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Showing posts with label SIRT1. Show all posts
Showing posts with label SIRT1. Show all posts

Tuesday, 28 January 2020

Piperine/Resveratrol/Sunitinib for Rett’s and indeed much Autism? Or, R-Baclofen to raise KCC2 expression in Bumetanide-responsive autism.



Piperine/Pepper             Resveratrol/Red wine          Sunitinib/Sutent
  

This post is all about lowering chloride within neurons, by increasing the expression of the transporter that lets it leave, called KCC2.


Today’s post is one I never finished writing from last year; I looked up the price of Sutent/Sunitinib and then I remembered why. It does again highlight how cancer drugs, when they become cheap generics, will provide interesting options for autism treatment. It also shows again how Rett Syndrome is getting attention from researchers.

It also highlights that really clever Americans are looking for bumetanide alternatives, in the false belief that bumetanide has troubling side effects that cannot be managed/mitigated.

The study is by some clever guys in Cambridge Massachusetts.

Another group of clever guys from MIT burned through $40 million dollars a few years ago trying to develop R-Baclofen for Fragile-X and autism.  After that Roche-funded clinical trial failed, R-Baclofen has now been resurrected and a new trial is planned, with different end points (measures of success).

Today we see why many people should indeed respond positively to R-Baclofen, but the mode of action is entirely different to the one originally targeted by the clever guys from MIT.

Tucked away in the supplementary material of today’s paper we see that R-Baclofen increases the expression of the transporter (KCC2) that takes chloride out of neurons. So, R-Baclofen is doing the same thing as Bumetanide, just to a lesser extent and in a different way.  Both lower intracellular chloride.

That means that people responsive to bumetanide should get a further boost from R baclofen, but you might need a lot of it.

Clever they may be, but these researchers do not know how to communicate their findings.  I had to dig through the supplementary tables to extract the good stuff, which is a list of what substances increase KCC2 in regular brains (Table S1) and specifically in Rett Syndrome brains (Table S2).

This blog does rather bang on about blocking/inhibiting NKCC1 that lets chloride into neurons, you can of course alternatively open up KCC2 to let the chloride flood out. This latter strategy is proposed by the MIT researchers.

What really matters is the ratio KCC2/NKCC1.  In people with bumetanide-responsive autism, which pretty clearly will include girls with Rett Syndrome, you want to increase KCC2/NKCC1. So, block/down-regulate NKCC1 and/or up-regulate KCC2.

·        NKCC1

·        KCC2


The researchers identified 14 compounds.  To be useful as drugs these compounds have to be able to cross the blood brain barrier to be of much use, many do not.

In the paper they call KCC2 expression-enhancing compounds KEECs.

We have five approved drugs to add to the list that are functionally the same to primary hit compounds. 

·        Sunitinib
·        Crenolanib
·        Indirubin Monoxiome
·        Cabozantinib
·        TWS-119


The researchers went on to test just two compounds in Rett syndrome mice; they picked piperine (from black pepper) and KW 2449 (a leukemia drug)


Even R-baclofen pops up, with a “B score” of 6.65 (needs to be >3 to increase KCC2 expression).



Abstract
Rett syndrome (RTT) is a neurodevelopmental disorder caused by mutations in the methyl CpG binding protein 2 (MECP2) gene. There are currently no approved treatments for RTT. The expression of K+/Cl- cotransporter 2 (KCC2), a neuron-specific protein, has been found to be reduced in human RTT neurons and in RTT mouse models, suggesting that KCC2 might play a role in the pathophysiology of RTT. To develop neuron-based high-throughput screening (HTS) assays to identify chemical compounds that enhance the expression of the KCC2 gene, we report the generation of a robust high-throughput drug screening platform that allows for the rapid assessment of KCC2 gene expression in genome-edited human reporter neurons. From an unbiased screen of more than 900 small-molecule chemicals, we have identified a group of compounds that enhance KCC2 expression termed KCC2 expression-enhancing compounds (KEECs). The identified KEECs include U.S. Food and Drug Administration-approved drugs that are inhibitors of the fms-like tyrosine kinase 3 (FLT3) or glycogen synthase kinase 3β (GSK3β) pathways and activators of the sirtuin 1 (SIRT1) and transient receptor potential cation channel subfamily V member 1 (TRPV1) pathways. Treatment with hit compounds increased KCC2 expression in human wild-type (WT) and isogenic MECP2 mutant RTT neurons, and rescued electrophysiological and morphological abnormalities of RTT neurons. Injection of KEEC KW-2449 or piperine in Mecp2 mutant mice ameliorated disease-associated respiratory and locomotion phenotypes. The small-molecule compounds described in our study may have therapeutic effects not only in RTT but also in other neurological disorders involving dysregulation of KCC2.





Table S1. KEECs identified from screening with WT human KCC2 reporter neurons.






Table S2. KEECs identified from screening with RTT human KCC2 reporter neurons


Note Baclofen, Quercetin, Luteolin etc

















Fig. 3. Identification of KEECs that increase KCC2 expression in human RTT neurons
B score >3 indicates compounds potentially increasing KCC2 expression

In cultured RTT neurons, treatment with KEECs KW-2449 and BIO restored the impaired KCC2 expression and rescued deficits in both GABAergic and glutamatergic neurotransmissions, as well as abnormal neuronal morphology. Previous data suggested that disrupted Cl− homeostasis in the brainstem causes abnormalities in breathing pattern (64), consistent with breathing abnormalities seen in mice carrying a conditional Mecp2 deletion in GABAergic neurons (67). The reduction in locomotion activity observed in the Mecp2 mutant mice has also been attributed to abnormalities in the GABAergic system (65). Therefore, treatment with the KEEC KW-2449 or piperine may ameliorate disease phenotypes in MeCP2 mutant mice through restoration of the impaired KCC2 expression and GABAergic inhibition.

Most KEECs that enhanced KCC2 expression in WT neurons, including KW-2449, BIO, and resveratrol, also induced a robust increase of KCC2 reporter activity in RTT neurons (Fig. 3, A and B; a complete list of hit compounds is provided in table S2). The increase in KCC2 signal induced by KEECs was higher in RTT neurons than in WT neurons,


Our results establish a causal relationship between reduced FLT3 or GSK3 signaling activity and increased KCC2 expression.

Two hit compounds, resveratrol and piperine, act on different pathways than the kinase inhibitors, activating the SIRT1 signaling pathway (50) and the TRPV1 (51), respectively

Thus, our data demonstrate that activation of the SIRT1 pathway or the TRPV1 channel enhances KCC2 expression in RTT human neurons.


The group of KEECs reported here may help to elucidate the molecular mechanisms that regulate KCC2 gene expression in neurons. A previous study conducted with a glioma cell line showed that resveratrol activates the SIRT1 pathway and reduces the expression of NRSF/REST (50), a transcription factor that suppresses KCC2 expression (52). Our results demonstrate that resveratrol increases KCC2 expression by a similar mechanism, which could contribute to the therapeutic benefit of resveratrol on a number of brain disease conditions (68, 69). We also identified a group of GSK3 pathway inhibitors as KEECs. Overactivation of the GSK3 pathway has been reported in a number of brain diseases (70). Thus, our results suggest that GSK3 pathway inhibitors could exert beneficial effects on brain function through stimulating KCC2 expression. Another major KEEC target pathway, the FLT3 kinase signaling, has been investigated as a cancer therapy target (71, 72). Although FLT3 is expressed in the brain (73), drugs that target FLT3 pathway have not been extensively studied as potential treatments for brain diseases. Our results provide the first evidence that FLT3 signaling in the brain is critical for the regulation of key neuronal genes such as KCC2. Therefore, this work lays the foundation for further research to repurpose a number of clinically approved FLT3 inhibitors as novel brain disease therapies

Our results are valuable for the development of novel therapeutic strategies to treat neurodevelopmental diseases through rectification of dysfunctional neuronal chloride homeostasis. Because of the lack of pharmaceutical reagents that enhance KCC2 expression, bumetanide, a blocker of the inward chloride transporter NKCC1 that counteracts KCC2, has been used as an alternative (74). Bumetanide treatment has shown benefits in treating symptoms in mouse models of fragile X syndrome (75) and Down’s syndrome (76) and was shown to confer symptomatic benefit to human patients with autism or fragile X syndrome (77, 78). These findings strongly suggest that pharmacological restoration of disrupted chloride homeostasis may provide symptomatic treatment for various neurodevelopmental and neuropsychiatric disorders. However, NKCC1 lacks the neuron- restricted expression pattern of KCC2 and is also expressed in nonbrain tissue including kidney and inner ears (79), consistent with knockout of Nkcc1 in mouse model leading to deafness and imbalance (30). Therefore, bumetanide treatment may trigger undesirable side effects, thus severely limiting its therapeutic application. In contrast, the expression of KCC2 is restricted to neurons, and a number of the KEECs identified in this study that enhance KCC2 expression in neurons are Food and Drug Administration–approved and have not elicited any severe adverse effects in clinical trials (80–83). The promising efficacy of KEECs demonstrated in this study and the known safety of the KCC2 target warrant further preclinical and clinical studies to investigate these drugs and their derivatives as potential therapies for neurodevelopmental diseases.

In summary, in this work, we investigated the efficacy of KEECs to rescue a number of well-documented cellular and behavior phenotypes of RTT, including impaired GABA functional switch, reductions in excitatory synapse number and strength, immature neuronal morphology (53, 54), as well as an increase in breathing pauses and a decrease in locomotion (84). It is possible, however, that KEECs may also be effective in treatment of conditions other than RTT, as impairment in KCC2 expression has been linked to many brain diseases (17, 85) including epilepsy (86–88), schizophrenia (19, 20, 89), brain and spinal cord injury (21, 90), stroke and ammonia toxicity conditions (91–93), as well as the impairments in learning and memory observed in the senile brain (23). Thus, a phenotypically diverse array of brain diseases may benefit from enhancing the expression of KCC2. The newly identified KEECs are potential therapeutic agents for otherwise elusive neurological disorders



Rett syndrome (RTT) is a neurodevelopmental disorder caused by mutations in the methyl CpG binding protein 2 (MECP2) gene. There are currently no approved treatments for RTT. The expression of K+/Cl− cotransporter 2 (KCC2), a neuron-specific protein, has been found to be reduced in human RTT neurons and in RTT mouse models, suggesting that KCC2 might play a role in the pathophysiology of RTT. To develop neuron-based high-throughput screening (HTS) assays to identify chemical compounds that enhance the expression of the KCC2 gene, we report the generation of a robust high-throughput drug screening platform that allows for the rapid assessment of KCC2 gene expression in genome-edited human reporter neurons. From an unbiased screen of more than 900 small-molecule chemicals, we have identified a group of compounds that enhance KCC2 expression termed KCC2 expression– enhancing compounds (KEECs). The identified KEECs include U.S. Food and Drug Administration–approved drugs that are inhibitors of the fms-like tyrosine kinase 3 (FLT3) or glycogen synthase kinase 3 (GSK3) pathways and activators of the sirtuin 1 (SIRT1) and transient receptor potential cation channel subfamily V member 1 (TRPV1) pathways. Treatment with hit compounds increased KCC2 expression in human wild-type (WT) and isogenic MECP2 mutant RTT neurons, and rescued electrophysiological and morphological abnormalities of RTT neurons. Injection of KEEC KW-2449 or piperine in Mecp2 mutant mice ameliorated disease-associated respiratory and locomotion phenotypes. The small-molecule compounds described in our study may have therapeutic effects not only in RTT but also in other neurological disorders involving dysregulation of KCC2.


By screening these KCC2 reporter human neurons, we identified a number of hits KCC2 expression–enhancing compounds (KEECs) from ~900 small-molecule compounds. Identified KEECs were validated by Western blot and quantitative reverse transcription polymerase chain reaction (RT-PCR) experiments on cultured human wild-type (WT) and isogenic RTT neurons, as well as on organotypic mouse brain slices. Pharmacological and molecular biology experiments showed that identified KEECs act through inhibition of the fms-like tyrosine kinase 3 (FLT3) or glycogen synthase kinase 3b (GSK3b) kinases, or activation of the sirtuin 1 (SIRT1) or transient receptor potential cation channel subfamily V member 1 (TRPV1) pathways. Treatment of RTT neurons with KEECs rescued disease-related deficits in GABA functional switch, excitatory synapses, and neuronal morphological development. Last, injection of the identified KEEC KW-2449 or piperine into a Mecp2 mutant mice ameliorated behavioral phenotypes including breathing pauses and reduced locomotion, which represent important preclinical data, suggesting that the KEECs identified in this study may be effective in restoring impaired E/I balance in the RTT brain and provide symptomatic treatment for patients with RTT.





Fig. 2. KEEC treatment–induced enhancement of KCC2 protein and mRNA expression in cultured organotypic mouse brain slices and a hyperpolarizing EGABA shift in cultured immature neurons.

(E to G) KCC2 and NKCC1 mRNA expression induced by FLT3 inhibitors including sunitinib (n = 4), XL-184 (n = 6), crenolanib (n = 4), or a structural analog of BIO termed indirubin monoxime (n = 6). The calculated ratios of KCC2/NKCC1 mRNA expression are shown in (G). A.U., arbitrary units




Our results are valuable for the development of novel therapeutic strategies to treat neurodevelopmental diseases through rectification of dysfunctional neuronal chloride homeostasis. Because of the lack of pharmaceutical reagents that enhance KCC2 expression, bumetanide, a blocker of the inward chloride transporter NKCC1 that counteracts KCC2, has been used as an alternative (74). Bumetanide treatment has shown benefits in treating symptoms in mouse models of fragile X syndrome (75) and Down’s syndrome (76) and was shown to confer symptomatic benefit to human patients with autism or fragile X syndrome (77, 78). These findings strongly suggest that pharmacological restoration of disrupted chloride homeostasis may provide symptomatic treatment for various neurodevelopmental and neuropsychiatric disorders. However, NKCC1 lacks the neuron restricted expression pattern of KCC2 and is also expressed in nonbrain tissue including kidney and inner ears (79), consistent with knockout of Nkcc1 in mouse model leading to deafness and imbalance (30). Therefore, bumetanide treatment may trigger undesirable side effects, thus severely limiting its therapeutic application. In contrast, the expression of KCC2 is restricted to neurons, and a number of the KEECs identified in this study that enhance KCC2 expression in neurons are Food and Drug Administration–approved and have not elicited any severe adverse effects in clinical trials (80–83). The promising efficacy of KEECs demonstrated in this study and the known safety of the KCC2 target warrant further preclinical and clinical studies to investigate these drugs and their derivatives as potential therapies for neurodevelopmental diseases.


In summary, in this work, we investigated the efficacy of KEECs to rescue a number of well-documented cellular and behavior phenotypes of RTT, including impaired GABA functional switch, reductions in excitatory synapse number and strength, immature neuronal morphology (53, 54), as well as an increase in breathing pauses and a decrease in locomotion (84). It is possible, however, that KEECs may also be effective in treatment of conditions other than RTT, as impairment in KCC2 expression has been linked to many brain diseases (17, 85) including epilepsy (86–88), schizophrenia (19, 20, 89), brain and spinal cord injury (21, 90), stroke and ammonia toxicity conditions (91–93), as well as the impairments in learning and memory observed in the senile brain (23). Thus, a phenotypically diverse array of brain diseases may benefit from enhancing the expression of KCC2. The newly identified KEECs are potential therapeutic agents for otherwise elusive neurological disorders.




The science-light version:-

Drug screen reveals potential treatments for Rett syndrome

An experimental leukemia drug and a chemical in black pepper ease breathing and movement problems in a mouse model of Rett syndrome, according to a new study.

Rett syndrome is a rare brain condition related to autism, caused by mutations in the MECP2 gene. Because the gene is located on the X chromosome, the syndrome occurs almost exclusively in girls. No drugs are available to treat Rett.
The team screened 929 compounds from three large drug libraries, including one focused on Rett therapies. They found 30 compounds that boost KCC2’s expression in the MECP2 neurons; 14 of these also increased the protein’s expression in control neurons.

The team tested two of the identified compounds in mice with mutations in MECP2: KW-2449, which is a small molecule in clinical trials for leukemia, and piperine, an herbal supplement and component of black pepper. These mice have several traits reminiscent of Rett. They are prone to seizures, breathing problems, movement difficulties and disrupted social behavior.
Injecting the mice with either drug daily for two weeks improved the animals’ mobility relative to untreated mice. The drugs also eased the mice’s breathing problems, decreasing the frequency of pauses in breathing (apnea). The findings appeared in July in Science Translational Medicine.


 

Piperine, Resveratrol and analogs thereof

Piperine and Resveratrol are commercially available supplements.

Resveratrol has been mentioned many times in this blog.  It has numerous beneficial properties, to which we can now add increasing KCC2 expression, but it is held back by its poor ability to cross the blood barrier.

The other natural substance highlighted in the study is piperine. Piperine is the substance that gets added to curcumin to increases its bioavailability and hopefully get its health benefits.

Piperine has been recently been found to be a positive allosteric modulator of GABAA receptors.

It may be that piperine has 2 different effects on GABA, or maybe it is just the same one?

The result is that people are trying to develop modified versions of piperine that could be patentable commercial drugs.

Piperine also activated TRPV1 receptors.

You might wonder what is the effect in humans of plain old piperine in bumetanide-responsive autism.

Invitro blood–brain-barrier permeability predictions for GABAA receptor modulating piperine analogs

The alkaloid piperine from black pepper (Piper nigrum L.) and several synthetic piperine analogs were recently identified as positive allosteric modulators of γ-aminobutyric acid type A (GABAA) receptors. In order to reach their target sites of action, these compounds need to enter the brain by crossing the blood–brain barrier (BBB). We here evaluated piperine and five selected analogs (SCT-66, SCT-64, SCT-29, LAU397, and LAU399) regarding their BBB permeability. Data were obtained in three in vitro BBB models, namely a recently established human model with immortalized hBMEC cells, a human brain-like endothelial cells (BLEC) model, and a primary animal (bovine endothelial/rat astrocytes co-culture) model. For each compound, quantitative UHPLC-MS/MS methods in the range of 5.00–500 ng/mL in the corresponding matrix were developed, and permeability coefficients in the three BBB models were determined. In vitro predictions from the two human BBB models were in good agreement, while permeability data from the animal model differed to some extent, possibly due to protein binding of the screened compounds. In all three BBB models, piperine and SCT-64 displayed the highest BBB permeation potential. This was corroborated by data from in silico prediction. For the other piperine analogs (SCT-66, SCT-29, LAU397, and LAU399), BBB permeability was low to moderate in the two human BBB models, and moderate to high in the animal BBB model. Efflux ratios (ER) calculated from bidirectional permeability experiments indicated that the compounds were likely not substrates of active efflux transporters.


The alkaloid piperine, the major pungent component of black pepper (Piper nigrum L.), was recently identified as a positive allosteric γ-aminobutyric acid type A (GABAA) receptor modulator. The compound showed anxiolytic-like activity in behavioral mouse models, and was found to interact with the GABAA receptors at a binding site that was independent of the benzodiazepine binding site [1,2]. Given that the compound complied with Lipinski’s “rule of five” [1], it represented a new scaffold for the development of novel GABAA receptor modulators [1–3]. Given that piperine also activates the transient receptor potential vanilloid 1 (TRPV1) receptors [4] which are involved in pain signaling and regulation of the body temperature [5,6], structural modification of the parent compound was required to dissect GABAA and TRPV1 activating properties

For drugs acting on the central nervous system (CNS), brain penetration is required. This process is controlled by the blood-brain barrier (BBB), a tight layer of endothelial cells lining the brain capillaries that limits the passage of molecules from the blood circulation into the brain [10]. Since low BBB permeability can reduce CNS exposure [11], lead compounds should be evaluated at an early stage of the drug development process for their ability to permeate the BBB [12].

Conclusions

Piperine and five selected piperine analogs with positive GABAA receptor modulatory activity were screened in three in vitro cell-based human and animal BBB models for their ability to cross the BBB. Data from the three models differed to some extent, possibly due to protein binding of the piperine analogs. In all three models, piperine and SCT-64 displayed the highest BBB permeation potential, which could be corroborated by in silico prediction data. For the other piperine analogs (SCT-66, SCT-29, LAU397, and LAU399), BBB permeability was low to moderate in the two human models, and moderate to high in the animal model. ER calculated from bidirectional permeability experiments indicated that the compounds were likely not substrates of active efflux. In addition to the early in vitro BBB permeability assessment of the compounds, further studies (such as PK and drug metabolism studies) are currently in progress in our laboratory. Taken together, these data will serve for selecting the most promising candidate molecule for the next cycle of medicinal chemistry optimization




Conclusion

My conclusions are a little different to the MIT researchers

“The newly identified KEECs are potential therapeutic agents for otherwise elusive neurological disorders.”

This assumes that you cannot safely use bumetanide/azosemide, which you can.  Open your eyes and look at France, where several hundred children with autism are safely taking bumetanide.

”It is possible, however, that KEECs may also be effective in treatment of conditions other than RTT, as impairment in KCC2 expression has been linked to many brain diseases”

We have copious evidence that elevated chloride is a feature of many conditions, not just Rett’s and an effective cheap therapy has been sitting in the pharmacy for decades.

In the clinical trial of R-Baclofen that failed, there were some positive effects on some subjects.  Were the positive effects just caused by the effect of Baclofen in increasing KCC2 expression?

Should R-Baclofen become a cheap generic, it might indeed become a useful add-on for those with bumetanide-responsive. Regular Baclofen (Lioresal) is an approved drug, but it does have some side effects, so most likely R-baclofen will have side effects in some.

Baclofen itself in modest doses has little effect on bumetanide-responsive autism.



A cheap side-effect free KCC2 enhancer would be a good drug for autism, although cheap, safe NKCC1 blockers already exist. 

I have no idea if piperine benefits bumetanide-responsive autism.  Piperine has long been used in traditional medicine.

The TRPV1 receptor also affected by piperine plays a role in pain and anxiety.

We saw in the post below that TRPV1 controls cortical microglia activation and that GABARAP modulates TRPV1 expression.

So, TRPV1 and GABAA receptors are deeply intertwined.

  

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



Is Piperine going to make autism better, or worse?








Wednesday, 14 December 2016

Refining Antioxidant (ROS & RNS) Therapy in Autism -  Selenium and Molybdenum




Today’s post is about further refining antioxidant therapy.

As we saw in a recent post, oxidative and nitrosative stress is a very common feature of autism and is treatable with OTC products.

The cheapest antioxidant, N-acetylcysteine (NAC), looks to be the best one, but there are numerous others with exotic names and equally exotic prices.

Today we just look at selenium and molybdenum.  Selenium was on my to-do list for a long time because it affects some key enzymes call GPX (glutathione peroxodases).
Molybdenum was enthusiastically recommended in a recent comment and this blog has previously touched on Molybdenum Cofactor Sulfurase (MOCOS).

Rather surprisingly, there is a commercial product that contains NAC, Selenium and Molybdenum. 


Selenium and GPX (glutathione peroxodases)

There are eight different glutathione peroxodases, but GPx1, GPx2, GPx3, and GPx4 are all made from selenium.

GPX speeds up the antioxidant reactions that involve glutathione (GSH).

In autism we know that both GSH and GPX are lacking.

We know how to make more GSH, just take some NAC.  But what about the catalyst GPX? 
There may be an equally easy way to increase that. 


Selenium and Thyroid  Enzymes

Selenium is also part of the three deiodinase enzymes D1, D2 and D3.

The active thyroid hormone is called T3, but most of what is circulating in your body is the inactive pro-hormone form called T4.

Deiodinase 1 (D1)  both activates T4 to produce T3 and inactivates T4. Besides its increased function in producing extrathyroid T3, its function is less well understood than D2 or D3.

Deiodinase 2 (D2), located in the ER membrane, converts T4 into T3 and is a major source of the cytoplasmic T3 pool.  It looks like some people with autism may lack D2 in their brain.

Deiodinase 3 (D3) prevents T4 activation and inactivates T3. It looks like some people with autism have too much D3 in their brain.

D2 and D3 are important in homeostatic regulation in maintaining T3 levels at the plasma and cellular levels.


·        In hyperthyroidism D2 is down regulated and D3 is upregulated to clear extra T3

·        in hypothyroidism D2 is upregulated and D3 is downregulated to increase cytoplasmic T3 levels


Serum T3 levels remain fairly constant in healthy individuals, but D2 and D3 can regulate tissue specific intracellular levels of T3 to maintain homeostasis since T3 and T4 levels may vary by organ.  

It appears that some people with autism may have central hyperthyroidism, meaning in their brain.

Regular readers may recall this post:-


The major source of the biologically active hormone T3 in the brain is the local intra-brain conversion of T4 to T3, while a small fraction comes from circulating T3. 

As evidence derived from in vitro studies suggests, in response to oxidative stress D3 increases while D2 decreases (Lamirand et al., 2008; Freitas et al., 2010).  As we know in the autistic brain we have a lot of oxidative stress.



Furthermore, in ASD, the lower intra-brain T3 levels occur in the

Absence of a systemic T3 deficiency (Davis et al., 2008), most likely due to the increased activity of D3.



So in some autistic brains we have too much D3 which is inactivating T3 and preventing T4 being converted to T3.

Reduced D2 is reducing the conversion of T4 to T3. 

We would therefore want to increase D2 in some autism.

This can be achieved by:-

·        Reducing oxidative stress, which we are already sold on. 

·        We can also potentially upregulate the gene that produces D2 using some food-based genetic therapy. Kaempferol (KPF) appears to work and may explain why broccoli sprout powder makes some people go hyper and some others cannot sleep  



The cAMP-responsive gene for type 2 iodothyronine deiodinase (D2), an intracellular enzyme that activates thyroid hormone (T3) for the nucleus, is approximately threefold upregulated by KPF



·        Perhaps low levels of selenium differentially affect the synthesis of D1, D2 and D3?

  

Where does selenium come from? 

We know from Chauham/James that selenium levels are reduced in autism, but we also know that selenium levels vary widely by geography.  

You get selenium from your diet and the level of selenium in the soil varies widely.  It is widely held that most healthy people should have plenty selenium in their diet. 

In the following paper there is an analysis of Selenium status in Europe and the Middle East.
Since we have plenty of Polish readers I have included the chart with the Polish data (on the left).  It shows that Polish people may be a little deficient in selenium.
You can see the level of selenium in Poland is below that needed to optimise plasma GPx activity.
So if you already have reduced GPx activity, because of autism, and you really need to make the most of your limited glutathione (GSH) because you have oxidative/nitrosative stress, then a little extra selenium could be just what the doctor should have ordered.

  

Se is an essential non-metal trace element [3] that is required for selenocysteine synthesis and is essential for the production of selenoproteins [4]. Selenoproteins are primarily either structural or enzymatic [2], acting as catalysts for the activation of thyroid hormone and as antioxidants, such as glutathione peroxidases (GPxs) [5]. GPx activity is commonly used as a marker for Se sufficiency in the body [6], where serum or plasma Se concentrations are believed to achieve maximum GPx expression at 90–100 μg/L (90.01 μg/L as proposed by Duffield and colleagues [7] and 98.7 μg/L according to Alfthan et al. [8]). However, plasma selenoprotein P (SEPP1) concentration is a more suitable marker than plasma GPx activity [9]. Prospective studies provide some evidence that adequate Se status may reduce the risk of some cancers, while elevated risk of type 2 diabetes and some cancers occurs when the Se concentration exceeds 120 μg/L [10]. Higher Se status has been linked to enhanced immune competence with better outcomes for cancer, viral infections, including HIV progression to AIDS, male infertility, pregnancy, cardiovascular disease, mood disorders [2] and, possibly, bone health [11–14].





  




Selenium and NAC for Rats with TBI

Perhaps not surprisingly, selenium and NAC have been found beneficial for Rats unfortunate enough to have sufferred a traumatic brain injury (TBI).




It has been suggested that oxidative stress plays an important role in the pathophysiology of traumatic brain injury (TBI). N-acetylcysteine (NAC) and selenium (Se) display neuroprotective activities mediated at least in part by their antioxidant and anti-inflammatory properties although there is no report on oxidative stress, antioxidant vitamin, interleukin-1 beta (IL)-1β and IL-4 levels in brain and blood of TBI-induced rats. We investigated effects of NAC and Se administration on physical injury-induced brain toxicity in rats. Thirty-six male Sprague–Dawley rats were equally divided into four groups. First and second groups were used as control and TBI groups, respectively. NAC and Se were administrated to rats constituting third and forth groups at 1, 24, 48 and 72 h after TBI induction, respectively. At the end of 72 h, plasma, erythrocytes and brain cortex samples were taken. TBI resulted in significant increase in brain cortex, erythrocytes and plasma lipid peroxidation, total oxidant status (TOS) in brain cortex, and plasma IL-1β values although brain cortex vitamin A, β-carotene, vitamin C, vitamin E, reduced glutathione (GSH) and total antioxidant status (TAS) values, and plasma vitamin E concentrations, plasma IL-4 level and brain cortex and erythrocyte glutathione peroxidase (GSH-Px) activities decreased by TBI. The lipid peroxidation and IL-1β values were decreased by NAC and Se treatments. Plasma IL-4, brain cortex GSH, TAS, vitamin C and vitamin E values were increased by NAC and Se treatments although the brain cortex vitamin A and erythrocyte GSH-Px values were increased through NAC only. In conclusion, NAC and Se caused protective effects on the TBI-induced oxidative brain injury and interleukin production by inhibiting free radical production, regulation of cytokine-dependent processes and supporting antioxidant redox system.

  


  

And now to Molybdenum 

Molybdenum (Mo) is a trace dietary element necessary for human survival.

Low soil concentration of molybdenum in a geographical band from northern China to Iran results in a general dietary molybdenum deficiency, and is associated with increased rates of esophageal cancer.  Compared to the United States, which has a greater supply of molybdenum in the soil, people living in those areas have about 16 times greater risk for esophageal cancer.
So you would not want to have molybdenum deficiency.

Four Molybdenum-dependent enzymes are known, all of them include molybdenum cofactor (Moco) in their active site: sulfite oxidase, xanthine oxidoreductase, aldehyde oxidase, and mitochondrial amidoxime reductase.

Moco cannot be taken up as a nutrient, and thus it requires to made in your body from molybdenum.

If your body cannot make enough Moco you may develop what is called molybdenum cofactor deficiency, which would ultimately kill you. It is ultra rare.

Symptoms include early seizures, low blood levels of uric acid, and high levels of sulphite, xanthine, and uric acid in urine.


When caused by a mutation in the MOCS1 gene it is called the type A variant.

Molybdenum cofactor deficiency may indeed be extremely rare, but MOCS1 is a known autism gene.  Perhaps there exists partial molybdenum cofactor deficiency, which is not rare at all?





Source:-  Identification of candidate intergenic risk loci in autism spectrum disorder



MOCOS (Molybdenum cofactor sulfurase)


Molybdenum cofactor sulfurase is an enzyme that in humans is encoded by the MOCOS gene.

MOCOS sulfurates the molybdenum cofactor of xanthine dehydrogenase (XDH) and aldehyde oxidase (AOX1), which is required for their enzymatic activities.

MOCOS is downregulated in autism and is suggested to induce increased oxidative-stress sensitivity, which would not be good.

So it looks like we need a clever way to upregulate MOCOS.

You need adequate molybdenum cofactor (Moco), for which you do need adequate molybdenum.

You need the genes MOCS1 and MOCOS to be correctly expressed.

SIRT1 activation, which is a future therapy for Alzheimer’s, is suggested to increase MOCOS, as may NRF2.

Sirtuin-activating compounds (STAC) are chemical compounds having an effect on sirtuins, a group of enzymes that use NAD+ to remove acetyl groups from proteins. They are molecules able to prevent aging related diseases like Alzheimer's, diabetes, and obesity.  There is quite a long list that includes ranges from polyphenols such as resveratrol, the flavonols fisetin, and quercetin also butein, piceatannol, isoliquiritigenin,


Fisetin is found in strawberries, cucumbers and supplements.  In normal animals, fisetin can improve memory; it also can have an effect on animals prone to Alzheimer's.




Here is the excellent French paper on MOCOS:-



With an onset under the age of 3 years, autism spectrum disorders (ASDs) are now understood as diseases arising from pre- and/or early postnatal brain developmental anomalies and/or early brain insults. To unveil the molecular mechanisms taking place during the misshaping of the developing brain, we chose to study cells that are representative of the very early stages of ontogenesis, namely stem cells. Here we report on MOlybdenum COfactor Sulfurase (MOCOS), an enzyme involved in purine metabolism, as a newly identified player in ASD. We found in adult nasal olfactory stem cells of 11 adults with ASD that MOCOS is downregulated in most of them when compared with 11 age- and gender-matched control adults without any neuropsychiatric disorders. Genetic approaches using in vivo and in vitro engineered models converge to indicate that altered expression of MOCOS results in neurotransmission and synaptic defects. Furthermore, we found that MOCOS misexpression induces increased oxidative-stress sensitivity. Our results demonstrate that altered MOCOS expression is likely to have an impact on neurodevelopment and neurotransmission, and may explain comorbid conditions, including gastrointestinal disorders. We anticipate our discovery to be a fresh starting point for the study on the roles of MOCOS in brain development and its functional implications in ASD clinical symptoms. Moreover, our study suggests the possible development of new diagnostic tests based on MOCOS expression, and paves the way for drug screening targeting MOCOS and/or the purine metabolism to ultimately develop novel treatments in ASD.  

Lately, a diminished seric expression of glutathione, glutathione peroxidase, methionine and cysteine has been highlighted in a meta-analysis from 29 studies on ASD subjects.45 Along this line, purines and purine-associated enzymes are recognized markers of oxidative stress. ROS are generated during the production of uric acid, catalyzed by xanthine oxidase and XDH.46 Conversely, uric acid is nowadays recognized as a protective factor acting as a ROS scavenger.47, 48 Interestingly, allopurinol, a xanthine oxidase inhibitor, was found efficient in reducing symptoms, especially epileptic seizures, in ASD patients displaying high levels of uric acid.49 However, in our cohort, only 3 out of 10 patients exhibited an abnormal uric acid secretion. It can therefore be postulated that still unknown other MOCOS-associated mechanisms may have a role in the unbalanced stress response observed in ASD OSCs.
Identifying and manipulating downstream effectors of MOCOS will be the next critical step to better understand its mechanisms of action. In parallel, we plan to ascertain some of its upstream regulators. For example, bioinformatic analyses revealed that the promoter region of MOCOS includes conserved binding sites for transcription factors such as GATA3 and NRF2. In addition, other putative interactors, such as the NAD-dependent deacetylase sirtuin-1 (SIRT1), may have a regulatory role on MOCOS expression. Interestingly, these three genes have been associated with ASD, fragile X syndrome, epilepsy and/or oxidative stress.54, 55, 56, 57 In conclusion, our study opens an unexplored new avenue for the study of MOCOS in ASD, and could set bases for the development of new diagnostic tools as well as the search of new therapeutics.

Conclusion

It looks like a little extra selenium may be in order to increase those GPx enzymes that are need to speed up aspects of the antioxidant activity of GSH.

When it comes to molybdenum, things get much more complex. You certainly do not want to be deficient in molybdenum and you do not want Molybdenum cofactor deficiency; you also do not want molybdenum cofactor Sulfurase (MOCOS) mis-expression.

It is fair to say that quite likely there is a problem related to molybdenum that affects oxidative stress in autism; but it is not yet clear what to do about it.  I rather doubt the solution is as simple as just a little extra molybdenum, but it is easy to try.

On the plus side, we see that if you have autism, epilepsy and high uric acid you are likely to benefit from allopurinol, which also seems to help in COPD.

There is nothing new about allopurinol possibly be effective in some autism, as from this 25 year old book, Diagnosis and Treatment of Autism.



Again we see that activating NRF2 looks a good idea, that applies to both autism and COPD.
One thing to note is that NRF2 activators are good for cancer prevention, but if you have a cancer you want NRF2 inhibitors.

NRF2 activators include sulforaphane (SFN), R-alphalipoic acid (ALA), resveratrol and curcumin.  SFN is by far the most potent.  Resveratrol and curcumin have a problem with bioavailability.