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Wednesday, 23 October 2019

GABAa receptor trafficking, Migraine, Pain, Light Sensitivity, Autophagy, Jacobsen Syndrome, Angelman Syndrome, GABARAP, TRPV1, PX-RICS, CaMKII and CGRP ... Oh and the "fever effect"



The mechanism controlling transporting just the “right” number of GABAA receptors


Today’s post is not for the faint-hearted.  It is another one that could just keep on rolling.  Ling will like it.

It again shows that GABAA receptors are at the centre of much autism, whether single gene or idiopathic. Today we highlight what can go wrong as these receptors are “transported”.

Today’s post also draws on several quite recent papers. It seeks to tie together some previous things mentioned in this blog like the symptoms of pain, particularly felt in the head, sensory sensitivity with dysfunction processes like autophagy and linking it all back to the GABAA receptor.  There is even a link at the end to the "fever effect", which occurs when a high temperature in some people causes a marked improvement in their autism symptoms.

We will come across some expensive drugs like Erenumab, the medical food PEA (Palmitoylethanolamide) and indeed Natasa’s favourite, CBD (Cannabidiol) and a newcomer CBDV (Cannabidivarin).   
We come across a protein called GABARAP (GABAA receptor associated protein) for the first time in this blog.  There is a vast amount in this blog about the GABAA receptor, how and why to modulate it. 

CaMKII makes an appearance, this is a protein kinase that is miss-regulated in much neurological disease. It changes the effect of many other proteins, acting just like a switch, by chemically adding phosphate groups to them. We have previously seen how important the protein kinases PKA, PKB and PKC are to autism.  Today add CaMKII to the list.

We come across another distinctive “face” of autism, this time it is Jacobsen syndrome, which I think is easily spotted by the trained eye, or some facial recognition software.  Jacobsen syndrome is a rare chromosomal disorder resulting from deletion of genes from chromosome 11 that includes band 11q24. This may include the gene that encodes the protein PX-RICS and, if so, it will lead to “autism”. Loss of that gene should be treatable with a GABA agonist.     

We also come back to that happy puppet syndrome (Angelman syndrome) which usually involves loss of the gene UBE3A, from chromosome 15. What I found interesting was that both Jacobsen syndrome and Angelman syndrome should share impaired GABAA receptor trafficking as a feature. They each have a different impediment that should reduce the number of functioning GABAA receptors. In the case of Angelman the impediment is CaMKII inhibition, in Jacobsen it is lack of the protein PX-RICS. Angelman syndrome may well respond to the same therapy as Jacobsen syndrome – a GABA agonist, of just a PAM (positive allosteric modulator, to “turn up the volume”).

Back to GABARAP

GABARAP has multiple functions:

1.     Transport of freshly minted GABAA receptors

In order for newly minted GABAA receptors to get to their final destination it requires four “helpers”: GABARAP, PX-RICS, 14-3-3 and Dynactin.  In addition, you need a dose of CaMKII. If you lack any one of these four, you will end up with reduced expression of GABAA receptors. If CaMKII is overactivated you get too many GABAA receptors.

In Jacobsen Syndrome there is reduced GABAA receptor trafficking/transport, leading to reduced surface expression. (in effect not enough functioning GABAA receptors in situ).  In some people with this syndrome the part of their DNA which encodes PX-RICS is missing.  This lack of PX-RICS produces autism.  The autism-like behavioural abnormalities in PX-RICS-deficient mice are ameliorated by enhancing inhibitory synaptic transmission with a GABAAR agonist.

2.     GABARAP modulates TRPV1 expression

GABARAP also does something totally different, it modulates TRPV1 ion channels, that we have previously touched on in this blog.  This then triggers a cascade of effects relating to pain, neuralgia, migraine headaches, microglial activation, epilepsy and indeed longevity.

The simple function of TRPV1 is detection and regulation of body temperature. In addition, TRPV1 provides a sensation of scalding heat and pain. TRPV1 is also known as the capsaicin receptor.  Capsaicin is the active component of chilli peppers.
TRPV1 not only plays a role in pain, but is suggested to play a role in migraine. In migraine TRPV1 plays a role along with calcitonin gene-related peptide receptor (CGRPR). TRPV1 determines how much of the CGRPR protein is produced. CGRPR affects your metabolism broadly and as such plays a key role in longevity.  Ablation of select pain sensory receptors (TRPV1) or the inhibition of CGRP are associated with increased metabolic health and longevity.
Erenumab/Aimovig is a medication which targets CGRPR for the prevention of migraine. It was the first of the group of CGRPR antagonists to be FDA approved in 2018. It is a form of monoclonal antibody therapy in which antibodies are used to block the receptors for the protein CGRP, thought to play a major role in starting migraines.
Recent evidence suggests that TRPV1 may contribute to the onset and progression of some forms of epilepsy;  Cannabidivarin  (CBDV) and cannabidiol (CBD), activate and desensitize TRPV1.
TRPV1 also plays a crucial role in the activation of microglia. As the researchers put it “TRPV1 channels are critical brain inflammation detectorsmicroglia shifted toward an anti-inflammatory phenotype when TRPV1 is lacking.

So, if we jump a few steps forward we can see that desensitizing TRPV1 might be helpful for people with: -

·        Some epilepsy
·        Some neuralgia
·        Perhaps some with chronic migraine
·        People with activated microglia, which is most autism

We also can see that a dysfunction in GABARAP may itself contribute to worsening the above conditions via its effect on TRPV1.


Epilepsy is the most common neurological disorder, with over 50 million people worldwide affected. Recent evidence suggests that the transient receptor potential cation channel subfamily member 1 (TRPV1) may contribute to the onset and progression of some forms of epilepsy. V Since the two nonpsychotropic cannabinoids cannabidivarin (CBDV) and cannabidiol (CBD) exert anticonvulsant activity in vivo and produce TRPV1-mediated intracellular calcium elevation in vitro, we evaluated the effects of these two compounds on TRPV1 channel activation and desensitization and in an in vitro model of epileptiform activity. Patch clamp analysis in transfected HEK293 cells demonstrated that CBD and CBDV dose-dependently activate and rapidly desensitize TRPV1, as well as TRP channels of subfamily V type 2 (TRPV2) and subfamily A type 1 (TRPA1). TRPV1 and TRPV2 transcripts were shown to be expressed in rat hippocampal tissue. When tested on epileptiform neuronal spike activity in hippocampal brain slices exposed to a Mg2+-free solution using multielectrode arrays (MEAs), CBDV reduced both epileptiform burst amplitude and duration. The prototypical TRPV1 agonist, capsaicin, produced similar, although not identical effects. Capsaicin, but not CBDV, effects on burst amplitude were reversed by IRTX, a selective TRPV1 antagonist. These data suggest that CBDV antiepileptiform effects in the Mg2+-free model are not uniquely mediated via activation of TRPV1. However, TRPV1 was strongly phosphorylated (and hence likely sensitized) in Mg2+-free solution-treated hippocampal tissue, and both capsaicin and CBDV caused TRPV1 dephosphorylation, consistent with TRPV1 desensitization. We propose that CBDV effects on TRP channels should be studied further in different in vitro and in vivo models of epilepsy.


TRPV1 channels are critical brain inflammation detectors and neuropathic pain biomarkers in mice

The capsaicin receptor TRPV1 has been widely characterized in the sensory system as a key component of pain and inflammation. A large amount of evidence shows that TRPV1 is also functional in the brain although its role is still debated. Here we report that TRPV1 is highly expressed in microglial cells rather than neurons of the anterior cingulate cortex and other brain areas. We found that stimulation of microglial TRPV1 controls cortical microglia activation per se and indirectly enhances glutamatergic transmission in neurons by promoting extracellular microglial microvesicles shedding. Conversely, in the cortex of mice suffering from neuropathic pain, TRPV1 is also present in neurons affecting their intrinsic electrical properties and synaptic strength. Altogether, these findings identify brain TRPV1 as potential detector of harmful stimuli and a key player of microglia to neuron communication.

TRPV1 controls cortical microglia activation

In the healthy mature brain, microglial cells play a role in immune surveillance and ensure the maintenance of brain homeostasis. Upon injuries these cells shift to an activated state characterized by drastic changes in the cellular shape, functional behavior and by the release of different proinflammatory and immunoregulatory factors58,59. Conforming to the capsaicin-mediated induction of microglial chemotaxis29, we investigated whether TRPV1 stimulation regulates the morphology of microglial cells…. Thus, stimulation of TRPV1 induced a pro-inflammatory phenotype of microglia from WTs. Conversely, microglia shifted toward an anti-inflammatory phenotype when TRPV1 is lacking.


Angelman syndrome

Angelman syndrome (Happy puppet syndrome) is a genetic disorder that mainly affects the nervous system. Symptoms include a small head and a specific facial appearance, severe intellectual disability, developmental disability, speaking problems, balance and movement problems, seizures, and sleep problems. Children usually have a happy personality and have a particular interest in water. The symptoms generally become noticeable by one year of age.  Angelman syndrome is typically due to a new mutation rather than one inherited from a person's parents. Angelman syndrome is due to a lack of function of part of chromosome 15 inherited from a person's mother. Most of the time, it is due to a deletion or mutation of the UBE3A gene.

CaMKII inhibition underlies Angelman Syndrome



CaMKII
CaMKII is a serine/threonine-specific protein kinase that is regulated by the Ca2+/calmodulin complex. CaMKII is involved in many signaling cascades and is thought to be an important mediator of learning and memory. CaMKII is also necessary for Ca2+ homeostasis and reuptake in cardiomyocytes, chloride transport in epithelia, positive T-cell selection, and CD8 T-cell activation.
Misregulation of CaMKII is linked to Alzheimer’s disease, Angelman syndrome, and heart arrhythmia.

Recent evidence for CaMKII dysregulation in psychiatric diseases is reviewed.
Changes in postsynaptic structure and function appear to be central to multiple diseases.
Altered regulation of the CaMKIIα gene promoter may be a common mechanism among diseases.
CaMKII dysregulation in diverse brain regions may account for myriad disorders.
Although it has been known for decades that hippocampal calcium/calmodulin (CaM)-dependent protein kinase II (CaMKII) plays an essential role in learning and memory consolidation, the roles of CaMKII in other brain regions are only recently being explored in depth. A series of recent studies suggest that CaMKII dysfunction throughout the brain may underlie myriad neuropsychiatric disorders, including drug addiction, schizophrenia, depression, epilepsy, and multiple neurodevelopmental disorders, perhaps through maladaptations in glutamate signaling and neuroplasticity. I review here the structure, function, subcellular localization, and expression patterns of CaMKII isoforms, as well as recent advances demonstrating that disturbances in these properties may contribute to psychiatric disorders.

A Novel Human CAMK2A Mutation Disrupts Dendritic Morphology and Synaptic Transmission, and Causes ASD-Related Behaviors


Characterizing the functional impact of novel mutations linked to autism spectrum disorder (ASD) provides a deeper mechanistic understanding of the underlying pathophysiological mechanisms. Here we show that a de novo Glu183 to Val (E183V) mutation in the CaMKIIα catalytic domain, identified in a proband diagnosed with ASD, decreases both CaMKIIα substrate phosphorylation and regulatory autophosphorylation, and that the mutated kinase acts in a dominant-negative manner to reduce CaMKIIα-WT autophosphorylation. The E183V mutation also reduces CaMKIIα binding to established ASD-linked proteins, such as Shank3 and subunits of l-type calcium channels and NMDA receptors, and increases CaMKIIα turnover in intact cells. In cultured neurons, the E183V mutation reduces CaMKIIα targeting to dendritic spines. Moreover, neuronal expression of CaMKIIα-E183V increases dendritic arborization and decreases both dendritic spine density and excitatory synaptic transmission. Mice with a knock-in CaMKIIα-E183V mutation have lower total forebrain CaMKIIα levels, with reduced targeting to synaptic subcellular fractions. The CaMKIIα-E183V mice also display aberrant behavioral phenotypes, including hyperactivity, social interaction deficits, and increased repetitive behaviors. Together, these data suggest that CaMKIIα plays a previously unappreciated role in ASD-related synaptic and behavioral phenotypes.
SIGNIFICANCE STATEMENT Many autism spectrum disorder (ASD)-linked mutations disrupt the function of synaptic proteins, but no single gene accounts for >1% of total ASD cases. The molecular networks and mechanisms that couple the primary deficits caused by these individual mutations to core behavioral symptoms of ASD remain poorly understood. Here, we provide the first characterization of a mutation in the gene encoding CaMKIIα linked to a specific neuropsychiatric disorder. Our findings demonstrate that this ASD-linked de novo CAMK2A mutation disrupts multiple CaMKII functions, induces synaptic deficits, and causes ASD-related behavioral alterations, providing novel insights into the synaptic mechanisms contributing to ASD.

Jacobsen Sydrome

The signs and symptoms of Jacobsen syndrome can vary. Most affected people have delayed development of motor skills and speech; cognitive impairment; and learning difficulties. Behavioral features have been reported and may include compulsive behavior; a short attention span; and distractibility. Many people with the condition are diagnosed with attention deficit-hyperactivity disorder (ADHD). The vast majority of people with Jacobsen syndrome also have a bleeding disorder called Paris-Trousseau syndrome, which causes abnormal bleeding and easy bruising. 

People with Jacobsen syndrome typically have distinctive facial features, which include small and low-set ears; wide-set eyes (hypertelorism) with droopy eyelids (ptosis); skin folds covering the inner corner of the eyes; a broad nasal bridge; down-turned corners of the mouth; a thin upper lip; and a small lower jaw (micrognathia). Affected people often have a large head (macrocephaly) and a skull abnormality called trigonocephaly, giving the forehead a pointed appearance.

The Autism-Related Protein PX-RICS Mediates GABAergic Synaptic Plasticity in Hippocampal Neurons and Emotional Learning in Mice


GABAergic dysfunction underlies many neurodevelopmental and psychiatric disorders. GABAergic synapses exhibit several forms of plasticity at both pre- and postsynaptic levels. NMDA receptor (NMDAR)–dependent inhibitory long-term potentiation (iLTP) at GABAergic postsynapses requires an increase in surface GABAARs through promoted exocytosis; however, the regulatory mechanisms and the neuropathological significance remain unclear. Here we report that the autism-related protein PX-RICS is involved in GABAAR transport driven during NMDAR–dependent GABAergic iLTP. Chemically induced iLTP elicited a rapid increase in surface GABAARs in wild-type mouse hippocampal neurons, but not in PX-RICS/RICS–deficient neurons. This increase in surface GABAARs required the PX-RICS/GABARAP/14–3-3 complex, as revealed by gene knockdown and rescue studies. iLTP induced CaMKII–dependent phosphorylation of PX-RICS to promote PX-RICS–14-3-3 assembly. Notably, PX-RICS/RICS–deficient mice showed impaired amygdala–dependent fear learning, which was ameliorated by potentiating GABAergic activity with clonazepam. Our results suggest that PX-RICS–mediated GABAAR trafficking is a key target for GABAergic plasticity and its dysfunction leads to atypical emotional processing underlying autism.

There is a growing consensus that autism arises from the atypical regulation of the excitation/inhibition balance within specific neural microcircuitry. In terms of neural inhibition, autism is closely related to dysfunctional inhibitory signaling mediated by the γ-aminobutyric acid (GABA) type A receptors (GABAARs). Impaired presynaptic release of GABA and postsynaptic trafficking of GABAARs lead to autistic-like social behavior in mouse models of autism. There is a significant reduction in the number of GABAARs and GABAergic activity in certain brain areas of autistic individuals. Genetic association studies have revealed that several GABAAR subunits are linked to an increased risk for autism. GABAAR–mediated signaling is thus essential for the proper regulation of the excitation/inhibition balance associated with socio-emotional cognition.

PX-RICS, GABARAP and 14-3-3ζ/θ are localized in the specific dendritic compartments that are immunopositive for organelle markers for the endoplasmic reticulum (ER), ER exit sites and the trans-Golgi network. This structure, termed the dendritic satellite secretory pathway, is comprised of the dendritic ER and the Golgi outposts and is involved in the local synthesis, processing and transport of membrane-integral or secretory proteins in dendrites. The rapid increase in surface-expressed GABAARs after NMDA stimulation could be explained by the localization of the PX-RICS–dependent trafficking machinery in the dendritic secretory compartments.
Several lines of evidence suggest that the dysregulation of GABA signaling underlies atypical social behavior in autism However, there has been no report describing deficits in GABAergic plasticity that contribute to autistic features. The present study has shown that PX-RICS is essential for GABAergic iLTP and that loss of the PX-RICS function in mice leads to impaired cued fear learning. Cued fear learning is closely associated with GABAAR–mediated activity and plasticity in the amygdala and is inversely correlated with the severity of autistic symptoms. Considering all of these findings, we thus reason that PX-RICS–dependent GABAAR transport may play critical roles in emotional learning in the amygdala through the control of GABAergic synaptic plasticity and that the impairment of this transport mechanism may lead to improper socio-emotional processing, resulting in autistic-like atypical social behavior (Supplementary Fig. 7). Further elucidation of the functional link between GABAergic plasticity and socio-emotional learning could lead to a better understanding of autism pathogenesis and treatment. 
We have previously identified and characterized two splicing isoforms of GTPase-activating proteins specific for Cdc42 predominantly expressed in neurons of the cerebral cortex, amygdala and hippocampus: RICS (ARHGAP32 isoform 2) and PX-RICS (ARHGAP32 isoform 1) . RICS regulates NMDAR–mediated signaling at the postsynaptic density and axonal elongation at the growth cone. In contrast, PX-RICS forms an adaptor complex with GABARAP and 14-3-3ζ/θ to facilitate steady-state trafficking of the N-cadherin/β-catenin complex and GABAARs. PX-RICS is also responsible for autistic-like features observed in more than half of the patients with Jacobsen syndrome (JBS) [3]. Mice lacking PX-RICS/RICS show marked decreases in surface-expressed GABAARs and GABAAR–mediated inhibitory synaptic transmission, resulting in various autistic-like behaviors and autism-related comorbidities. Rare single-nucleotide variations in PX-RICS are also linked to non-syndromic autism, schizophrenia and alexithymia. These findings strongly suggest that dysfunction of PX-RICS–mediated GABAAR trafficking has severe effects on socio-emotional processing of the brain.
Our previous study described above showed that PX-RICS and other components of the GABAAR trafficking complex are required for constitutive transport of the receptor. In this study, we have focused on the role of PX-RICS in the activity–induced promotion of GABAAR trafficking during iLTP. Here we show that PX-RICS–mediated GABAAR trafficking is also involved in NMDAR activity–dependent trafficking of GABAARs and that PX-RICS is a key target of CaMKII for regulating GABAergic synaptic plasticity. Furthermore, we show that PX-RICS dysfunction in mice leads to impaired amygdala–dependent emotional learning, which manifests as autistic-like social behavior [3].




Supplementary Fig. 7. PX-RICS–mediated GABAAR trafficking underlies NMDAR–dependent GABAergic iLTP PX-RICS, GABARAP and 14-3-3s are assembled to form an adaptor complex that interconnects γ2-containing GABAARs (cargo) and dynein/dynactin (motor). Interaction
of PX-RICS with 14-3-3s depends on the phosphorylation activity of CaMKII, and this interaction is a critical regulatory point for GABAAR trafficking. When CaMKII activity is at a basal level, the PX-RICS–mediated trafficking complex has a role in steady-state transport of GABAARs to maintain the number of surface GABAARs as needed for proper synaptic inhibition.3 Neural activity that evokes moderate Ca2+ influx through NMDAR preferentially increases the activated form of CaMKII and elicits its translocation to inhibitory synapses, where it phosphorylates target proteins such as gephyrin and the GABAAR β3 subunit. Phosphorylated gephyrin and the GABAAR β3 subunit regulate the surface dynamics of GABAARs such as lateral diffusion and synaptic confinement. The present study has revealed that PXRICS
is a downstream CaMKII target associated with anterograde transport of
GABAARs. Enhanced PX-RICS phosphorylation increases the PX-RICS–14-3-3 complex and thereby drives de novo GABAAR surface expression, resulting in GABAergic iLTP. Dysfunction of this trafficking mechanism in the amygdala causes impaired GABAergic synaptic plasticity, which may contribute to deficits in socioemotional behavior as observed in PX-RICS/RICS–deficient mice and JBS patients with autism.


PX-RICS-deficient mice mimic autism spectrum disorder in Jacobsen syndrome through impaired GABAA receptor trafficking


Jacobsen syndrome (JBS) is a rare congenital disorder caused by a terminal deletion of the long arm of chromosome 11. A subset of patients exhibit social behavioural problems that meet the diagnostic criteria for autism spectrum disorder (ASD); however, the underlying molecular pathogenesis remains poorly understood. PX-RICS is located in the chromosomal region commonly deleted in JBS patients with autistic-like behaviour. Here we report that PX-RICS-deficient mice exhibit ASD-like social behaviours and ASD-related comorbidities. PX-RICS-deficient neurons show reduced surface γ-aminobutyric acid type A receptor (GABAAR) levels and impaired GABAAR-mediated synaptic transmission. PX-RICS, GABARAP and 14-3-3ζ/θ form an adaptor complex that interconnects GABAAR and dynein/dynactin, thereby facilitating GABAAR surface expression. ASD-like behavioural abnormalities in PX-RICS-deficient mice are ameliorated by enhancing inhibitory synaptic transmission with a GABAAR agonist. Our findings demonstrate a critical role of PX-RICS in cognition and suggest a causal link between PX-RICS deletion and ASD-like behaviour in JBS patients.


TRPV1

We now come back to TRPV1, which we saw is modulated by GABARAP.

GABAA receptor associated protein (GABARAP) modulates TRPV1 expression and channel function and desensitization


Transient receptor potential vanilloid (TRPV1) transduces noxious chemical and physical stimuli in high-threshold nociceptors. The pivotal role of TRPV1 in the physiopathology of pain transduction has thrust the identification and characterization of interacting partners that modulate its cellular function. Here, we report that TRPV1 associates with γ-amino butyric acid A-type (GABAA) receptor associated protein (GABARAP) in HEK293 cells and in neurons from dorsal root ganglia coexpressing both proteins. At variance with controls, GABARAP augmented TRPV1 expression in cotransfected cells and stimulated surface receptor clustering. Functionally, GABARAP expression attenuated voltage and capsaicin sensitivity of TRPV1 in the presence of extracellular calcium. Furthermore, the presence of the anchor protein GABARAP notably lengthened the kinetics of vanilloid-induced tachyphylaxia. Notably, the presence of GABARAP selectively increased the interaction of tubulin with the C-terminal domain of TRPV1. Disruption of tubulin cytoskeleton with nocodazole reduced capsaicin-evoked currents in cells expressing TRPV1 and GABARAP, without affecting the kinetics of vanilloid-induced desensitization. Taken together, these findings indicate that GABARAP is an important component of the TRPV1 signaling complex that contributes to increase the channel expression, to traffic and cluster it on the plasma membrane, and to modulate its functional activity at the level of channel gating and desensitization.

‘Entourage’ effectsof N‐palmitoylethanolamide and N‐oleoylethanolamide on vasorelaxation to anandamide occur through TRPV1 receptors



Age-Dependent Anti-seizure and Neuroprotective Effect of Cannabidivarin in Neonatal Rats


Neonatal seizures and seizures of infancy represent a significant cause of morbidity. 30–40% of infants and children with seizures will fail to achieve seizure remission with current anti-epileptic drug (AED) treatment. Moreover, pharmacotherapy during critical periods of brain development can adversely affect nervous system function. We, and others, have shown that early life exposure to AEDs including phenobarbital, phenytoin, and valproate are associated with induction of enhanced neuronal apoptosis during a confined period of postnatal development in rats. Thus, identification of new therapies for neonatal/infantile epilepsy syndromes that provide seizure control without neuronal toxicity is a high priority.
Current clinical trials report that modulation of the cannabinoid system with the phytocannabinoid cannabidiol exerts anti-seizure effects in children with epilepsy. While cannabidiol and the propyl analog cannabidivarin (CBDV) display anti-seizure efficacy in adult animal models of seizures/epilepsy, they remained unexplored in neonatal models. Therefore, we investigated the therapeutic potential of CBDV in multiple neonatal rodent seizure models. To evaluate the therapeutic potential of CBDV, we tested its anti-seizure efficacy in five models of neonatal seizures: pentylenetetrazole (PTZ), DMCM, hypoxia, kainate and NMDA-evoked spasms, each representing a different clinical seizure phenotype. We also evaluated the preclinical safety profile in the developing brain.
Postnatal day (P) 10 or P20 male, Sprague-Dawley rat pups were pretreated with CBDV or vehicle prior to chemically or hypoxia induced seizures. CBDV only displayed anticonvulsant effects in the P20 rat pups in the PTZ and DMCM models, with no effect on seizure severity or latency in the P10 animals. Therefore, we next measured the relative expression of known targets for CBDV (TRPV1, TRPA1) to determine a mechanism for which CBDV is anticonvulsant in P20, but not P10 animals. The P20 animals show increased expression of TRPV1 in key brain regions implicated in epileptogenic activity.
Together, these results indicate that modulation of the cannabinoid system in a receptor independent manner can provide seizure control in developing animals, but in an age specific manner. Further, during a developmentally sensitive neonatal period, drugs targeting the cannabinoid system do not induce neuronal apoptosis characteristic of many other AEDs. These results provide some of the first systemic, preclinical data evaluating CBDV in pediatric models of epilepsy.


Weight-based dosing of 10 mg/kg/day of CBDV for 12 weeks
Primary Outcome Measures  :
1.     Aberrant Behavior Checklist-Irritability Subscale (ABC-I) [ Time Frame: Change in ABC-I from Baseline to Week 12 (Change over 12 weeks) ]
Change in ABC-I from Baseline to Endpoint


  

Lack of Autophagy will reduce the number of GABAA receptors, by blocking GABARAP function

Regular readers will recall that one feature of autism and many other neurological diseases is a reduction in autophagy, which I likened to an intra-cellular garbage collection service. 

The very recent paper below shows that lack of autophagy blocks GABARAP from its job to transport freshly minted GABAA receptors.
If correct, this actually has very wide implications.



The disruption of MTOR-regulated macroautophagy/autophagy was previously shown to cause autistic-like abnormalities; however, the underlying molecular defects remained largely unresolved. In a recent study, we demonstrated that autophagy deficiency induced by conditional Atg7 deletion in either forebrain GABAergic inhibitory or excitatory neurons leads to a similar set of autistic-like behavioral abnormalities even when induced following the peak period of synaptic pruning during postnatal neurodevelopment. Our proteomic analysis and molecular dissection further revealed a mechanism in which the GABAA receptor trafficking function of GABARAP (gamma-aminobutyric acid receptor associated protein) family proteins was compromised as they became sequestered by SQSTM1/p62-positive aggregates formed due to autophagy deficiency. Our discovery of autophagy as a link between MTOR and GABA signaling may have implications not limited to neurodevelopmental and neuropsychiatric disorders, but could potentially be involved in other human pathologies such as cancer and diabetes in which both pathways are implicated.


Conclusion

You may have skipped to the conclusion to avoid all the science.

The conclusion is simple, you need to keep your GABAA receptors in tip top form if you want to avoid the symptoms of autism.

o   You need the right number of them
o   You need the right balance among the five constituent subunits
o   You need the correct level of chloride inside neurons so the receptors are not “working backwards”

All of the genes that encode proteins involved in the above are individually “autism genes”, because any one of them can disrupt the process.

Whether it is Dravet syndrome (GABAA receptor α2 subunit), Angelman syndrome, Jacobsen syndrome, Down syndrome or numerous other autism syndromes, not to mention idiopathic autism, check the above 3 bullet points.

Tune up/down your GABAA receptors!

Desensitizing TRPV1 looks interesting and not just for epilepsy.  TRPV1 appears to be essential for microglia in the in brain to be activated.  We know that in autism microglia in the brain are permanently activated, as if there was a threat.

I do think there is cross-talk (feedback loops etc) going on here, for example you can treat the severe epilepsy in Dravet syndrome by any of the following:-

·        KBr, to lower intracellular chloride
·        Low dose clonazepam to affect α subunits of GABAA receptors
·        CBD or CBDV to modify TRPV1


Note that Dravet syndrome is caused by a mutation in the gene that encodes the sodium ion channel Nav1.1, the dysfunction of GABAA receptors is a secondary effect. Also of interest is that the seizures that occur in Dravet syndrome are often triggered by hot temperatures or fever, so you can see how TRPV1 is indeed likely involved.  More generally in idiopathic autism, we have the "fever effect" when high temperatures trigger a reduction in autistic behaviors, making it the opposite of Dravet syndrome. 

On the one hand the biology behind the various problems may look horribly complicated and interwoven, the solutions appear to be much simpler and you have multiple options.

I await the results of the autism clinical trial of CBDV (Cannabidivarin) with interest.

Just impaired autophagy may lead to a reduction in GABAA receptors and the appearance of autistic features in an otherwise “normal” brain. This reminds us again of why autism is not a medical diagnosis, it is just a vague/subjective observation, which, in severe cases, should then trigger a thorough medical investigation.









Wednesday, 16 October 2019

DMF for Mitochondrial Dysfunction in Autism and Friedreich's Ataxia?


Yet more money was just donated to autism research. In 2017 the CEO of Broadcom gave $20 million to MIT and now he has given $20 million to Harvard, where he did his MBA.




Time to boost Homer's mitochondria?


I think philanthropists from the fast-moving IT sector should demand rather more from the slow-moving world of autism research.  I also think common sense is often more lacking than money.

The US Government has also just announced $1.8 billion for autism research.

Donald Trump authorized a five-year extension of the Autism Collaboration, Accountability, Research, Education and Support (CARES) Act. The 2014 act dedicated funds to children with autism spectrum disorder, but the new version includes adults.  Children with autism do indeed grow up to become adults with autism. 
Today we look at further applications of DMF, which is a cheap chemical also sold as a very expensive drug.

We learnt from Dr Kelley, from Johns Hopkins, that most regressive autism features mitochondrial dysfunction. Mitochondria within cells produce ATP (fuel) via a complex multi-step process called OXPHOS. If you lack any of the required enzyme complexes for OXPHOS, that part of your body will suffer a power shortage/outage.  Another potential problem is just too few mitochondria.

The treatment for mitochondrial disease is mainly to avoid further damage, using antioxidants.  If you know which enzyme complex is lacking, you might try and target that.

We saw a long time ago in this blog that PGC-1α is the master regulator of mitochondrial biogenesis and as such this would be a target for people with mitochondrial dysfunction.

Among other interactions, PGC-1α is affected by something called PPAR-γ (Peroxisome proliferator-activated receptor gamma), also known as the glitazone receptor.

There are many cheap drugs that target PPAR-γ, because this is also one way to treat type 2 diabetes.  We saw that Glitazone drugs have been successfully trialed in autism.

Today we look at another way to activate PGC-1α and stimulate the production of more mitochondria and increase the necessary enzyme complexes for OXPHOS.

Many people with autism in the US are diagnosed by their MAPS/DAN doctor as lacking Complex 1.

DMF has two principal effects. It affects NRF2 and HCAR2.

Many supplements sold online are supposed to activate NRF2, but may well lack potency.

Activating NRF2 turns on your antioxidant defences and so is good for people with autism, diabetes, COPD and many other conditions, but is bad for someone with cancer.

We will see later how, somewhat bizarrely, at high doses DMF reverses function and causes cell death via oxidative stress, making it a potent potential cancer therapy.  Cancer cells are highly vulnerable to oxidative stress.

In this blog we are focusing on low doses of DMF, that are NRF2 activating.

In the chart below the NFE2L2 gene encodes the transcription factor NRF2. We want the antioxidant genes turned on.

We then get another benefit because NRF2 expression also regulates NRF1 expression.

The transcription factor NRF1 is another regulator of mitochondrial biogenesis with involvements in mitochondrial replication  and transcription of mitochondrial DNA.

We then get a third benefit from DMF via activating HCAR2, this time we increase Complex I expression.  In the OXPOS multistep process to make fuel/ATP the bottleneck is usually Complex I, so Complex I is often referred to as being “rate limiting”. Complex I is the most important deficiency to fix.









Dimethyl fumarate mediates Nrf2-dependent mitochondrial biogenesis in mice and humans



The induction of mitochondrial biogenesis could potentially alleviate mitochondrial and muscle disease. We show here that dimethyl fumarate (DMF) dose-dependently induces mitochondrial biogenesis and function dosed to cells in vitro, and also dosed in vivo to mice and humans. The induction of mitochondrial gene expression is more dependent on DMF's target Nrf2 than hydroxycarboxylic acid receptor 2 (HCAR2). Thus, DMF induces mitochondrial biogenesis primarily through its action on Nrf2, and is the first drug demonstrated to increase mitochondrial biogenesis with in vivo human dosing. This is the first demonstration that mitochondrial biogenesis is deficient in Multiple Sclerosis patients, which could have implications for MS pathophysiology and therapy. The observation that DMF stimulates mitochondrial biogenesis, gene expression and function suggests that it could be considered for mitochondrial disease therapy and/or therapy in muscle disease in which mitochondrial function is important.

                                                                                                                    
DMF for Friedreich's ataxia

Friedreich's ataxia (FA) is a genetic disease caused by mutations in the FXN gene on the chromosome 9, which produces a protein called frataxin. It causes difficulty walking, a loss of sensation in the arms and legs and impaired speech that worsens over time. Symptoms typically start between 5 and 15 years of age. Most young people diagnosed with FA require a mobility aid such as a wheelchair by their teens. As the disease progresses, people lose their sight and hearing. Other complications include scoliosis and diabetes.

Frataxin is required for the normal functioning of mitochondria, the energy-producing factories of cells. Mutations in the FXN gene lead to a decrease in the production of frataxin and the consequent disruption in mitochondrial function.
No effective treatment exists. FA shortens life expectancy due to heart disease, but some people can live into their sixties.


Friedreich’s Ataxia (FA) is an inherited neurodegenerative disorder resulting from decreased expression of the mitochondrial protein frataxin, for which there is no approved therapy. High throughput screening of clinically used drugs identified Dimethyl fumarate (DMF) as protective in FA patient cells. Here we demonstrate that DMF significantly increases frataxin gene (FXN) expression in FA cell model, FA mouse model and in DMF treated humans. DMF also rescues mitochondrial biogenesis deficiency in FA-patient derived cell model. We further examined the mechanism of DMF's frataxin induction in FA patient cells. It has been shown that transcription-inhibitory R-loops form at GAA expansion mutations, thus decreasing FXN expression. In FA patient cells, we demonstrate that DMF significantly increases transcription initiation. As a potential consequence, we observe significant reduction in both R-loop formation and transcriptional pausing thereby significantly increasing FXN expression. Lastly, DMF dosed Multiple Sclerosis (MS) patients showed significant increase in FXN expression by ~85%. Since inherited deficiency in FXN is the primary cause of FA, and DMF is demonstrated to increase FXN expression in humans, DMF could be considered for Friedreich's therapy.


High Dose DMF to treat some cancer

Some readers may recall that the protein DJ-1 is encoded by the Parkinson’s gene PARK7 and that DMF has already been proposed as a therapy for Parkinson’s disease. 

At high doses of DMF the protein DJ-1 loses its stabilization function and ends up effectively blocking NRF2. Put simply, high dose DMF turns off NRF2, making it a cancer cell killer.

Dimethyl Fumarate Controls the NRF2/DJ-1Axis in Cancer Cells: Therapeutic Applications

The transcription factor NRF2 (NFE2L2), regulates important antioxidant and cytoprotective genes. It enhances cancer cell proliferation and promotes chemoresistance in several cancers. Dimethyl fumarate (DMF) is known to promote NRF2 activity in noncancer models. We combined in vitro and in vivo methods to examine the effect of DMF on cancer cell death and the activation of the NRF2 antioxidant pathway. We demonstrated that at lower concentrations (<25 a="" activation="" antioxidant="" cytoprotective="" dmf="" has="" mol="" nrf2="" of="" pathway.="" role="" span="" the="" through=""> At higher concentrations, however (>25 μmol/L), DMF caused oxidative stress and subsequently cytotoxicity in several cancer cell lines. High DMF concentration decreases nuclear translocation of NRF2 and production of its downstream targets. The pro-oxidative and cytotoxic effects of high concentration of DMF were abrogated by overexpression of NRF2 in OVCAR3 cells, suggesting that DMF cytotoxicity is dependent of NRF2 depletion. High concentrations of DMF decreased the expression of DJ-1, a NRF2 protein stabilizer. Using DJ-1 siRNA and expression vector, we observed that the expression level of DJ-1 controls NRF2 activation, antioxidant defenses, and cell death in OVCAR3 cells. Finally, antitumoral effect of daily DMF (20 mg/kg) was also observed in vivo in two mice models of colon cancer. Taken together, these findings implicate the effect of DJ-1 on NRF2 in cancer development and identify DMF as a dose-dependent modulator of both NRF2 and DJ-1, which may be useful in exploiting the therapeutic potential of these endogenous antioxidants.







Proposed mechanism of DMF-induced cancer cell death. Low concentrations of DMF can induce the NRF2 antioxidant pathway, allowing NRF2 nuclear translocation and binding to the antioxidant response elements leading to the transcription of antioxidant and detoxifying enzymes, thereby promoting cell survival. High concentrations of DMF, however, induce disruption of the NRF2 stabilizer DJ-1, which in turn impairs NRF2 induction and transcriptional activities in response to DMF, induces ROS generation, GSH depletion, and hence, facilitates cancer cell death. Cys, cysteine; 2SC, succination of cysteine residues.


Conclusion

This post did not cost $20 million, it is yours for free.

It looks pretty obvious that people with autism caused by, or associated with, mitochondrial dysfunction might potentially benefit from DMF.

People with Friedreich’s Ataxia do not currently have any treatment options. Low dose DMF is free of side effects, the high doses used to treat Psoriasis and Multiple Sclerosis often cause troubling GI side effects.

DMF seems to have very many potential therapeutic applications, limited only by the cost of the pharmaceutical version of this cheap chemical. Fortunately the "autism dose" is tiny.


Related Earlier Posts







Wednesday, 9 October 2019

Treating Autism – The State of Play


Image © Acabashi; Creative Commons CC-BY-SA 4.0 Source: Wikimedia Commons


I have learnt a great deal since I started to research autism treatment in 2012 and publish my notes in this blog from 2013. Prior to 2012 I had assumed that autism was not medically treatable and that there was no evidence to the contrary, so anyone claiming to treat autism must be a quack.  You are supposed to "trust your doctor" and I come from a family full of them.  It turns out that almost all treatments for conditions of the brain, ranging from depression to Multiple Sclerosis to dementia are only very partially effective, but in most cases they are better than nothing. Apply these expectations to treating autism and then read the medical research and clinical trials; you will see that autism is indeed as treatable.  

It turns out that many people have found effective medical therapies for their autism. But autism is not viewed as a public health emergency, like HIV or Ebola and no public health authority shows much interest. Don't expect that to change.

The leaves are beginning to fall and we are on our way to 2020, much time has passed but has the wider world caught on and moved at all?  Not really.

  • Enthusiastic autism pharma start-ups come and go, losing hundreds of millions of dollars
  • Autism therapies are fast-tracked by the FDA, then go nowhere fast
  • Autism treatment case histories, using existing drugs, get published but are ignored
  • Partially successful autism clinical trials of existing drugs keep getting published and are then ignored 
  • Some very bright clinicians do not publish their successful work in treating autism
  • Clinicians successfully treating their own children with autism often choose to remain silent
  • A tiny number of mainstream medical doctors do treat autism, but some cleverly call it something less controversial, like encephalopathy
  • Many of the “doctors” who do treat autism are not doctors of medicine (i.e. an MD).  This is the case in North America where the "doctor" can be a DO (Osteopathy) or a DC (Chiropractic), for example Dr Nemenchek is a DO.  I think this is partly where the crank issue has arisen from; many MDs do not seem to like DOs and DCs, particularly if they write books with the word miracle on the front cover.   
  • Treating idiopathic autism is still viewed as a dangerous/crank activity by mainstream medicine; the  best view is fringe and the worst is cringe.
  • Treating single gene autism is now viewed quite favorably, it is somehow more acceptable that treating equally severe idiopathic autism.  It attracts at least some MDs, rather than DOs and DCs.  It is seen as something clever, like treating cancer.
  • By shifting autism to a more trivial condition, by diagnosing so many people, it appears to not even need treating
  • Many things do look very odd in the world of autism. People with a sibling or child with Autism/MR/ID can react very differently, some are inspired to help others and some even look to develop medical treatments, while others either never tried, failed or gave up and are now against medical treatment (in the UK Psychologist Simon Barons Cohen and author/GP Dr Fitzpatrick, for example). The idea seems to be that because they could not help their family member, you should not try.  Very defeatist. People should declare their inherent bias and indeed their own psychiatric diagnosis, if they have one, that would rule out 90% of what is written about autism, much of which is nonsense. In the wider world, you learn from your failures, strive for success and never give up.  That is how progress is made.  Those who have failed, or given up, should move aside and give space to the next generation who will achieve more.  If it is a disease or disability, you treat it; you do not just hide it by broadening the diagnosis to include trivial cases and then "celebrate" it as just a difference.

Hopefully, Neurochlore and Servier will get Bumetanide approved for autism in Europe in the next few years.

Hopefully, doctors will actually prescribe it to European toddlers through to adults with autism.

Only then will mainstream doctors stop saying you cannot treat core autism with a pill. In reality there is evidence that dozens of pills are potentially beneficial, but there is no sure-fire way to predict which will be helpful in one specific person. 

It has been clear for years, to anyone who chooses to actually read the medical research, that many cheap existing pills can be repurposed for various sub-types of autism.  In almost all cases, polytherapy will be needed and treatment leads to improvement rather than cure. This is also the case with MS, epilepsy, depression etc.

I hope that by 2030 at least monotherapy for core autism with MR/ID will be in the mainstream.  In the meantime a small number of people, with otherwise severe autism, will continue to benefit from their science-based personalized medical treatment.