the corresponding potassium channels. These malfunctions can disrupt normal neuronal activity and contribute to intellectual disability.

  • KCNQ2/3 Mutations: Research suggests increased activity in KCNQ2 and KCNQ3 channels, due to mutations in their genes, might be associated with a subset of patients with intellectual disability alongside autism spectrum disorder. 
  • KCNQ5 Mutations: Studies have identified mutations in the KCNQ5 gene, leading to both loss-of-function and gain-of-function effects on the channel. These changes in KCNQ5 channel activity can contribute to intellectual disability, sometimes accompanied by epilepsy.

 

The other naming system

KCNQ channels belong to a larger potassium channel family called Kv7. So, you might see them referred to as Kv7.1 (KCNQ1), Kv7.2 (KCNQ2), and so on, based on their specific gene and protein sequence.

 

Mefenamic acid and Kir channels (inwards rectifying potassium ion channels)

Ponstan (mefenamic acid) affects Kir channels and KCNQ channels.

Different Kir channel subtypes contribute to various brain functions, including:

  • Neuronal excitability: Kir channels help regulate the resting membrane potential of neurons, influencing their firing activity.
  • Potassium homeostasis: They play a role in maintaining the proper balance of potassium ions within and outside neurons, crucial for normal electrical signaling.
  • Synaptic inhibition: Some Kir channels contribute to inhibitory neurotransmission, which helps balance excitatory signals in the brain.

Kir Channels are primarily inward rectifiers, meaning they allow potassium ions to flow more easily into the cell than out. They play a role in setting the resting membrane potential of cells, influencing their excitability.

KCNQ Channels can be voltage-gated or regulated by other factors. They contribute to various functions like regulating neuronal firing in the brain,

 

Other effects of Cilantro

It is certainly could be just a coincidence that Cilantro and Ponstan affect KCNQ channels. Cilantro has many other effects.

Coriandrum sativum and Its Utility in Psychiatric Disorders

Recent research has shown that Coriandrum sativum offers a rich source of metabolites, mainly terpenes and flavonoids, as useful agents against central nervous system disorders, with remarkable in vitro and in vivo activities on models related to these pathologies. Furthermore, studies have revealed that some compounds exhibit a chemical interaction with γ-aminobutyric acid, 5-hydroxytryptamine, and N-methyl-D-aspartate receptors, which are key components in the pathophysiology associated with psychiatric and neurological diseases. 

 

Bioactivities of isolated compounds from Coriandrum sativum by interaction with some neurotransmission systems involved in psychiatric and neurological disorders.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10385770/table/molecules-28-05314-t002/?report=objectonly

 

 

Understanding 2p16.3 (NRXN1) deletions



One parent contacted me to ask about the genetic test results they had received for their child.

To understand what happens when parts of the NRXN1 gene are missing you need to read up on neurexins and neuroligins.

 

Neurexins and Neuroligins

Neurexins ensure the formation of proper synaptic connections, fine-tune their strength, and contribute to the brain's adaptability. Understanding their role is crucial for understanding brain development, function, and various neurological disorders.

Neurexins and neuroligins are cell adhesion molecules that work together to ensure proper synapse formation, function, and ultimately, a healthy and functioning brain.

Neuroligins are located on the postsynaptic membrane (receiving neuron) of a synapse.

Neurexins are located on the presynaptic membrane (sending neuron) of a synapse.

Mutations in either neurexin or neuroligin genes have been linked to various neurodevelopmental disorders, including autism.

A comprehensive presentation for families is below:

 

Understanding 2p16.3 (NRXN1) deletions

https://www.rarechromo.org/media/information/Chromosome%20%202/2p16.3%20(NRXN1)%20deletions%20FTNW.pdf

 

A microdeletion in the NRXN1 gene on chromosome 2p16.3 can cause a condition similar to Pitt-Hopkins syndrome, but referred to as Pitt-Hopkins like syndrome 2 (PHLS2).

 

NRXN1 Gene:

  • NRXN1 codes for a protein called neurexin 1 alpha, which plays a critical role in the development and function of synapses, the junctions between neurons in the brain.
  • Neurexin 1 alpha helps neurons connect with each other and transmit signals.

Microdeletion:

  • A microdeletion is a small deletion of genetic material from a chromosome.
  • In PHLS2, a microdeletion occurs in the NRXN1 gene, removing some of the genetic instructions needed to produce functional neurexin 1 alpha protein.

Pitt-Hopkins Like Syndrome 2 (PHLS2):

  • PHLS2 is a genetic disorder characterized by intellectual disability, developmental delays, and various neurodevelopmental features.
  • Symptoms can vary depending on the size and specific location of the NRXN1 microdeletion.
  • Common features include:
    • Intellectual disability (ranging from mild to severe)
    • Speech and language impairments
    • Developmental delays in motor skills
    • Stereotypies (repetitive movements)
    • Seizures
    • Behavioral problems (e.g., hyperactivity, anxiety)
    • Distinctive facial features (not always present)

 

What has this got to do with Pitt Hopkins syndrome (loss of TCF4)?

“TCF4 may be transcribed into at least 18 different isoforms with varying N-termini, which impact subcellular localization and function. Functional analyses and mapping of missense variants reveal that different functional domains exist within the TCF4 gene and can alter transcriptional activation of downstream genes, including NRXN1 and CNTNAP2, which cause Pitt-Hopkins-like syndromes 1 and 2.”

 

NRXN1 interactions with other genes/proteins

Given the function of neurexins and neuroligins, you would expect that the common interactions of NRXN1 are with neuroligins. We see below the NLGNs (neuroligin genes/proteins)

Our more avid readers may recall that neuroligins are one mechanism for regulating the GABA switch. This is the developmental switch that should occur in all humans about two weeks after birth.  If it does not occur, the brain cannot develop and function normally. Autism and intellectual disability are the visible symptoms.

 

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

https://molecularbrain.biomedcentral.com/articles/10.1186/1756-6606-6-23#:~:text=Novel%20function%20of%20neuroligin%2D2,expression%20level%20was%20significantly%20decreased.

 

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. 

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.

 

It would seem plausible that in the case of microdeletions of the NRXN1 gene there will be a direct impact on the expression of NLGN2 gene that encodes neuroligin 2.

So plausible therapies to trial for microdeletions of the NRXN1 gene would include bumetanide, as well as cGPMax, due to the link with Pitt Hopkins.

 

GPC5 gene 

Finally, we move on to our last gene which is GPC5.

The protein Glpycan 5/GPC5 plays a role in the control of cell division and growth regulation.

Not surprising, GPC5 acts a tumor suppressor, making it a cancer gene. Because of this it is also an autism gene. It also plays a role in Alzheimer’s disease.

I was not sure I would be able to say anything about how you might treat autism caused by a mutation in GPC5.

 

Glycan susceptibility factors in autism spectrum disorders

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5556687/

 

I am assuming the mutation causes a loss of function, meaning there is a reduced level of the protein Glpycan 5.

Since one role of this gene is to suppress Wnt/beta-catenin signaling, you might want to replace this action.

This is actually covered in my blog in various places. One way is via a GSK-3β inhibitor.

GSK-3β inhibitor include drugs designed to block GSK-3β activity, examples include lithium (used for bipolar disorder), kenpaullone, and tideglusib. Certain natural compounds like curcumin and quercetin have been shown to possess GSK-3β inhibitory effects.

Atorvastatin, which my son has taken for 10 years, is indirectly a GSK-3β inhibitor

Some natural compounds like fisetin (found in fruits and vegetables) have been shown to promote beta-catenin phosphorylation, leading to its degradation.

In previous posts I pointed out that the cheap kids’ anthelmintic medication Mebendazole is indirectly another Wnt inhibitor. This is because it reduces TNIK. TNIK promotes Wnt signaling by stabilizing beta-catenin, a key player in the pathway. By reducing TNIK levels, mebendazole indirectly disrupts Wnt signaling. Mebendazole is therefore a novel cancer therapy and is being investigated to treat brain cancers, colon cancer, breast cancers etc.

Unlike what is says in the literature about GPC5, there actually are many options that can be safely trialed.

Note that you may not know for sure that any mutation is actually causal/pathogenic. Some people have several “likely pathogenic” mutations, some likely are not.

 

Conclusion

We have covered the potassium ion channel Kv7.1 previously. In Pitt Hopkins syndrome this ion channel is over expressed and so you would want to inhibit it. Do not take Cilantro, it would have the opposite effect to what you want.

It looks like cGPMAX is one thing you need to trial for Pitt Hopkins syndrome and Rett syndrome. For idiopathic autism it may, or may not help. Try a low dose first, observe the effect, then try a higher dose.

In Rett syndrome we know that people with have as much NKCC1 RNA — a molecule that carries the instructions to make the protein — as healthy individuals. However, their levels of KCC2 RNA are much lower, potentially disrupting the excitation/inhibition balance of nerve cell signaling. This will result in elevated chloride in neurons. This is correctable today using bumetanide.

People with NRXN1 microdeletions do seem to have treatment options, as do people with GPC5 mutations.

Note that out reader Janu, treating a mutation in GABRB2, reports success with a combination of the SSRI drug Lexapro and sodium valproate.

I am a fan of low dose Ponstan for sound sensitivity, it has numerous potentially beneficial mechanisms. It has been even shown to protect against Alzheimer’s disease.  There is no reason not to give cilantro a try as an alternative or complement to improve sound sensitivity.

Dried coriander is normally made from the seeds and is not what you need. In your supermarket you can buy fresh coriander leaves (Cilantro). The fresh herb is about 90% water, but when you dry the herb you will lose at lot of the active substance because it is volatile and will evaporate. My guess is that you will need 2-3 g of the fresh herb to equal Andy’s 425mg supplement.  You can eat the stalks as well as the leaves, it all has the same pungent taste.




Wednesday, 2 February 2022

Genetic Mutations vs Differentially Expressed Genes (DEGs) in Autism

 

Genes make proteins and you need the right amount in the right place
at the right time.

I should start this post by confessing to not having carried out genetic testing on Monty, now aged 18 with autism.  When I did mention this to one autism doctor at a conference, I was surprised by her reply:- “ You did not need to.  Now there’s no point doing it”.

I got lucky and treated at least some of Monty’s Differentially Expressed Genes (DEGs) by approaching the problem from a different direction.

People do often ask me about what diagnostic tests to run and in particular about genetic testing.  In general, people have far too high expectations regarding such tests and assume that there will be definitive answers, leading to effective therapeutic interventions.

I do include an interesting example today where parent power is leading a drive towards an effective therapeutic intervention in one single gene type of autism.  The approach has been to start with the single gene that has the mutation and look downstream at the resulting Differentially Expressed Genes (DEGs). The intervention targets one of the DEGs and not the mutated gene itself.

This is a really important lesson.

It can be possible to repurpose existing drugs to treat DEGs quite cheaply.  Many DEGs encode ion channels and there are very many existing drugs that affect ion channels.

Entirely different types of autism may share some of the same DEGs and so benefit from the same interventions.

 

Genetic Testing 

Genetic testing has not proved to be the holy grail in diagnosing and treating autism, but it remains a worthwhile tool at a population level (i.e. maybe not in your specific case).  What matters most of all are Differentially Expressed Genes (DEGs), which is something different.

A paper was recently published that looked into commercially available genetic testing.  Its conclusion was similar to my belief that you risk getting a “false negative” from these tests, in other words they falsely conclude that there is no genetic basis for the person’s symptoms of autism. 

 

Brief Report: Evaluating the Diagnostic Yield of Commercial Gene Panels in Autism

Autism is a prevalent neurodevelopmental condition, highly heterogenous in both genotype and phenotype. This communication adds to existing discussion of the heterogeneity of clinical sequencing tests, “gene panels”, marketed for application in autism. We evaluate the clinical utility of available gene panels based on existing genetic evidence. We determine that diagnostic yields of these gene panels range from 0.22% to 10.02% and gene selection for the panels is variable in relevance, here measured as percentage overlap with SFARI Gene and ranging from 15.15% to 100%. We conclude that gene panels marketed for use in autism are currently of limited clinical utility, and that sequencing with greater coverage may be more appropriate.

 

To save time and money, the commercial gene panels only test genes that the company defines as autism genes.  There is no approved list of autism genes. 

You have more than 20,000 genes and very many are implicated directly, or indirectly, in autism and its comorbities. To be thorough you need Whole Exome Sequencing (WES), where you check them all.  

There are tiny mutations called SNPs ("snips") which you inherit from your parents; there are more than 300 million known SNPs and most people will carry 4-5 million.  Some SNPs are important but clearly most are not.  Some SNPs are very common and some are very rare. 

Even WES only analyses 2% of your DNA, it does not consider the other 98% which is beyond the exome.  Whole Genome Sequencing (WGS) which looks at 100% of your DNA will be the ideal solution, but at some time in the future.  The interpretation of WES data is often very poor and adding all the extra data from WGS is going to overwhelm most people involved. 

Today we return to the previous theme of treating autism by treating the downstream effects caused by Differentially Expressed Genes (DEGS).

Genetics is very complicated and so people assume that is must be able to provide answers. For a minority of autism current genetics does indeed provide an answer, but for most people it does not.

Early on in this blog I noted so many overlaps between the genes and signaling pathways that drive cancer and autism, that is was clear that to understand autism you probably first have to understand cancer; and who has time to do that!

Some people’s cancer is predictable. Chris Evert, the American former world No. 1 tennis player, announced that she has ovarian cancer.  Her sister had exactly the same cancer.  Examining family history can often yield useful information and it is a lot less expensive that genetic testing.  Most people’s cancer is not so predictable; sure if you expose yourself to known environmental triggers you raise its chances, but much appears to be random.  Cancer, like much autism, is usually a multiple hit process. Multiple events need to occur and you may only need to block one of them to avoid cancer. We saw this with a genetic childhood leukemia that you can prevent with a gut bacteria. 


Learning about Autism from the 3 Steps to Childhood Leukaemia


What is not random in cancer are the Differentially Expressed Genes (DEGs).

We all carry highly beneficial tumor suppressing genes, like the autism/cancer gene PTEN.  You would not want to have a mutation in one of these genes.

What happens in many cancers is that the individual carries two good copies of the gene like PTEN, but the gene is turned off. For example, in many people with prostate cancer, the tumor suppressor gene PTEN is turned off in that specific part of the body.  There is no genetic mutation, but there is a harmful Differentially Expressed Gene (DEG). If you could promptly turn PTEN expression back on, you would suppress the cancer.

Not surprisingly, daily use of drugs that increase PTEN expression is associated with reduced incidence of PTEN associated cancer.  Atorvastatin is one such drug.

 

DEGs are what matter, not simply mutations

 

In many cases genetic mutations are of no clinical relevance, we all carry several on average.  In some cases they are of immediate critical relevance.  In most cases mutations are associated with a chance of something happening, there is no certainty and quite often further hits/events/triggers are required.

A good example is epilepsy. Epilepsy is usually caused by an ion channel dysfunction (sodium, potassium or calcium) that is caused by a defect in the associated gene. Most people are not born with epilepsy, the onset can be many years later.  Some parents of a child with autism/epilepsy carry the same ion channel mutation but remain unaffected. 

 

Follow the DEGs from a known mutation 

There is a vanishingly small amount of intelligent translation of autism science to therapy, or even attempts to do so.  I set out below an example of what can be done.

 

Pitt Hopkins (Haploinsufficiency of TCF4) 

The syndrome is caused by a reduction in Transcription factor 4, due to mutation in the TCF4 gene.  One recently proposed therapy is to repurpose the cheap calcium channel blocker Nicardipine. Follow the rationale below.

 

  means down regulated

↑ means up regulated


1.     Gene/Protein TCF4 (Transcription Factor 4) ↓↓↓↓

2.     Genes SCN10a  ↑↑    KCNQ1 ↑↑

3.     Encoding ion channels  Nav1.8   ↑↑     Kv7.1   ↑↑

4.     Repurpose approved drugs as inhibitors of Kv7.1 and Nav1.8 

5.     High throughput screen (HTS) of 1280 approved drugs.

6.     The HTS delivered 55 inhibitors of Kv7.1 and 93 inhibitors of Nav1.8

7.     Repurposing the Calcium Channel Inhibitor Nicardipine as a Nav1.8 inhibitor 


           

The supporting science: 

Psychiatric Risk Gene Transcription Factor 4 Regulates Intrinsic Excitability of Prefrontal Neurons via Repression of SCN10a and KCNQ1

  

Highlights

•TCF4 loss of function alters the intrinsic excitability of prefrontal neurons 

TCF4-dependent excitability deficits are rescued by SCN10a and KCNQ1 antagonists 

TCF4 represses the expression of SCN10a and KCNQ1 ion channels in central neurons 

•SCN10a is a potential therapeutic target for Pitt-Hopkins syndrome

  

Nav1.8 is a sodium ion channel subtype that in humans is encoded by the SCN10A gene

Kv7.1 (KvLQT1) is a potassium channel protein whose primary subunit in humans is encoded by the KCNQ1 gene.

  

Transcription Factor 4 (TCF4) is a clinically pleiotropic gene associated with schizophrenia and Pitt-Hopkins syndrome (PTHS).  

SNPs in a genomic locus containing TCF4 were among the first to reach genome-wide significance in clinical genome-wide association studies (GWAS) for schizophrenia  These neuropsychiatric disorders are each characterized by prominent cognitive deficits, which suggest not only genetic overlap between these disorders but a potentially overlapping pathophysiology.

We propose that these intrinsic excitability phenotypes may underlie some aspects of pathophysiology observed in PTHS and schizophrenia and identify potential ion channel therapeutic targets.

Given that TCF4 dominant-negative or haploinsufficiency results in PTHS, a syndrome with much more profound neurodevelopmental deficits than those observed in schizophrenia, the mechanism of schizophrenia risk associated with TCF4 is presumably due to less extreme alterations in TCF4 expression at some unknown time point in development

The pathological expression of these peripheral ion channels in the CNS may create a unique opportunity to target these channels with therapeutic agents without producing unwanted off-target effects on normal neuronal physiology, and we speculate that targeting these ion channels may ameliorate cognitive deficits observed in PTHS and potentially schizophrenia.

 

 

Disordered breathing in a Pitt-Hopkins syndrome model involves Phox2b-expressing parafacial neurons and aberrant Nav1.8 expression

Pitt-Hopkins syndrome (PTHS) is a rare autism spectrum-like disorder characterized by intellectual disability, developmental delays, and breathing problems involving episodes of hyperventilation followed by apnea. PTHS is caused by functional haploinsufficiency of the gene encoding transcription factor 4 (Tcf4). Despite the severity of this disease, mechanisms contributing to PTHS behavioral abnormalities are not well understood. Here, we show that a Tcf4 truncation (Tcf4tr/+) mouse model of PTHS exhibits breathing problems similar to PTHS patients. This behavioral deficit is associated with selective loss of putative expiratory parafacial neurons and compromised function of neurons in the retrotrapezoid nucleus that regulate breathing in response to tissue CO2/H+. We also show that central Nav1.8 channels can be targeted pharmacologically to improve respiratory function at the cellular and behavioral levels in Tcf4tr/+ mice, thus establishing Nav1.8 as a high priority target with therapeutic potential in PTHS. 

 

Repurposing Approved Drugs as Inhibitors of Kv7.1 and Nav1.8 To Treat Pitt Hopkins Syndrome

Purpose:

Pitt Hopkins Syndrome (PTHS) is a rare genetic disorder caused by mutations of a specific gene, transcription factor 4 (TCF4), located on chromosome 18. PTHS results in individuals that have moderate to severe intellectual disability, with most exhibiting psychomotor delay. PTHS also exhibits features of autistic spectrum disorders, which are characterized by the impaired ability to communicate and socialize. PTHS is comorbid with a higher prevalence of epileptic seizures which can be present from birth or which commonly develop in childhood. Attenuated or absent TCF4 expression results in increased translation of peripheral ion channels Kv7.1 and Nav1.8 which triggers an increase in after-hyperpolarization and altered firing properties.

Methods:

We now describe a high throughput screen (HTS) of 1280 approved drugs and machine learning models developed from this data. The ion channels were expressed in either CHO (KV7.1) or HEK293 (Nav1.8) cells and the HTS used either 86Rb+ efflux (KV7.1) or a FLIPR assay (Nav1.8).

Results:

The HTS delivered 55 inhibitors of Kv7.1 (4.2% hit rate) and 93 inhibitors of Nav1.8 (7.2% hit rate) at a screening concentration of 10 μM. These datasets also enabled us to generate and validate Bayesian machine learning models for these ion channels. We also describe a structure activity relationship for several dihydropyridine compounds as inhibitors of Nav1.8.

Conclusions:

This work could lead to the potential repurposing of nicardipine or other dihydropyridine calcium channel antagonists as potential treatments for PTHS acting via Nav1.8, as there are currently no approved treatments for this rare disorder.

  

Repurposing the Dihydropyridine Calcium Channel Inhibitor Nicardipine as a Nav1.8 inhibitor in vivo for Pitt Hopkins Syndrome

Individuals with the rare genetic disorder Pitt Hopkins Syndrome (PTHS) do not have sufficient expression of the transcription factor 4 (TCF4) which is located on chromosome 18. TCF4 is a basic helix-loop-helix E protein that is critical for the normal development of the nervous system and the brain in humans. PTHS patients lacking sufficient TCF4 frequently display gastrointestinal issues, intellectual disability and breathing problems. PTHS patients also commonly do not speak and display distinctive facial features and seizures. Recent research has proposed that decreased TCF4 expression can lead to the increased translation of the sodium channel Nav1.8. This in turn results in increased after-hyperpolarization as well as altered firing properties. We have recently identified an FDA approved dihydropyridine calcium antagonist nicardipine used to treat angina, which inhibited Nav1.8 through a drug repurposing screen.

 

All of the above was a parent driven process.  Well done, Audrey!

Questions remain.

Is Nicardipine actually beneficial to people with Pitt Hopkins Syndrome? Does it matter at what age therapy is started? What about the Kv7.1 inhibitor?

 

Conclusion 

Genetics is complicated, ion channel dysfunctions are complicated; but just a superficial understanding can take you a long way to understand autism, epilepsy and many other health issues.

There is a great deal in this blog about channelopathies/ion channel dysfunctions.

https://epiphanyasd.blogspot.com/search/label/Channelopathy

Almost everyone with autism has one or more channelopathies. Most channelopathies are potentially treatable.

Parents of children with rare single gene autisms should get organized and make sure there is basic research into their specific biological condition.  They need to ensure that there is an animal model created and it is then used to screen for existing drugs that may be therapeutic.  I think they also need to advocate for gene therapy to be developed.  This all takes years, but the sooner you start, the sooner you will make an impact.

Very likely, therapies developed for some single gene autisms will be applicable more broadly.  A good example may be the IGF-1 derivative Trofinetide, for girls with Rett Syndrome. IGF-1 (Insulin-like growth factor 1) is an important growth factor that is required for proper brain development. In the brain, IGF-1 is broken down into a protein fragment called glypromate (GPE). Trofinetide is an orally available version of GPE.

The MeCP2 protein controls the expression of several genes, such as Insulin-like Growth Factor 1 (IGF1), brain-derived neurotrophic factor (BDNF) and N-methyl-D-aspartate (NMDA).  All three are implicated in broader autism. 

https://rettsyndromenews.com/trofinetide-nnz-2566/

In girls with Rett Syndrome the genetic mutation is in the gene MeCP2, but one of the key DEGs (differentially expressed genes) is the FXYD1; it is over-expressed. IGF-1 supresses the activity of FXYD1 and hopefully so does Trofinetide.  Not so complicated, after all!

Medicine is often driven by the imperative to do no harm.

In otherwise severely impaired people, perhaps the imperative should be to try and do some good.

In medicine, time is of the essence; doctors in the ER can be heard to say "Stat!", from the Latin word for immediately, statim.  

How about some urgency in translating autism science into therapy? But then, what's the hurry? Why rock the boat?

On an individual basis, much is already possible, but you will have to do most of the work yourself - clearly a step too far for most people.