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Showing posts with label IP3R. Show all posts
Showing posts with label IP3R. Show all posts

Friday 21 April 2017

The Excitatory/Inhibitory Imbalance – GABAA stabilization via IP3R


This blog aims to synthesize the relevant parts of the research and make connections that point towards some potential therapeutic avenues.  Most researchers work in splendid isolation and concentrate on one extremely narrow area of interest.

The GABAA reset, not functional in some autism

On the one hand things are very simple, if the GABAA receptors function correctly and are inhibitory and the glutamate receptors (particularly NMDA and mGluRx) function correctly, there is harmony and a  perfect excitatory/inhibitory balance.

Unfortunately numerous different things can go wrong and you could write a book about each one.

As you dig deeper you see that the sub-unit make-up of GABAA receptors is not only critical but changes.  The plus side is that you can influence this.

Today we see that the receptors themselves are physically movable and sometimes get stuck in the “wrong place”. When the receptors cluster close together they produce a strong inhibitory effect, but continual activation of NMDA receptors by the neurotransmitter glutamate - as occurs naturally during learning and memory, or in epilepsy - leads to an excess of incoming calcium, which ultimately causes the receptors to become more spread out, reducing how much the neuron can be inhibited by GABA. There needs to be a mechanism to move the GABAA receptors back into their original clusters.

Very clever Japanese researchers have figured out the mechanism and to my surprise it involves one of those hubs, where strange things in autism seem to connect to, this time IP3R.





I guess the Japanese answer to my question above is simple. YES,


A very recent science-light article by Gargus on IP3:-






Now to the Japanese.






I wonder if Gargus has read the Japanese research, because both the cause and cure for the GABAA receptors dispersing and clustering is an increase in calcium and both mediated by glutamate.  

The excitatory neurotransmitter glutamate binds to the mGluR receptor and activates IP3 receptor-dependent calcium release and protein kinase C to promote clustering of GABAA receptors at the postsynaptic membrane - the place on a neuron that receives incoming neurotransmitters from connecting neurons.

If Professor Gargus is correct, and IPR3 does not work properly in autism, the GABAA receptors are likely not sitting there in nice neat clusters. As a result their inhibitory effect is reduced and neurons fire when they should not.

Gargus has found that in the types of autism he has investigated IP3 receptor open as they should, but close too fast and so do not release enough calcium from the cell’s internal calcium store (the endoplasmic reticulum).

In particular the Japanese researchers found that:-

“Stabilization of GABA synapses by mGluR-dependent Ca2+ release from IP3R via PKC”
If the IP3 receptor does not stay open as long as it should, not enough Ca2+ will be released and GABA synapses will not be stabilized. Then GABAA receptors will be diffused rather than being in neat clusters.

The science-light version of the Japanese study:-




Just as a thermostat is used to maintain a balanced temperature in a home, different biological processes maintain the balance of almost everything in our bodies, from temperature and oxygen to hormone and blood sugar levels. In our brains, maintaining the balance -- or homeostasis -- between excitation and inhibition within neural circuits is important throughout our lives, and now, researchers at the RIKEN Brain Science Institute and Nagoya University in Japan, and École Normale Supérieure in France have discovered how disturbed inhibitory connections are restored. Published in Cell Reports, the work shows how inhibitory synapses are stabilized when the neurotransmitter glutamate triggers stored calcium to be released from the endoplasmic reticulum in neurons.

"Imbalances in excitation and inhibition in the brain has been linked to several disorders," explains lead author Hiroko Bannai. "In particular, forms of epilepsy and even autism appear to be related to dysfunction in inhibitory connections."

One of the key molecules that regulates excitation/inhibition balance in the brain is the inhibitory neurotransmitter GABA. When GABA binds to GABAA receptors on the outside of a neuron, it prevents that neuron from sending signals to other neurons. The strength of the inhibition can change depending on how these receptors are spaced in the neuron's membrane.

While GABAA receptors are normally clustered together, continual neural activation of NMDA receptors by the neurotransmitter glutamate -- as occurs naturally during learning and memory, or in epilepsy -- leads to an excess of incoming calcium, which ultimately causes the receptors to become more spread out, reducing how much the neuron can be inhibited by GABA.

To combat this effect, the receptors are somehow continually re-clustered, which maintains the proper excitatory/inhibitory balance in the brain. To understand how this is accomplished, the team focused on another signaling pathway that also begins with glutamate, and is known to be important for brain development and the control of neuronal growth.

In this pathway glutamate binds to the mGluR receptor and leads to the release of calcium from internal storage into the neuron's internal environment. Using quantum dot-single particle tracking, the team was able to show that after release, this calcium interacts with protein kinase C to promote clustering of GABAA receptors at the postsynaptic membrane--the place on a neuron that receives incoming neurotransmitters from connecting neurons.

These findings show that glutamate activates distinct receptors and patterns of calcium signaling for opposing control of inhibitory GABA synapses.

Notes Bannai, "it was surprising that the same neurotransmitter that triggers GABAA receptor dispersion from the synapse, also plays a completely opposite role in stabilizing GABAA receptors, and that the processes use different calcium signaling pathways. This shows how complex our bodies are, achieving multiple functions by maximizing a limited number of biological molecules.

Pre-activation of the cluster-forming pathway completely prevented the dispersion of GABAA receptors that normally results from massive excitatory input, as occurs in status epilepticus -- a condition in which epileptic seizures follow one another without recover of consciousness. Bannai explains, "further study of the molecular mechanisms underlying the process we have uncovered could help develop treatments or preventative medication for pathological excitation-inhibition imbalances in the brain.

"The next step in understanding how balance is maintained in the brain is to investigate what controls which pathway is activated by glutamate. Most types of cells use calcium signals to achieve biological functions. On a more basic level, we believe that decoding these signals will help us understand a fundamental biological question: why and how are calcium signals involved in such a variety of biological phenomena?"


The full Japanese study:-





·        Bidirectional synaptic control system by glutamate and Ca2+ signaling

·        Stabilization of GABA synapses by mGluR-dependent Ca2+ release from IP3R via PKC

·        Synaptic GABAAR clusters stabilized through regulation of GABAAR lateral diffusion

·        Competition with an NMDAR-dependent Ca2+ pathway driving synaptic destabilization

GABAergic synaptic transmission regulates brain function by establishing the appropriate excitation-inhibition (E/I) balance in neural circuits. The structure and function of GABAergic synapses are sensitive to destabilization by impinging neurotransmitters. However, signaling mechanisms that promote the restorative homeostatic stabilization of GABAergic synapses remain unknown. Here, by quantum dot single-particle tracking, we characterize a signaling pathway that promotes the stability of GABAA receptor (GABAAR) postsynaptic organization. Slow metabotropic glutamate receptor signaling activates IP3 receptor-dependent calcium release and protein kinase C to promote GABAAR clustering and GABAergic transmission. This GABAAR stabilization pathway counteracts the rapid cluster dispersion caused by glutamate-driven NMDA receptor-dependent calcium influx and calcineurin dephosphorylation, including in conditions of pathological glutamate toxicity. These findings show that glutamate activates distinct receptors and spatiotemporal patterns of calcium signaling for opposing control of GABAergic synapses.



In this study, we demonstrate that the mGluR/IICR/PKC pathway stabilizes GABAergic synapses by constraining lateral diffusion and increasing clustering of GABAARs, without affecting the total number of GABAAR on the cell surface. This pathway defines a unique form of homeostatic regulation of GABAergic transmission under conditions of basal synaptic activity and during recovery from E/I imbalances. The study also highlights the ability of neurons to convert a single neurotransmitter (glutamate) into an asymmetric control system for synaptic efficacy using different calcium-signaling pathways.

The most striking conceptual finding in this study is that two distinct intracellular signaling pathways, NMDAR-driven Ca2+ influx and mGluR-driven Ca2+ release from the ER, effectively driven by the same neurotransmitter, glutamate, have an opposing impact on the stability and function of GABAergic synapses. Sustained Ca2+ influx through ionotropic glutamate receptor-dependent calcium signaling increases GABAAR lateral diffusion, thereby causing the dispersal of synaptic GABAAR, while tonic mGluR-mediated IICR restrains the diffusion of GABAAR, thus increasing its synaptic density. How can Ca2+ influx and IICR exert opposing effects on GABA synaptic structure? Our research indicates that each Ca2+ source activates a different Ca2+-dependent phosphatase/kinase: NMDAR-dependent Ca2+ influx activates calcineurin, while ER Ca2+ release activates PKC.


Taken together, these results lead us to propose the following model for bidirectional competitive regulation of GABAergic synapses by glutamate signaling. Phasic Ca2+ influx through NMDARs following sustained neuronal excitation or injury leads to the activation of calcineurin, overcoming PKC activity and relieving GABAAR diffusion constraints. In contrast, during the maintenance of GABAergic synaptic structures or the recovery from GABAAR dispersal, the ambient tonic mGluR/IICR pathway constrains GABAAR diffusion by PKC activity, overcoming basal calcineurin activity. One possible mechanism of dual regulation of GABAAR by Ca2+ is that each Ca2+-dependent enzyme has a unique sensitivity to the frequency and number of external glutamate release events and can act to decode neuronal inputs (Fujii et al., 2013xNonlinear decoding and asymmetric representation of neuronal input information by CaMKIIα and calcineurin. Fujii, H., Inoue, M., Okuno, H., Sano, Y., Takemoto-Kimura, S., Kitamura, K., Kano, M., and Bito, H. Cell Rep. 2013; 3: 978–987

Abstract | Full Text | Full Text PDF | PubMed | Scopus (24)See all References, Li et al., 2012xCalcium input frequency, duration and amplitude differentially modulate the relative activation of calcineurin and CaMKII. Li, L., Stefan, M.I., and Le Novère, N. PLoS ONE. 2012; 7: e43810

Crossref | PubMed | Scopus (29)See all References, Stefan et al., 2008xAn allosteric model of calmodulin explains differential activation of PP2B and CaMKII. Stefan, M.I., Edelstein, S.J., and Le Novère, N. Proc. Natl. Acad. Sci. USA. 2008; 105: 10768–10773

Crossref | PubMed | Scopus (44)See all References) in inhibitory synapses.

Tight control of E/I balance, the loss of which results in epilepsy and other brain and nervous system diseases/disorders, is dependent on GABAergic synaptic transmission (Mann and Paulsen, 2007xRole of GABAergic inhibition in hippocampal network oscillations. Mann, E.O. and Paulsen, O. Trends Neurosci. 2007; 30: 343–349

Abstract | Full Text | Full Text PDF | PubMed | Scopus (194)See all ReferencesMann and Paulsen, 2007). A recent study showed that the excitation-induced acceleration of GABAAR diffusion and subsequent dispersal of GABAARs from synapses is the cause of generalized epilepsy febrile seizure plus (GEFS+) syndrome (Bouthour et al., 2012xA human mutation in Gabrg2 associated with generalized epilepsy alters the membrane dynamics of GABAA receptors. Bouthour, W., Leroy, F., Emmanuelli, C., Carnaud, M., Dahan, M., Poncer, J.C., and Lévi, S. Cereb. Cortex. 2012; 22: 1542–1553

Crossref | PubMed | Scopus (14)See all ReferencesBouthour et al., 2012). Our results indicate that pre-activation of the mGluR/IICR pathway by DHPG could completely prevent the dispersion of synaptic GABAARs induced by massive excitatory input similar to status epilepticus. Thus, further study of the molecular mechanisms underlying the mGluR/IICR-dependent stabilization of GABAergic synapses via regulation of GABAAR lateral diffusion and synaptic transmission could be helpful in the prevention or treatment of pathological E/I imbalances, for example, in the recovery of GABAergic synapses from epileptic states


DHPG = group I mGluR agonist dihydroxyphenylglycine.

On a practical level you want to inhibit GABAA  dispersion and promote GABAA stabilization. How you might do this would depend on exactly what was the underlying problem.

If the problem is IP3R not releasing enough calcium, you might activate PKC in a different way or just increase the signal from Group 1 mGluR. If the problem is too much calcium influx through NMDA receptors due to excess glutamate, you could increase the re-uptake of glutamate, via GLT-1, using Riluzole.  You could block the flow of Ca2+ through NMDA receptors using an antagonist.

The Japanese used dihydroxyphenylglycine (DHPG) as their Group 1 mGluR agonist.  DHPG is an agonist of mGluR1 and mGluR5.  We have come across mGluR5 many times before in this blog.  Mavoglurant is an experimental drug candidate for the treatment of fragile X syndrome.  It is an antagonist of mGluR5.

We have seen many times before that there is both hypo and hyper function possible and indeed that fragile X is not necessarily a good model for autism.

The selective mGluR5 agonist CHPG protects against traumatic brain injury, which would indeed make sense. Although, that research suggests an entirely different mechanism.



The calcium released by IP3 works in complex way together with DAG (diacylglycerol ) to activate PKC (protein kinase C).





Ideally you would have enough calcium released from IP3, but you could also increase DAG. It depends which part of the process is rate-limiting.

Diacylglycerol (DAG) has been investigated extensively as a fat substitute due to its ability to suppress the accumulation of body fat.  Diglycerides, generally in a mix with monoglycerides are common food additives largely used as emulsifiers. In Europe, when used in food the mix is called E471.


Conclusion

On the one hand things are getting very complicated, but on the other we keep coming back to the same variables (IP3R, mGlur5, GABAA etc.).

It is pretty clear that some very personalized therapy will be needed.  Is it an mGlur5 agonist or antagonist? Or quite possibly neither, because in different parts of the brain it will have a good/bad effect.

It does look like Riluzole should work well in some people.

A safe IP3R agonist looks a possibility. As shown in the diagram earlier in this post,IP3 is usually made in situ, but agonists exist.

In effect autism could be the opposite of Huntington’s disease. In Huntington’s,  type 1 IP3 receptors are  more sensitive to IP3, which leads to the release of too much Ca2+ from the ER. The release of Ca2+ from the ER causes an increase in concentrations of Ca2+inside cells and in mitochondria.

According to Gargus we should have reduced concentrations of Ca2+inside cells in autism.

I suspect it is much more complicated in reality, because it is not just the absolute  level of Ca2+ but rather the flow of Ca2+; so it matters where it is coming from. I think we likely have impaired calcium channel activity of multiple types in autism and the actual level of intracellular calcium will not tell you much at all.

As the Japanese commented, it is surprising that glutamate is the neurotransmitter that controls the clustering, or not, of GABAA receptors.  This suggests that you cannot ignore glutamate and just “fix” GABA.





Friday 2 October 2015

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





Place de l'Étoile in Paris and the avenues radiating from it.  The Arc de Triomphe in the centre would be the IP3 receptor



There are a small number of researchers in the field of autism who really do seem to know what they are talking about;  one of those is Jay Gargus, from University of California at Irvine.  He is one of the few well versed on ion channel dysfunctions (channelopathies).  Today we look at his recent paper relating to the IP3R calcium channel in something called the endoplasmic reticulum (ER).

Gargus’ recent findings relate to calcium signaling, which we have seen previously in this blog to be dysfunctional in autism.  Blocking one type of calcium channel, with Verapamil, has had a remarkable effect in the children of some of those reading this blog; this has included resolving aggressive behavior, resolving GI problems and, most recently, greatly reducing seizures.  An interesting side effect of this drug is that it protects older people from Type 2 diabetes.

We will also encounter yet another kind of stress, ER stress (endoplasmic reticulum stress), which plays a role in many disorders including Type 2 diabetes and is suggested by some Japanese researchers to play a role in autism.  Interestingly some of my pet autism interventions are known to affect ER stress.

As usual in this blog, I will skip some of the complexities, but we do need to know some new words.  The explanation is mainly courtesy of the remarkable Wikipedia.


Organelle

In cell biology, an organelle is a specialized subunit within a cell that has a specific function.  Individual organelles are usually separately enclosed within their own lipid bilayers.  These lipid bilayers are also extremely important and need to be perfectly intact.  It does appear that these lipid bilayers are a little different in autism.











Components of a typical animal cell:

  1.     Nucleolus
  2.     Nucleus
  3.     Ribosome (little dots)
  4.    Vesicle
  5.    Rough endoplasmic reticulum
  6.    Golgi apparatus (or "Golgi body")
  7.    Cytoskeleton
  8.   Smooth endoplasmic reticulum
  9.   Mitochondrion
  10.   Vacuole
  11.   Cytosol (fluid that contains organelles)
  12.    Lysosome
  13.    Centrosome
  14.    Cell membrane



Endoplasmic Reticulum (ER) and ER Stress

The endoplasmic reticulum (ER) is the cellular organelle in which protein folding, calcium homeostasis, and lipid biosynthesis occur. Stimuli such as oxidative stress, ischemic insult, disturbances in calcium homeostasis, and enhanced expression of normal and/or folding-defective proteins lead to the accumulation of unfolded proteins, a condition referred to as ER stress.


Inositol trisphosphate receptor (InsP3R) or IP3R

IP3R is a Ca2+ channel activated by inositol trisphosphate (InsP3). InsP3R is very diverse among organisms, and is necessary for the control of cellular and physiological processes including cell division, cell proliferation, apoptosis, fertilization, development, behavior, learning and memory. Inositol triphosphate receptor represents a dominant second messenger leading to the release of Ca2+ from intracellular store sites.

It has a broad tissue distribution but is especially abundant in the cerebellum. Most of the InsP3Rs are found in the cell integrated into the endoplasmic reticulum.


Genes and autism

It is a widely held view that autism is essentially a genetic condition with some environmental triggers.

What is strange is that many hundreds, and later I suspect thousands, of genes are known to be implicated.  Do these lead to thousands of unique dysfunctions that ultimately manifest themselves as what we, rather clumsily, describe as “autism”?  This appears to be unlikely, more likely is that a much smaller number of downstream dysfunctions are involved.  This is behind what is suggested later by Gargus.

What I have always found odd is that siblings with idiopathic autism do NOT generally share the same genetic variations.  Most autism is called idiopathic, which means of unknown cause.  This is why I have not done any genetic testing on my son.

If siblings have Fragile X, then of course they do have the same genetic defect; the brother will likely be much more severely affected than the sister.

It occurs to me that unless the idiopathic autistic siblings live under some high voltage power cables, next to a TV transmitter or a chemical factory, the genetic testing must be missing something.  We have seen that sequencing the exome, the current “ultimate genetic test”, in fact only looks at 5% of genome.  We have also seen that in the remaining 95% are the so called enhancers and silencers of the genes in the exome.  We have also seen that overexpression of a perfect gene (as in Down syndrome) can do as much damage as a faulty gene.

My advice is to look in the remaining 95% of the genome.



Gargus, IP3R and Autism

Having completed the introduction now we can move on to the Gargus paper.

He is suggesting that a dysfunction at a specific calcium channel in the ER may be the common dysfunction triggered by “autism genes”.

So far he has only tested his idea on some single gene autisms, fragile X and tuberous sclerosis.
 





Autism spectrum disorder (ASD) affects 2% of children, and is characterized by impaired social and communication skills together with repetitive, stereotypic behavior. The pathophysiology of ASD is complex due to genetic and environmental heterogeneity, complicating the development of therapies and making diagnosis challenging. Growing genetic evidence supports a role of disrupted Ca2+ signaling in ASD. Here, we report that patient-derived fibroblasts from three monogenic models of ASD—fragile X and tuberous sclerosis TSC1 and TSC2 syndromes—display depressed Ca2+ release through inositol trisphosphate receptors (IP3Rs). This was apparent in Ca2+ signals evoked by G protein-coupled receptors and by photoreleased IP3 at the levels of both global and local elementary Ca2+ events, suggesting fundamental defects in IP3R channel activity in ASD. Given the ubiquitous involvement of IP3R-mediated Ca2+ signaling in neuronal excitability, synaptic plasticity, gene expression and neurodevelopment, we propose dysregulated IP3R signaling as a nexus where genes altered in ASD converge to exert their deleterious effect. These findings highlight potential pharmaceutical targets, and identify Ca2+ screening in skin fibroblasts as a promising technique for early detection of individuals susceptible to ASD.


This part I found interesting:-

Because of the ubiquitous nature of IP3R signaling and its diverse roles in almost all cells of the body, deficits in IP3-mediated Ca2+ signaling may not be limited to neurological correlates of ASD, but may also explain other characteristic ASD-associated heterogeneous symptoms, such as those of the gastrointestinal tract and immune system.  Furthermore, since the ER serves as a sensor of a host of environmental stressors, this same mechanism may contribute to the known environmental component
to the ASD phenotype, and holds the potential to reveal relevant stressors.

Is it a coincidence that the Verapamil therapy I propose also benefits autism symptoms linked to the gastrointestinal tract and immune system (mast cells/allergy) and also now seizures (hyper excitability)?  I think not,



Here is the rather easier to read press release from the University:-

UCI researchers find biomarker for autism that may aid diagnostics




Irvine, Calif., Sept. 22, 2015 — By identifying a key signaling defect within a specific membrane structure in all cells, University of California, Irvine researchers believe, they have found both a possible reliable biomarker for diagnosing certain forms of autism and a potential therapeutic target.

Dr. J. Jay Gargus, Ian Parker and colleagues at the UCI Center for Autism Research & Translation examined skin biopsies of patients with three very different genetic types of the disorder (fragile X syndrome and tuberous sclerosis 1 and 2). They discovered that a cellular calcium signaling process involving the inositol trisphosphate receptor was very much altered.

This IP3R functional defect was located in the endoplasmic reticulum, which is among the specialized membrane compartments in cells called organelles, and may underpin cognitive impairments – and possibly digestive and immune problems – associated with autism.

“We believe this finding will be another arrow in the quiver for early and accurate diagnoses of autism spectrum disorders,” said Gargus, director of the Center for Autism Research & Translation and professor of pediatrics and physiology & biophysics. “Equally exciting, it also presents a target of a molecular class already well-established to be useful for drug discovery.”

Study results appear online in Translational Psychiatry, a Nature publication.

Autism spectrum disorder is a range of complex neurodevelopmental disorders affecting 2 percent of U.S. children. The social and economic burden of ASD is enormous, currently estimated at more than $66 billion per year in the U.S. alone. Drug development has proven problematic due to the limited understanding of the underlying causes of ASD, as demonstrated by the recent failure of several much anticipated drug trials.

There are also no current, reliable diagnostic biomarkers for ASD. Genetic research has identified hundreds of genes that are involved, which impedes diagnosis and, ultimately, drug development. There simply may be too many targets, each with too small an effect.

Many of these genes associated with ASD, however, have been found to be part of the same signaling pathway, and multiple defects in this pathway may converge to produce a large functional change.

The UCI scientists detected such a convergence in the IP3R calcium channel in an organelle called the endoplasmic reticulum. Organelles are membrane structures within cells with specialized cellular functions. According to Gargus, diseases of the organelles, such as the ER, are an emerging field in medicine, with several well-recognized neurological ailments linked to two other ones, the mitochondria and lysosomes.

The IP3R controls the release of calcium from the ER. In the brain, calcium is used to communicate information within and between neurons, and it activates a host of other cell functions, including ones regulating learning and memory, neuronal excitability and neurotransmitter release – areas known to be dysfunctional in ASD.
“We propose that the proper function of this channel and its signaling pathway is critical for normal performance of neurons and that this signaling pathway represents a key ‘hub’ in the pathogenesis of ASD,” said Parker, a fellow of London’s Royal Society and UCI professor of neurobiology & behavior, who studies cellular calcium signaling.

To see if IP3R function is altered across the autism spectrum, clinical researchers at The Center for Autism & Neurodevelopmental Disorders – which is affiliated with the Center for Autism Research & Translation – are currently expanding the study and have begun to examine children with and without typical ASD for the same signaling abnormalities. These patients undergo complete behavioral diagnostic testing, and sophisticated EEG, sleep and biochemical studies are performed. This includes the sequencing of their entire genome. Also, skin cell samples are cultured and made available to lab-based researchers for functional assays.

In the area of drug discovery, scientists at the Center for Autism Research & Translation continue to probe the IP3R channel, specifically how it regulates the level of neuron excitability. The brains of people who have autism show signs of hyperexcitability, which is also seen in epilepsy, a disorder increasingly found to be associated with ASD. Cells from individuals who have autism exhibit depressed levels of calcium signaling, and this might explain why these patients experience this hyperexcitability. By restoring the release of calcium from the IP3R, the researchers believe, they can apply a “brake” on this activity.




ER Stress

As we saw above, the endoplasmic reticulum (ER) is the cellular organelle in which protein folding, calcium homeostasis, and lipid biosynthesis occur. Stimuli such as oxidative stress, ischemic insult, disturbances in calcium homeostasis, and enhanced expression of normal and/or folding-defective proteins lead to the accumulation of unfolded proteins, a condition referred to as ER stress.
We know that we usually have oxidative stress in autism and we know that calsium homeostasis is disturbed, so it is not surprising if we found ER stress in autism.

The following paper is not open access but it does suggest that ER stress leads to impaired synaptic function and specifically GABAB dysfunction.  If you respond well to Baclofen, you likely have a GABAB dysfunction.  Based on anecdotal evidence I would suggest that people with Asperger’s and anxiety might well have ER stress, since they are the ones that respond well to baclofen.




The molecular pathogenesis of ASD (autism spectrum disorder), one of the heritable neurodevelopmental disorders, is not well understood, although over 15 autistic-susceptible gene loci have been extensively studied. A major issue is whether the proteins that these candidate genes encode are involved in general function and signal transduction. Several mutations in genes encoding synaptic adhesion molecules such as neuroligin, neurexin, CNTNAP (contactin-associated protein) and CADM1 (cell-adhesion molecule 1) found in ASD suggest that impaired synaptic function is the underlying pathogenesis. However, knockout mouse models of these mutations do not show all of the autism-related symptoms, suggesting that gain-of-function in addition to loss-of-function arising from these mutations may be associated with ASD pathogenesis. Another finding is that family members with a given mutation frequently do not manifest autistic symptoms, which possibly may be because of gender effects, dominance theory and environmental factors, including hormones and stress. Thus epigenetic factors complicate our understanding of the relationship between these mutated genes and ASD pathogenesis. We focus in the present review on findings that ER (endoplasmic reticulum) stress arising from these mutations causes a trafficking disorder of synaptic receptors, such as GABA (γ-aminobutyric acid) B-receptors, and leads to their impaired synaptic function and signal transduction. In the present review we propose a hypothesis that ASD pathogenesis is linked not only to loss-of-function but also to gain-of-function, with an ER stress response to unfolded proteins under the influence of epigenetic factors.



I was surprised how much is known about ER stress, there is even a scientific journal devoted to it.

As is often the case, the literature is again full papers like the one below suggesting something, ER stress in this case, is a good drug target, but then do not suggest any drugs.





Abstract
Cardiovascular disease constitutes a major and increasing health burden in developed countries. Although treatments have progressed, the development of novel treatments for patients with cardiovascular diseases remains a major research goal. The endoplasmic reticulum (ER) is the cellular organelle in which protein folding, calcium homeostasis, and lipid biosynthesis occur. Stimuli such as oxidative stress, ischemic insult, disturbances in calcium homeostasis, and enhanced expression of normal and/or folding-defective proteins lead to the accumulation of unfolded proteins, a condition referred to as ER stress. ER stress triggers the unfolded protein response (UPR) to maintain ER homeostasis. The UPR involves a group of signal transduction pathways that ameliorate the accumulation of unfolded protein by increasing ER-resident chaperones, inhibiting protein translation and accelerating the degradation of unfolded proteins. The UPR is initially an adaptive response but, if unresolved, can lead to apoptotic cell death. Thus, the ER is now recognized as an important organelle in deciding cell life and death. There is compelling evidence that the adaptive and proapoptotic pathways of UPR play fundamental roles in the development and progression of cardiovascular diseases, including heart failure, ischemic heart diseases, and atherosclerosis. Thus, therapeutic interventions that target molecules of the UPR component and reduce ER stress will be promising strategies to treat cardiovascular diseases. In this review, we summarize the recent progress in understanding UPR signaling in cardiovascular disease and its related therapeutic potential. Future studies may clarify the most promising molecules to be investigated as targets for cardiovascular diseases.


However all is not lost, a little digging uncovers several existing substances that affect ER Stress.

Atorvastatin, long part of my autism Polypill, is quite prominent.  Atorvastatin is lipophilic statin, which means it can better cross the blood brain barrier.  By chance it is the statin with the least side effects.




Statins inhibit HMG-CoA reductase, target mevalonic acid synthesis, and limit cholesterol biosynthesis. HMG-CoA reductase is expressed in the membrane of the endoplasmic reticulum (ER). Statins are prescribed to prevent cardiovascular events.
In cultured neonatal mouse cardiac myocytes the lipophilic statin atorvastatin and the hydrophilic statin pravastatin both up-regulated PDI, indicating unfolded protein response (UPR) meant to relieve ER stress. Only atorvastatin increased ER stress, growth arrest, and induced apoptosis via induction of CHOP, Puma, active Caspase-3 and PARP. Dose-dependent release of LDH was only observed in atorvastatin treated cells (1–10 μM). Hearts of mice treated with atorvastatin (5mg/kg/day for 7 months) showed protein aggresomes and autophagosomes when compared to vehicle treated controls. While atorvastatin changed mitochondrial ultrastructure, no differences in cardiac function, exercise ability or creatine kinase levels were found.
We show differential activation of ER stress by atorvastatin and pravastatin in cardiac myocytes. Our results provide a novel mechanism through which specific statins therapeutically modulate the balance of UPR/ER stress responses thereby possibly influencing cardiac remodeling.






Cerebral ischemia triggers secondary ischemia/reperfusion injury and endoplasmic reticulum stress initiates cell apoptosis. However, the regulatory mechanism of the signaling pathway remains unclear. We hypothesize that the regulatory mechanisms are mediated by the protein kinase-like endoplasmic reticulum kinase/eukaryotic initiation factor 2α in the endoplasmic reticulum stress signaling pathway. To verify this hypothesis, we occluded the middle cerebral artery in rats to establish focal cerebral ischemia/reperfusion model. Results showed that the expression levels of protein kinase-like endoplasmic reticulum kinase and caspase-3, as well as the phosphorylation of eukaryotic initiation factor 2α, were increased after ischemia/reperfusion. Administration of atorvastatin decreased the expression of protein kinase-like endoplasmic reticulum kinase, caspase-3 and phosphorylated eukaryotic initiation factor 2α, reduced the infarct volume and improved ultrastructure in the rat brain. After salubrinal, the specific inhibitor of phosphorylated eukaryotic initiation factor 2α was given into the rats intragastrically, the expression levels of caspase-3 and phosphorylated eukaryotic initiation factor 2α in the were decreased, a reduction of the infarct volume and less ultrastructural damage were observed than the untreated, ischemic brain. However, salubrinal had no impact on the expression of protein kinase-like endoplasmic reticulum kinase. Experimental findings indicate that atorvastatin inhibits endoplasmic reticulum stress and exerts neuroprotective effects. The underlying mechanisms of attenuating ischemia/reperfusion injury are associated with the protein kinase-like endoplasmic reticulum kinase/eukaryotic initiation factor 2α/caspase-3 pathway.





ABSTRACT
The nuclear receptor peroxisome proliferator-activated receptor γ (PPAR-γ) is an important target in diabetes therapy, but its direct role, if any, in the restoration of islet function has remained controversial. To identify potential molecular mechanisms of PPAR-γ in the islet, we treated diabetic or glucose-intolerant mice with the PPAR-γ agonist pioglitazone or with a control. Treated mice exhibited significantly improved glycemic control, corresponding to increased serum insulin and enhanced glucose-stimulated insulin release and Ca2+ responses from isolated islets in vitro. This improved islet function was at least partially attributed to significant upregulation of the islet genes Irs1, SERCA, Ins1/2, and Glut2 in treated animals. The restoration of the Ins1/2 and Glut2 genes corresponded to a two- to threefold increase in the euchromatin marker histone H3 dimethyl-Lys4 at their respective promoters and was coincident with increased nuclear occupancy of the islet methyltransferase Set7/9. Analysis of diabetic islets in vitro suggested that these effects resulting from the presence of the PPAR-γ agonist may be secondary to improvements in endoplasmic reticulum stress. Consistent with this possibility, incubation of thapsigargin-treated INS-1 β cells with the PPAR-γ agonist resulted in the reduction of endoplasmic reticulum stress and restoration of Pdx1 protein levels and Set7/9 nuclear occupancy. We conclude that PPAR-γ agonists exert a direct effect in diabetic islets to reduce endoplasmic reticulum stress and enhance Pdx1 levels, leading to favorable alterations of the islet gene chromatin architecture.


PPAR-γ agonist pioglitazone is known to have a positive effect in some autism, but it does have side effects.

Other PPAR-γ agonists include Ibuprofen and Tangeretin (sold as Sytrinol).

ER stress plays a key role in diabetes and some obesity.









Conclusion

So as to Gargus’ question and the tittle of this post:

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

The researchers are now looking at children with and without idiopathic autism to see if dysregulated IP3R calcium is indeed a reliable marker.

Given so many things can lead to behavior diagnosed as autism, I think they will just identify an IP3R cluster.  Hopefully it is a big one.  Then they can find a therapy to  release calcium from IP3R.

Where does ER stress fit into this picture?  Gargus briefly mentions stressors and unfolded protein responses:-

In addition to its role in Ca2+ homeostasis, the ER serves as a key integrator of environmental stressors with metabolism and gene expression, as it mediates a host of broad ranging cell stress responses such as the heat shock and unfolded protein responses

I think he is missing something here. 

The endoplasmic reticulum (ER) is the cellular organelle in which lipid biosynthesis occurs as well as protein folding and calcium homeostasis.

I suspect all three may be dysfunctional.  We have ample evidence of lipid abnormalities in autism and even lipid bilayer abnormalities. The Japanese research referred to above suggests protein folding dysfunction.  Note that what reduces ER stress (statins and tangeretin) also reduces cholesterol.

The good news is that plenty of therapeutic avenues already exist.

The other good news is that after 261 posts of this blog, so many pieces of the autism puzzle seem to be fitting together, not perfectly, but well enough to figure out how to treat multiple aspects of classic autism.

I did stumble across a recent quote by Ricardo Dolmetsch, formerly of Stanford and currently Global Head of Neuroscience at drug maker Novartis.  He also has a son with classic autism.  He was quoted again saying there are currently no drug treatments for core autism.  He knows a thousand times more about biology than me, but he is totally wrong to keep saying that there is nothing you can do beyond behavioral education and, if that fails, institutionalization.  I did write to him a while back and I do feel rather sorry for him, since it was his research on Timothy Syndrome that indirectly led to my Verapamil “discovery”.

Some people are just too clever (him, not me).