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Showing posts with label self-injury. Show all posts
Showing posts with label self-injury. Show all posts

Tuesday 23 April 2024

Maternal Agmatine or Choline to prevent autism? International brain pH project. Androgen levels in autism spectrum disorders. Apigenin works for BTBR mice. Auditory hypersensitivity, myelin and Nav1.2 channels. Dopamine transporter binding abnormalities and self-injury

 


Shutting the stable door after the horse has bolted


Today’s post is a summary of what I found interesting in the latest research.  Many items have been touched on previously.

The topic of maternal treatment to prevent future autism did come up in some recent comments on this blog. Two of the recent papers cover this very subject. One uses agmatine, from my autism PolyPill therapy, while the other used choline.

Auditory sound sensitivity is a complex subject and today we see the potential role impaired myelination and Nav1.2 ion channels can play.

A Chinese study reconfirms the elevated level of androgen hormones in autism.  

Apigenin which was covered in an earlier post is shown to help “autistic” mice in the popular BTBR model. This is a model where the corpus callosum is entirely absent.

Self-injury is a recuring nightmare for many with severe autism and today we look at a possible correlation with dopamine transporter binding abnormalities.

We start with easier subject matter and leave the hard parts for later in the post.


Preventing future autism

It may seem like too late to be talking about preventing autism, but it is a recurring subject. Today we have two new ideas that have appeared in the literature, and both are very simple. One is choline and other agmatine; both are used in the treatment of already existing autism.

 

Maternal choline to prevent autism

“maternal choline supplementation may be sufficient to blunt some of the behavioral and neurobiological impacts of inflammatory exposures in utero, indicating that it may be a cheap, safe, and effective intervention for neurodevelopmental disorders.” 

 

Maternal choline supplementation modulates cognition and induces anti-inflammatory signaling in the prefrontal cortex of adolescent rats exposed to maternal immune activation


Maternal infection has long been described as a risk factor for neurodevelopmental disorders, especially autism spectrum disorders (ASD) and schizophrenia. Although many pathogens do not cross the placenta and infect the developing fetus directly, the maternal immune response to them is sufficient to alter fetal neurodevelopment, a phenomenon termed maternal immune activation (MIA). Low maternal choline is also a risk factor for neurodevelopmental disorders, and most pregnant people do not receive enough of it. In addition to its role in neurodevelopment, choline is capable of inducing anti-inflammatory signaling through a nicotinic pathway. Therefore, it was hypothesized that maternal choline supplementation would blunt the neurodevelopmental impact of MIA in offspring through long- term instigation of cholinergic anti-inflammatory signaling.

To model MIA in rats, the viral mimetic polyinosinic:polycytidylic acid (poly(I:C)) was used to elicit a maternal antiviral innate immune response in dams both with and without choline supplementation. Offspring were reared to both early and late adolescent stages (postnatal days 28 and 50, respectively), where cognition and anxiety-related behaviors were examined. After behavioral testing, animals were euthanized, and their prefrontal cortices (PFCs) were collected for analysis. MIA offspring demonstrated sex-specific patterns of altered cognition and repetitive behaviors, which were modulated by maternal choline supplementation. Choline supplementation also bolstered anti-inflammatory signaling in the PFCs of MIA animals at both early and late adolescent stages. These findings suggest that maternal choline supplementation may be sufficient to blunt some of the behavioral and neurobiological impacts of inflammatory exposures in utero, indicating that it may be a cheap, safe, and effective intervention for neurodevelopmental disorders.

 

Prenatal Agmatine to prevent autism

Agmatine is a cheap bodybuilder supplement also used in psychiatry that has been extensively covered in this blog. Here we see how in a popular mouse model it can prevent autism.


The prenatal use of agmatine prevents social behavior deficits in VPA-exposed mice by activating the ERK/CREB/BDNF signaling pathway


Background: According to reports, prenatal exposure to valproic acid can induce autism spectrum disorder (ASD)-like symptoms in both humans and rodents. However, the exact cause and therapeutic method of ASD is not fully understood. Agmatine (AGM) is known for its neuroprotective effects, and this study aims to explore whether giving agmatine hydrochloride before birth can prevent autism-like behaviors in mouse offspring exposed prenatally to valproic acid.

Methods: In this study, we investigated the effects of AGM prenatally on valproate (VPA)-exposed mice. We established a mouse model of ASD by prenatally administering VPA. From birth to weaning, we evaluated mouse behavior using the marble burying test, open-field test, and three-chamber social interaction test on male offspring.

Results: The results showed prenatal use of AGM relieved anxiety and hyperactivity behaviors as well as ameliorated sociability of VPA-exposed mice in the marble burying test, open-field test, and three-chamber social interaction test, and this protective effect might be attributed to the activation of the ERK/CREB/BDNF signaling pathway.

Conclusion: Therefore, AGM can effectively reduce the likelihood of offspring developing autism to a certain extent when exposed to VPA during pregnancy, serving as a potential therapeutic drug.


This builds on an earlier paper that first identified the benefit.

 

Agmatine rescues autistic behaviors in the valproic acid-induced animal model of autism

  

Highlights

                  Single treatment of agmatine rescues social impairment in the VPA-induced animal model of autism.

                  Effect of agmatine in social improvement in the VPA model is induced from agmatine itself, not its metabolite.

                  Agmatine rescues repetitive and hyperactive behavior, and seizure susceptibility in the VPA model.

                  Overly activated ERK1/2 in the brain of the VPA model is relieved by agmatine.

 

Apigenin


50mg of Apigenin

1g of dried parsley
15-20g of dried chamomile flowers

 

I have previously written about Apigenin, which is an OTC supplement. There has been another paper recently published about it. There is a logical connection with the maternal choline therapy from above.

 

What does Apigenin have in common with Choline?  α7-nAChRs

Choline is interesting because it acts as both a precursor for acetylcholine synthesis and it is a neuromodulator itself.

Choline is activates α7-nAChRs, alpha-7 nicotinic acetylcholine receptors.

These receptors are extremely important in learning and sensory processing.  They also play a key role in inflammation and signaling via the vagus nerve.

Apigenin is a flavonoid found in many plants, fruits, and vegetables. It has been shown to have a number of health benefits, including anti-inflammatory and antioxidant effects. Apigenin has also been shown to interact with α7-nAChRs.

Studies have shown that apigenin can:

Enhance α7-nAChR function: Apigenin has been shown to increase the activity of α7-nAChRs. This may be due to its ability to bind to a specific site on the receptor.

Protect α7-nAChRs from damage: Apigenin may also help to protect α7-nAChRs from damage caused by oxidative stress.

 

Apigenin Alleviates Autistic-like Stereotyped Repetitive Behaviors and Mitigates Brain Oxidative Stress in Mice


Studying the involvement of nicotinic acetylcholine receptors (nAChRs), specifically α7-nAChRs, in neuropsychiatric brain disorders such as autism spectrum disorder (ASD) has gained a growing interest. The flavonoid apigenin (APG) has been confirmed in its pharmacological action as a positive allosteric modulator of α7-nAChRs. However, there is no research describing the pharmacological potential of APG in ASD. The aim of this study was to evaluate the effects of the subchronic systemic treatment of APG (10–30 mg/kg) on ASD-like repetitive and compulsive-like behaviors and oxidative stress status in the hippocampus and cerebellum in BTBR mice, utilizing the reference drug aripiprazole (ARP, 1 mg/kg, i.p.). BTBR mice pretreated with APG (20 mg/kg) or ARP (1 mg/g, i.p.) displayed significant improvements in the marble-burying test (MBT), cotton-shredding test (CST), and self-grooming test (SGT) (all p < 0.05). However, a lower dose of APG (10 mg/kg, i.p.) failed to modulate behaviors in the MBT or SGT, but significantly attenuated the increased shredding behaviors in the CST of tested mice. Moreover, APG (10–30 mg/kg, i.p.) and ARP (1 mg/kg) moderated the disturbed levels of oxidative stress by mitigating the levels of catalase (CAT) and superoxide dismutase (SOD) in the hippocampus and cerebellum of treated BTBR mice. In patch clamp studies in hippocampal slices, the potency of choline (a selective agonist of α7-nAChRs) in activating fast inward currents was significantly potentiated following incubation with APG. Moreover, APG markedly potentiated the choline-induced enhancement of spontaneous inhibitory postsynaptic currents. The observed results propose the potential therapeutic use of APG in the management of ASD. However, further preclinical investigations in additional models and different rodent species are still needed to confirm the potential relevance of the therapeutic use of APG in ASD.

  

Altered acidity (pH) levels inside the brain

I found it intriguing that a large study has examined the altered acidity (pH) levels inside the brain of those with neurological disorders.

For all the disorders other than autism there was a clear pattern of low pH, which means increased acidity.

For autism certain autism models exhibited decreased pH and increased lactate levels, but others showed the opposite pattern, reflecting subpopulations within autism.

Altered brain energy metabolism is an acknowledged feature of autism, so we should not be surprised to find altered levels of acidity.

The easy reading version:

 

Brain Acidity Linked With Multiple Neurological Disorders

 

The study itself:

Large-scale animal model study uncovers altered brain pH and lactate levels as a transdiagnostic endophenotype of neuropsychiatric disorders involving cognitive impairment

Increased levels of lactate, an end-product of glycolysis, have been proposed as a potential surrogate marker for metabolic changes during neuronal excitation. These changes in lactate levels can result in decreased brain pH, which has been implicated in patients with various neuropsychiatric disorders. We previously demonstrated that such alterations are commonly observed in five mouse models of schizophrenia, bipolar disorder, and autism, suggesting a shared endophenotype among these disorders rather than mere artifacts due to medications or agonal state. However, there is still limited research on this phenomenon in animal models, leaving its generality across other disease animal models uncertain. Moreover, the association between changes in brain lactate levels and specific behavioral abnormalities remains unclear. To address these gaps, the International Brain pH Project Consortium investigated brain pH and lactate levels in 109 strains/conditions of 2,294 animals with genetic and other experimental manipulations relevant to neuropsychiatric disorders. Systematic analysis revealed that decreased brain pH and increased lactate levels were common features observed in multiple models of depression, epilepsy, Alzheimer’s disease, and some additional schizophrenia models. While certain autism models also exhibited decreased pH and increased lactate levels, others showed the opposite pattern, potentially reflecting subpopulations within the autism spectrum. Furthermore, utilizing large-scale behavioral test battery, a multivariate cross-validated prediction analysis demonstrated that poor working memory performance was predominantly associated with increased brain lactate levels. Importantly, this association was confirmed in an independent cohort of animal models. Collectively, these findings suggest that altered brain pH and lactate levels, which could be attributed to dysregulated excitation/inhibition balance, may serve as transdiagnostic endophenotypes of debilitating neuropsychiatric disorders characterized by cognitive impairment, irrespective of their beneficial or detrimental nature.

In conclusion, the present study demonstrated that altered brain pH and lactate levels are commonly observed in animal models of SZ, BD, ID, ASD, AD, and other neuropsychiatric disorders. These findings provide further evidence supporting the hypothesis that altered brain pH and lactate levels are not mere artifacts, such as those resulting from medication confounding, but are rather involved in the underlying pathophysiology of some patients with neuropsychiatric disorders. Altered brain energy metabolism or neural hyper- or hypoactivity leading to abnormal lactate levels and pH may serve as a potential therapeutic targets for neuropsychiatric disorders

 

Why would the brain be acidic (reduced pH)?

To function optimally mitochondria need adequate oxygen and glucose. When performance is impaired, for example due to the lack of Complex 1, mitochondria switch from OXPHOS (oxidative phosphorylation) to fermentation to produce energy (ATP). Lactic acid is the byproduct and this will lower pH.

 

Does brain pH matter?

It does matter and is linked to cognitive impairments, headaches, seizures etc.

Many enzymes in the brain rely on a specific pH range to function properly. Deviations from the ideal pH can hinder their activity, impacting various neurochemical processes essential for brain function.

Some ion channels are pH sensitive.

 

Chemical buffers in the brain aim to regulate pH in the brain

·       Carbonic Acid/Bicarbonate Buffer System: Similar to the blood, the brain utilizes this system to regulate pH.

·   Organic Phosphates: These molecules, like creatine phosphate, can act as buffers in the brain by binding or releasing hydrogen ions.

These buffering systems work together to maintain a tightly controlled pH range in both the blood (around 7.35-7.45) and the brain (slightly more acidic than blood, around 7.0-7.3). Even slight deviations from this ideal range can have significant consequences for cellular function.

  

Androgen Levels in Autism

Androgens are male hormones like testosterone, DHEA and DHT, but females have them too, just at lower levels.

Drugs that reduce the level of these hormones are called antiandrogens.

Finasteride reduces DHT and is used to treat hair loss in men as Propecia. This drug was trialed in women, but failed to show a benefit over the placebo.

The main use of Finasteride is for the treatment of benign prostatic hyperplasia (BPH) in older men.

Women sometimes take antiandrogens like Spironolactone to control acne.

Numerous studies have show elevated levels of males hormones in both males and females with autism.

A recent paper was published on this very subject: 


Androgen levels in autism spectrum disorders: A systematic review and meta-analysis

Background:

Accumulating evidence suggests that the autism spectrum disorder (ASD) population exhibits altered hormone levels, including androgens. However, studies on the regulation of androgens, such as testosterone and dehydroepiandrosterone (DHEA), in relation to sex differences in individuals with ASD are limited and inconsistent. We conducted the systematic review with meta-analysis to quantitatively summarise the blood, urine, or saliva androgen data between individuals with ASD and controls.

Methods:

A systematic search was conducted for eligible studies published before 16 January 2023 in six international and two Chinese databases. We computed summary statistics with a random-effects model. Publication bias was assessed using funnel plots and heterogeneity using I 2 statistics. Subgroup analysis was performed by age, sex, sample source, and measurement method to explain the heterogeneity.

Results:

17 case-control studies (individuals with ASD, 825; controls, 669) were assessed. Androgen levels were significantly higher in individuals with ASD than that in controls (SMD: 0.27, 95% CI: 0.06-0.48, P=0.01). Subgroup analysis showed significantly elevated levels of urinary total testosterone, urinary DHEA, and free testosterone in individuals with ASD. DHEA level was also significantly elevated in males with ASD. Androgen levels, especially free testosterone, may be elevated in individuals with ASD and DHEA levels may be specifically elevated in males.

 

By coincidence I was just sent the paper below, showing the benefit of Finasteride in one model of autism. 

Therapeutic effect of finasteride through its antiandrogenic and antioxidant role in a propionic acid-induced autism model: Demonstrated by behavioral tests, histological findings and MR spectroscopy

 

I do recall I think it was Tyler, long ago, writing a comment about the potential to use Finasteride in autism.

Some very expensive antiandrogens have been used in autism and this became rather controversial.

We saw in earlier posts that RORα/RORalpha/RORA is a key mechanism where the balance between male and female hormones controls some key autism gene.

 


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

 androgen receptor = AR             estrogen receptor = ER


Cerebellum and neurodevelopmental disorders: RORα is a unifying force

Errors of cerebellar development are increasingly acknowledged as risk factors for neuro-developmental disorders (NDDs), such as attention deficit hyperactivity disorder (ADHD), autism spectrum disorder (ASD), and schizophrenia. Evidence has been assembled from cerebellar abnormalities in autistic patients, as well as a range of genetic mutations identified in human patients that affect the cerebellar circuit, particularly Purkinje cells, and are associated with deficits of motor function, learning and social behavior; traits that are commonly associated with autism and schizophrenia. However, NDDs, such as ASD and schizophrenia, also include systemic abnormalities, e.g., chronic inflammation, abnormal circadian rhythms etc., which cannot be explained by lesions that only affect the cerebellum. Here we bring together phenotypic, circuit and structural evidence supporting the contribution of cerebellar dysfunction in NDDs and propose that the transcription factor Retinoid-related Orphan Receptor alpha (RORα) provides the missing link underlying both cerebellar and systemic abnormalities observed in NDDs. We present the role of RORα in cerebellar development and how the abnormalities that occur due to RORα deficiency could explain NDD symptoms. We then focus on how RORα is linked to NDDs, particularly ASD and schizophrenia, and how its diverse extra-cerebral actions can explain the systemic components of these diseases. Finally, we discuss how RORα-deficiency is likely a driving force for NDDs through its induction of cerebellar developmental defects, which in turn affect downstream targets, and its regulation of extracerebral systems, such as inflammation, circadian rhythms, and sexual dimorphism.

  



Figure 2. RORα regulates multiple genes and plays extensive roles in cerebellar development. (A) Key stages of PC development which are regulated by RORα. These are at all stages from embryonic development to adult maintenance. (B) A schema showing the central role of RORα in multiple cellular processes, that are modified in NDDs. When RORα is reduced (central red circle), its regulation of gene transcription is altered. Here we include the known RORα target genes that are also involved in NDDs. The effects in red illustrate the induced abnormalities according to the direction of change: estrogen and PC development are reduced, circadian rhythms are perturbed, but inflammation and ROS are increased.

 

Sound sensitivity in autism and Nav1.2

At this point today’s post does get complicated.

Researchers have learnt that the sodium ion channel Nav1.2 (expressed by the SCN2A gene) can play a key role in hypersensitivity to sound in autism.

Lack of these ion channels in the cells that produce myelin produces “faulty auditory circuits”, with too much sound sensitivity.

An impairment in myelin structure can trigger cascading effects on neuronal excitability. Sound sensitivity is just one example.

There is a great deal of evidence that genes involved in myelination are miss-expressed in many models of autism. Imaging studies have shown variations in myelination.

 

Scn2a deletion disrupts oligodendroglia function: Implication for myelination, neural circuitry, and auditory hypersensitivity in ASD

Autism spectrum disorder (ASD) is characterized by a complex etiology, with genetic determinants significantly influencing its manifestation. Among these, the Scn2a gene emerges as a pivotal player, crucially involved in both glial and neuronal functionality. This study elucidates the underexplored roles of Scn2a in oligodendrocytes, and its subsequent impact on myelination and auditory neural processes. The results reveal a nuanced interplay between oligodendrocytes and axons, where Scn2a deletion causes alterations in the intricate process of myelination. This disruption, in turn, instigates changes in axonal properties and neuronal activities at the single cell level. Furthermore, oligodendrocyte-specific Scn2a deletion compromises the integrity of neural circuitry within auditory pathways, leading to auditory hypersensitivity—a common sensory abnormality observed in ASD. Through transcriptional profiling, we identified alterations in the expression of myelin-associated genes, highlighting the cellular consequences engendered by Scn2a deletion. In summary, the findings provide unprecedented insights into the pathway from Scn2a deletion in oligodendrocytes to sensory abnormalities in ASD, underscoring the integral role of Scn2a-mediated myelination in auditory responses. This research thereby provides novel insights into the intricate tapestry of genetic and cellular interactions inherent in ASD.

Therefore, our study underscores the region-specific relationship between myelin integrity and ion channel distribution in the developing brain. We emphasize that any disturbances in myelin structure can trigger cascading effects on neuronal excitability and synaptic function in the CNS, especially at nerve terminals in the auditory nervous system. 

How are Nav1.2  channels, encoded by Scn2a, involved in OL maturation and myelination? One possible explanation is that the activation of Nav1.2 may be pivotal for triggering Cav channel activation, leading to a Ca2+ flux within OLs, which is involved in OL proliferation, migration, and differentiation. Specifically, Ca2+ signaling facilitated by R-type Cav in myelin sheaths at paranodal regions, might influence the growth of myelin sheaths. To activate high-voltage activated calcium channels such as L- and R-Type efficiently, the activation of Nav1.2 channels should be required for depolarizing OL membrane to around -30 mV. Consequently, the synergic interplay between Nav1.2 and Cav channels could amplify calcium signaling in OLs, initiating the differentiation and maturation processes. 

Defects in myelination can create a spectrum of auditory dysfunctions, including hypersensitivity. Our results demonstrated how OL-Scn2a is involved in the relationship between myelin defects, neuronal excitability, and auditory pathology in ASD, potentially paving the way for targeted therapeutic interventions.

 

One subject that some people write to me repeatedly about is self-injurious behavior, so I took note of the paper below.  

Dopamine Transporter Binding Abnormalities Are Associated with Self-injurious Behavior in Autism Spectrum Disorder 

Utilizing single-photon emission computed tomography dopamine transporter scans (DaTscan) we examined whether imaging markers of the dopaminergic system are related to repetitive behaviors as assessed by the Repetitive Behavior Scale-Revised in ASD.

Background: 

Autism spectrum disorder (ASD) is characterized by impairments in social communication, and restricted repetitive behaviors. Self-injurious behaviors are often observed in individuals with ASD. Dopamine is critical in reward, memory, and motor control. Some propose the nigrostriatal motor pathway may be altered in ASD, and alterations in dopamine are reported in some rodent models based on specific ASD genes. Additionally, repetitive behaviors may to be related to reward systems. Therefore, we examined the dopaminergic system, using DaTscans, to explore its relationship with measures of repetitive behavior in a clinical ASD population.

Design/Methods: 

Twelve participants (aged 18–27) with ASD were recruited from the Thompson Center for Autism and Neurodevelopment and completed the Repetitive Behaviors Scale - Revised (RBS-R). Of the 12 participants, 10 underwent a 45-minute DaTscan. ANOVA was used to compare the dopamine imaging findings with the overall total RB scores on the RBS-R. while other domains of the RBS-R were also investigated in an exploratory manner.

Results: 

Five of the participants had regional deficits in dopamine transporter binding in the striatum on DaTscan. Individuals with deficits on the DaTscan had significantly higher Self-Injurious Endorsed Scores than those with normal scans.

Conclusions: 

Half of the DaTscans obtained were determined abnormal, and abnormal scans were associated with greater endorsing of self-injurious behavior. Larger samples are needed to confirm this, and determine the impact of laterality of abnormalities, but this preliminary work suggests a potential role the dopaminergic system in self-injurious RBs. Elucidation of this relationship may be important for future interventional outcomes, with potential impact on targeted treatment, as the only currently approved medications for ASD are atypical neuroleptics.

 

Dopamine transporter binding abnormalities refer to deviations from the normal levels of dopamine transporter (DAT) in the brain. DAT is a protein on the surface of cells that reabsorbs dopamine from the synapse, regulating its availability.

Imaging techniques like DAT scans (dopamine transporter scans) are used to assess DAT levels. These scans measure the binding of radiotracers to DAT, with lower binding indicating reduced DAT levels.

Dopamine transporter binding abnormalities have been linked to various neurological and psychiatric conditions, including:

                 Parkinson's disease: Degeneration of dopamine-producing neurons in the substantia nigra, a hallmark of Parkinson's disease, leads to a significant decrease in dopamine levels and DAT binding in the striatum.

                 Attention deficit hyperactivity disorder (ADHD): Some studies suggest that individuals with ADHD may have abnormal DAT function, though the nature of the abnormality (increased or decreased DAT) is debated.

                 Autism spectrum disorder (ASD): Research suggests that a subgroup of individuals with ASD may have DAT abnormalities, potentially linked to repetitive behaviors and social difficulties.

                 Addiction: Dopamine plays a central role in reward and motivation. Drugs like cocaine and methamphetamine can cause long-term changes in DAT function, potentially contributing to addiction.

DAT binding abnormalities may not always translate to functional impairments.

 

Treatment options for DAT binding abnormalities

Unfortunately, medications that directly target Dopamine Transporter (DAT) binding abnormalities do not exist.

In Parkinson's disease the goal is to increase dopamine levels in the brain. Medications like levodopa, a dopamine precursor, or dopamine agonists (drugs that mimic dopamine) are used.

  

Conclusion

It certainly is not easy to figure out how to treat autism and its troubling symptoms like self-injury. Our reader currently trying to make sure his second child does not have severe autism is wise to invest his time now.

Today we added agmatine and choline to our list of preventative strategies to consider.

As regards strategies to treat autism in children and adults, we see that the research very often is repeating what has already been published over the past two decades.

Ion channels do seem to be central to understanding and treating autism.




Thursday 6 October 2022

Different L-type Calcium Channel Blockers Repurposed for Different Types of Autism

 

 A Purkinje Neuron, home of P-type calcium channels

Today’s post was prompted by a reader who saw a very positive response from the L-type calcium channel blocker, Amlodipine.

So we return to the subject of calcium channels.

The good news about calcium channel defects is that many are easy to treat.

In most single gene autisms (Rett, Fragile-X, Pitt Hopkins etc) the underlying problem is that a faulty gene does not do its job of producing the expected protein.  This is a problem of too little.

In many ion channel dysfunctions the problem is not too little, it is too much expression. For example, in Timothy Syndrome the mutation in the gene produces too much of the protein, in this case the L-type calcium channel Cav1.2.

Ion channel dysfunctions can be the result of a faulty gene, or just that the on/off switch for that gene is faulty.  Fortunately, the problem is usually that it is stuck “on”.

In people who develop Type-1 diabetes we have seen how the disease process can be halted by blocking Cav1.2 in the pancreas.  This halts the decline in the beta cells that produce insulin.

Once all the beta cells are dead, the person cannot produce insulin and has type-1 diabetes. Treating the person after this point with a Cav1.2 blocker will provide no benefit; the damage has already been done

Something similar happens in Parkinson’s disease, but this time you need to block Cav1.3.  In the early stages of the disease Cav1.3 is over-expressed in a key part of the brain, which triggers a slow process of degeneration. Treating a person with all the visible symptoms of Parkinson’s with a Cav1.3 blocker will provide no benefit; the damage has already been done.

 

Calcium channel blockers are not very specific

The current drugs used to block calcium channels were mainly developed to treat heart conditions.

When treating neurological disorders like autism we are primarily focused on the brain, what goes on elsewhere can also be very relevant, but in an indirect way.

In the brain the important calcium channels are: -

L type

N type

P type

R type

T type

Plus, Inositol trisphosphate receptor (IP3R) and Ryanodine receptors. IP3R has been covered in previous posts.


Verapamil (a Phenylalkylamine class drug)

Verapamil blocks L type channels and T type channels, plus some potassium ion channels.

When it comes to specific L type channels there are 4, Cav1.1, Cav1.2, Cav1.3, and Cav1.4.

In the brain we have just Cav1.2 and Cav1.3. Verapamil mainly affects Cav1.2.

 

Amlodipine (a Dihydropyridine class drug)

Amlodipine blocks L type channels and N type channels.

Amlodipine mainly affects Cav1.3.

 

Nicardipine (a Dihydropyridine class drug)

Nicardipine blocks L type channels and N type channels.

As a Dihydropyridine, it should mainly affect Cav1.3.

In addition, it blocks the sodium ion channel Nav1.8.

The effect on Nav1.8 is why it has been proposed as a therapy for Pitt Hopkins. In this syndrome Nav1.8 is over expressed as a downstream consequence of a mutation in the TCF4 gene.

 

Effect on P channels

To some extent Verapamil, Amlodipine and Nicardipine all block P channels.

P channels are called P after the Purkinje neurons, where they are located. These Purkinje cells likely define some aspects of autism, because of their absence. Purkinje neurons are among the largest in the brain, with elaborate dendritic arbor.  I imagine this makes them vulnerable.




In the people with severe autism most of the Purkinje cells appear to have died.

Blocking P channels might have protected Purkinje cells from death.

 

The effect of too much L-type calcium channel signaling on behavior 

You can both turn on self-injury via activating L type calcium channels and extinguish it by blocking the same channels.  It is proven in mice and seems to apply to at least some humans.

Calcium channel activation and self-biting in mice

The L type calcium channel agonist (±)Bay K 8644 has been reported to cause characteristic motor abnormalities in adult mice. The current study shows that administration of this drug can also cause the unusual phenomenon of self-injurious biting, particularly when given to young mice.

The self-biting provoked by (±)Bay K 8644 can be inhibited by pretreating the mice with dihydropyridine L type calcium channel antagonists such as nifedipine, nimodipine, or nitrendipine. However, self-biting is not inhibited by nondihydropyridine antagonists including diltiazem, flunarizine, or verapamil.

(±)Bay K 8644 functions as an L type calcium channel activator that increases calcium fluxes in response to depolarizing stimuli (). In rodents, this drug has been reported to produce characteristic motor abnormalities including impaired ambulation, twisting and stretching movements, transient limb extension, back arching, spasticity, ataxia, or catatonia (). Some studies have anecdotally noted the occurrence of SIB with this drug (), though this phenomenon has received little attention. The current study shows that (±)Bay K 8644 will reliably provoke SB and SIB under certain conditions in mice, providing a tool to study the neurobiology of this unusual behavior.

 

When I first encountered the above study, I did wonder why Verapamil did not extinguish the self-injury.

It turns out that Bay K 8644 is a modified version of the common drug nifedipine, which is a Cav1.3 blocker.  Verapamil is mainly a Cav1.2 blocker.  Bay K 8644 is like the opposite of nifedipine.

In the trial they have activated Cav1.3 causing excess calcium inside neurons. The only way to block this process is to block Cav1.3. Blocking Cav1.2 with Verapamil could not solve the problem. 

Note that activation of Cav1.3 can cause motor abnormities in mice and this might be seen as ataxia in a human. One particular reader of this blog will see the relevance of this. 

I did write extensively in earlier posts about the large amount of research that links L type calcium channels to neuropsychiatric disorders.

I did mainly focus on Cav1.2 using Verapamil, but the evidence for the role of Cav1.3 is clear as day. 

L-type calcium channels as drug targets in CNS disorders

 L-type calcium channels are present in most electrically excitable cells and are needed for proper brain, muscle, endocrine and sensory function. There is accumulating evidence for their involvement in brain diseases such as Parkinson disease, febrile seizures and neuropsychiatric disorders. Pharmacological inhibition of brain L-type channel isoforms, Cav1.2 and Cav1.3, may therefore be of therapeutic value.

 

From Gene to Behavior: L-Type Calcium Channel Mechanisms Underlying Neuropsychiatric Symptoms.

The L-type calcium channels (LTCCs) Cav1.2 and Cav1.3, encoded by the CACNA1C and CACNA1D genes, respectively, are important regulators of calcium influx into cells and are critical for normal brain development and plasticity. In humans, CACNA1C has emerged as one of the most widely reproduced and prominent candidate risk genes for a range of neuropsychiatric disorders, including bipolar disorder (BD), schizophrenia (SCZ), major depressive disorder, autism spectrum disorder, and attention deficit hyperactivity disorder.

Here, we provide a review of clinical studies that have evaluated LTCC blockers for BD, SCZ, and drug dependence-associated symptoms, as well as rodent studies that have identified Cav1.2- and Cav1.3-specific molecular and cellular cascades that underlie mood (anxiety, depression), social behavior, cognition, and addiction.

 

Was I surprised that Amlodipine, that targets Cav1.3 rather than Cav1.2, was very beneficial in someone with severe autism?  Not at all.

I was interested that the effect was more pro-cognitive than anti-anxiety.  Is that the effect on Cav1.3 or is it via that N channel Cav2.2?

N-type calcium channels are important in neurotransmitter release because they are localized at the synaptic terminals. Piracetam, the original cognitive enhancing drug, is also a N type channel blocker.

  

Statins and L type calcium channels blockers – it matters which one you choose

We previously saw how the statin class of drugs can be beneficial in autism, but it depends which one you chose. For example, in SLOS (Smith-Lemli-Opitz syndrome), where both copies of the gene DHCR7 are mutated, you need to push the gene to work. To increase expression of this gene you need Simvastatin. This is hard for people to understand because SLOS features very low cholesterol and statins are thought of as cholesterol lowering drugs. The body needs the enzyme DHCR7 to make cholesterol and Simvastatin increases DHCR7 expression.

In the case of L type channel blockers, the selection is very important.  The effect will not be the same.

If you have a mutation in Cav1.2, you would expect Verapamil to be a good choice.  If the mutation is in Cav1.3, you would expect Amlodipine to be better.

If you have over expression of T channels (Cav3.1, Cav3.2 or Cav3.3) then you would expect a benefit from Verapamil and none from Amlodipine.

If you have over expression of the N channel (Cav2.2) then you would want Amlodipine

If you have over expression of the sodium channel Nav1.8 then you would want Nicardipine

  

Conclusion

It is likely that many people with autism, bipolar, ADHD or schizophrenia might benefit from treating their ion channel dysfunctions.  The required drugs are cheap generics that have been in your local pharmacy for a few decades.

Back in 2019 I wrote the post below:

Cheap common drugs may help mental illness

I highlighted a new study, using historic data from Sweden, that looked at the secondary effects of statins, calcium channel blockers and metformin on psychiatric hospitalization.

 

Association of Hydroxylmethyl Glutaryl Coenzyme A Reductase Inhibitors, L-Type Calcium Channel Antagonists, and Biguanides With Rates of Psychiatric Hospitalization and Self-Harm in Individuals With Serious Mental Illness

 

Question  Are drugs in common use for physical health problems (hydroxylmethyl glutaryl coenzyme A reductase inhibitors, L-type calcium channel antagonists, and biguanides) associated with reduced rates of psychiatric hospitalization and self-harm in individuals with serious mental illness?

Findings  In this series of within-individual cohort studies of 142 691 patients with bipolar disorder, schizophrenia, or nonaffective psychosis, exposure to any of the study drugs was associated with reduced rates of psychiatric hospitalization compared with unexposed periods. Self-harm was reduced in patients with bipolar disorder and schizophrenia during exposure to all study drugs and in patients with nonaffective psychosis taking L-type calcium channel antagonists. 

We found that periods of HMG-CoA RI (statin) exposure were associated with reduced psychiatric hospitalization in all subgroups of SMI (Serious Mental Illness) and with reduced self-harm in BPD and schizophrenia.

Exposure to LTCC (L type calcium channel) antagonists was associated with reduced rates of psychiatric hospitalization and self-harm.

Periods of metformin (a type 2 diabetes drug) exposure were associated with reduced psychiatric and nonpsychiatric hospitalization across all SMI subgroups.

 

Use of L type calcium channel blockers reduces self-harm.

How much more evidence is needed?

I took an educated guess several years ago that Verapamil would tame summertime raging in my son.  It was the only calcium channel blocker I tried and it worked. This year we had the emergence of extreme sound sensitivity. My educated guess was that blocking potassium channels with Ponstan (Mefenamic acid) would resolve the problem, and it did.  

Treating ion channel dysfunctions (channelopathies) in autism clearly is not rocket science; it is just waiting to be attempted.