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Showing posts with label Epigenopathies. Show all posts
Showing posts with label Epigenopathies. Show all posts

Tuesday 23 February 2016

Therapeutic Epigenetics in Autism and Junk DNA




Today’s post takes another dip into the genetics of autism and currently existing therapies that could be re-purposed for autism.  We also see that many secrets remain beyond the 3% of your DNA that usually gets all the research attention.  The remaining 97% is not junk after all.

There was an earlier post on this blog that introduced Epigenetics.  It is not such a complicated subject, just think about it as little tags on your DNA that turn genes on/off usually when they should not be, but there remains the possibility to use epigenetics for good.  In people with under-expression of an important gene you could “tag it” and then increase its expression.

The exome is the part of your DNA that encodes the various proteins needed to build your body.  The remaining 97% of your DNA was once thought to be just junk; we saw in recent post that one part contains enhancers and silencers that control expression of the genes in the 3% that is the exome.

A recent study of gene expression in neurological conditions including autism showed just how broadly disturbed gene expression is.







(A) Consistent fold enrichments were found for each cell type across fourteen cortical and three subcortical brain regions of Alzheimer's patients. The box plots mark the distribution of cellular fold enrichments across all the brain regions examined. Asterisks mark that the fold enrichment for each cell type that was found to be significantly non-zero with p < 0.05. (B) Two independent autism studies show the same cellular phenotypes, including upregulation of glial cells and downregulation of neurons. Asterisks mark those cell types found to be significantly differential with p < 0.05 after BH correction over all groups.


Here I am making the point that even though only a handful of genes may have an identifiable dysfunction, a much broader range of genes seem to be affected, as we see in the wide range of over and under expressed genes.

While it would be logical to think about a specific dysfunction needing a therapy that targets just that gene, this appears not to be necessary.

It appears that downstream processes may be the most damaging/relevant, for example disturbances in Protein Kinase A and C (PKA and PKC) may play a key role in many cases of regressive autism, and this will feature in its own post, because it would be treatable today. 

Reduced activity of protein kinase C in the frontal cortex of subjects with regressive autism: relationship with developmental abnormalities.


Brain Region–Specific Decrease in the Activity and Expression of Protein Kinase A inthe Frontal Cortex of Regressive Autism

 

Both the above papers are by Abha and Ved Chauhan.  I put Abha on my Dean’s list long ago.  I did have a discussion with her a while back.  She is clearly a very nice person and intellectually towers over the Curemark lady (Joan Fallon) who gets $40 million to play with her pancreatic enzymes, but never publishes anything except very superficial patents.


I think for $40 million Abha and Ved could figure it all out.

PKB, otherwise known as Akt is also very relevant to some types of autism.

Tamoxifen, recently shown to reverse autism in a SHANK3 mouse model, is a PKC inhibitor.

Another epigenetic drug, Theophylline activates PKA.

Akt, also known as protein kinase B (PKB), is a central node in cell signaling downstream of growth factors, cytokines, and other cellular stimuli. Aberrant loss or gain of Akt activation underlies the pathophysiological properties of a variety of complex diseases, including type-2 diabetes and cancer.

If you could identify if a particular person was hypo/hyper in PKA, PKB and PKC, this might well open the door to an effective treatment.


Research on PKB, also known as AKT

Dysregulation of theIGF-I/PI3K/AKT/mTOR signaling pathway in autism spectrum disorders.




And a paper from the clever Japanese:-



Autism spectrum disorder is a set of neurodevelopmental disorders in terms of prevalence, morbidity and impact to the society, which is characterized by intricate behavioral phenotype and deficits in both social and cognitive functions. The molecular pathogenesis of autism spectrum disorder has not been well understood, however, it seems that PI3K, AKT, and its downstream molecules have crucial roles in the molecular pathogenesis of autism spectrum disorder. The PI3K/AKT signaling pathway plays an important role in the regulation of cell proliferation, differentiation, motility, and protein synthesis. Deregulated PI3K/AKT signaling has also been shown to be associated with the autism spectrum disorder. Discovery of molecular biochemical phenotypes would represent a breakthrough in autism research. This study has provided new insight on the mechanism of the disorder and would open up future opportunity for contributions to understand the pathophysiology


For those who favour dietary intervention:-




  
Based on the above chart curcumin should likely be good for my N=1 case of autism. Time will tell.



Consequences of upstream dysfunctions

So it might be better to consider autism as a disease of wider downstream gene expression, rather than necessarily of “faulty” genes.  Modulating the resulting wider gene expression may be much more realistic than fixing individual genes.

It is certainly plausible that the body has its own protective self-repair mechanism that might be somehow re-energized. Some people have pondered why so many highly intelligent mathematicians and computer scientists seem have relatives with autism.  The clever genes do associate with a type of autism plus ID/MR.  It was suggested that protective genetic changes might be in play, so that the people with the most genetic variance are actually the family members without the autism.

This does remain conjecture, but as more whole genome data is collected we are seeing some interesting findings.

A fascinating very recent study that looked at a group of 53 families with autism using the traditional approach of whole exome sequencing and also microarray. 

Using these methods, that are the current gold standard, the researchers found very little.  Dysfunctions in the 700 known autism genes were not detected.

However using more expensive whole genome sequencing, dysfunctions were identified in the “DNA junk” zone very close beside the known autism genes.  The researchers were then able to identify the genetic cause of 30% of the cases, a big improvement on 0%.  I expect if they looked a little harder the 30% would be higher.


“We performed whole-genome sequencing (WGS) of 208 genomes from 53 families affected by simplex autism.”

“For the majority of these families, no copy-number variant (CNV) or candidate de novo gene-disruptive single-nucleotide variant (SNV) had been detected by microarray or whole-exome sequencing (WES).

Comparing the sequences of the individuals with autism and those of their unaffected siblings, the researchers found that people with autism are more likely to have genetic variants — either single base-pair changes in the sequence or small CNVs — in swaths of DNA abutting known autism genes. But the researchers only found the variants after they restricted their search to regions of the genome already implicated in autism, and even then the statistical significance is modest.

Sequencing whole genomes could reveal the genetic cause of autism in as much as 30 percent of people for whom faster and cheaper sequencing methods come up short

“It’s increasing power even in areas that are supposed to be covered by whole-exome sequencing,” says Peixoto. “It seems that it’s clear that whole-genome sequencing will become the standard.”







One specific microRNA has strong links to autism spectrum disorder, say TSRI scientists


Epigenopathies

Many diseases have an epigenetic component. The severe progressive asthma that is COPD is a well-known example.  It appears that smoking in middle age often leads to permanent epigenetic changes that come back to haunt often then non-smokers in old age.  Even though they have not smoked for twenty years, there oxidative stress response has been permanently modified.  This results in a kind of steroid resistance, so that usually reliable drug therapies fail to work. 

It is thought that autism has an epigenetic component.  This would do some way to explaining 30-40% of the increase in prevalence in recent years that is not explained by ever widening diagnostic criteria.

Because epigenetic changes can be heritable and can be accumulated from all kinds of exposures, even simple ones like severe emotional stress and pollution, you can reconcile autism as being primarily a genetic condition even though incidence has clearly risen within one or two generations. So you can have an “epigenetic epidemic”, so to speak.


Epigenetics as a therapy

While much is written about epigenetic change being bad, it could also be good.

There are many known substances that affect gene expression; some are very target specific which is useful.

This answers a recent issue raised by a reader of this blog who did exome sequencing. What is the point of discovering a genetic dysfunction if there is no therapy? Medicine is some decades behind science, better to know what gene is affected because you well be able to affect its expression, you just need some help from Google.

Epigenetic therapy could be used to remove unwanted tags, but it could also be used to leave new ones to upregulate under-expressed genes.

Such epigenetic therapy is already a reality in COPD and is being considered for rare single autisms where one copy of the gene is not functional, so turn up the volume on the remaining copy.

As we saw in the post on epigenetics, one potential category of drugs are HDAC inhibitors, these would affect one epigenetic mechanism.

There are many such HDAC inhibitors and most have other modes of action, so you cannot be sure what is giving the noted effect.


Valproate

This epilepsy drug has numerous effects including as a HDAC inhibitor.  Given to mothers during pregnancy it can cause autism in the offspring, but when given to the affected offspring the autism can be reduced.

Valproate is given off label to treat autism even when no epilepsy is present.

As we saw in the comments section, long term valproate se can have side effects.


Sulforaphane

This substance derived from broccoli and patented by Johns Hopkins, is another HDAC inhibitor.  It also upregulates Nrf2, which turns on the oxidative response genes.  This was proposed as a COPD therapy by Professor Barnes.

We saw in a post that for Nrf2 to have its full effect there needed to be enough of a protein called DJ-1.  You can increase DJ-1 expression with cinnamon (sodium benzoate).

That was one reason to think that cinnamon would complement Sulforaphane as a therapy for both COPD and some autism.


Sodium Butyrate

Sodium Butyrate is an HDAC inhibitor that is available as a supplement. We came across it in an earlier post as a precursor to butyric acid.  Butyric acid plays a role in the permeability of the gut and the Blood Brain Barrier (BBB).  It also seems to protect from auto immune disease.

Butyrate is fed to millions of farm animals every day to increase their resistance to auto-immune disease.

Butyric acid is produced naturally in the gut by the bacteria living there, however the amount can be increased by the uses of a particular probiotic-bacteria.

This would support the uses of sodium butyrate and the Miyari 588 bacteria.

I have on my to-do-list to investigate higher doses of Miyari 588, but having read the comment by Alli that 500 mg of sodium butyrate is effective, I will try that first.  She also found higher doses ineffective, which was the same in a mouse study published last November,

The study below highlights which genes were down-regulated and which were up-regulated, the overall effect was beneficial


Sodium butyrate attenuate ssocial behavior deficits and modifies the transcription ofinhibitory/excitatory genes in the frontal cortex of an autism model.

 

The core behavioral symptoms of Autism Spectrum Disorders (ASD) include dysregulation of social communication and the presence of repetitive behaviors. However, there is no pharmacological agent that is currently used to target these core symptoms. Epigenetic dysregulation has been implicated in the etiology of ASD, and may present a pharmacological target. The effect of sodium butyrate, a histone deacetylase inhibitor, on social behavior and repetitive behavior, and the frontal cortex transcriptome, was examined in the BTBR autism mouse model. A 100 mg/kg dose, but not a 1200 mg/kg dose, of sodium butyrate attenuated social deficits in the BTBR mouse model. In addition, both doses decreased marble burying, an indication of repetitive behavior, but had no significant effect on self-grooming. Using RNA-seq, we determined that the 100 mg/kg dose of sodium butyrate induced changes in many behavior-related genes in the prefrontal cortex, and particularly affected genes involved in neuronal excitation or inhibition. The decrease in several excitatory neurotransmitter and neuronal activation marker genes, including cFos Grin2b, and Adra1, together with the increase in inhibitory neurotransmitter genes Drd2 and Gabrg1, suggests that sodium butyrate promotes the transcription of inhibitory pathway transcripts. Finally, DMCM, a GABA reverse agonist, decreased social behaviors in sodium butyrate treated BTBR mice, suggesting that sodium butyrate increases social behaviors through modulation of the excitatory/inhibitory balance. Therefore, transcriptional modulation by sodium butyrate may have beneficial effects on autism related behaviors.


  

Theophylline

Theophylline is an old asthma drug that is an HDAC inhibitor.

At low doses it is now being trialled as an epigenetic add-on therapy in COPD.  It pretty obviously does work, but data needs to be collected to measure how effective it is and what is the best dose.

It shows how the COPD researchers/clinicians like Professor Barnes are doing a good job and not frightened to experiment.

Would a similar low dose of theophylline benefit a sub-group of those with autism/schizophrenia?  I think it is quite likely.

COPD and autism/schizophrenia share the same impaired oxidative stress response.



Chronic Obstructive Pulmonary Disease (COPD) is a progressive lung disease characterised by progressive airflow limitation. In the UK, it affects around 3 million people, is the fifth leading cause of death and costs the NHS approximately £1 billion annually. Exacerbations of COPD account for 60% of NHS COPD costs and are associated with accelerated rate of lung function decline, reduced physical activity, reduced quality of life, increased mortality and increased risk of co-morbidities. COPD treatment guidelines recommend inhaled corticosteroids (ICS) to reduce exacerbations and improve lung function. However, in COPD, airway inflammation is relatively insensitive to the anti-inflammatory effects of ICS and even high doses fail to prevent exacerbations. Preclinical and pilot studies demonstrate that low dose theophylline may increase the sensitivity of the airway inflammation to ICS, and thus when used with ICS will reduce the rate of COPD exacerbation. In this study we will determine the clinical effectiveness and cost-effectiveness of adding low dose theophylline to ICS therapy in patients with COPD. The primary outcome is the number of exacerbations. The primary economic outcome is the cost-per-QALY gained during the one year treatment period. We will recruit 1424 participants from primary and secondary care across seven areas of the UK. Participants will be randomised to theophylline (200 mg once or twice daily depending on smoking status and weight) or placebo for 12 months. We will follow participants up at six and twelve months to assess the number of exacerbations. We will also collect data on adverse events, health care utilisation, quality of life and breathlessness, and lung function. Low dose theophylline is cheap (10p/day) and, if shown to make current ICS therapy more effective in a cost effective manner, it will improve the quality of life of COPD patients and reduce the burden of COPD on the NHS.


At large doses, Theophylline has long been a therapy for asthma and COPD, but as with Sodium Butyrate, it is quite possible that larger doses of Theophylline produce a different result.  In other words the epigenetic effect fortunately comes from the low dose.

Low doses mean less chance of side effects.

For example, in anyone predisposed to reflux/GERD/GORD many asthma drugs pose a problem because at the same time as opening the airways in your lungs they will relax the lower esophageal sphincter and allow stomach acid to rise upwards.

We saw in an earlier post that in some types of autism something called mGluR5 is dysfunctional in the brain. By chance mGluR5 is also involved in closing the lower esophageal sphincter.  In people with reflux/GERD/GORD a mGluR5 inhibitor was found to have promise for the management of their symptoms.


Randomised clinical trial:effects of monotherapy with ADX10059, a mGluR5 inhibitor, on symptoms and reflux events in patients with gastro-oesophageal reflux disease.




So it is not surprising that many people with autism also have reflux/GERD/GORD. 

But the dysfunction with mGluR5 in autism can be both hyper and hypo, so the therapy might be a positive allosteric modulator (PAM), or a negative allosteric modulator (NAM).  

In someone with autism + reflux/GERD/GORD  it would be reasonable to think a NAM, like ADX10059, might help both conditions.



Gene Repression and Genome Stability

There is another epigenetic process that may be disturbing gene expression in some people and may be treatable.

I have been trying to find why so many people with autism can benefit from biotin; I think I have found a plausible explanation.

“Biotinylation of histones plays a role in gene repression and repression of transposable elements, thereby maintaining genome stability”

I think in some people with autism and no clinical deficiency of biotin the continued “overdosing” of biotin might be having an effect on gene expression, bringing things a little closer to where they should be.

Rather beyond the scope of this blog, it appears that in some people the impaired genome stability, reversible with biotin(ylation), this might be a significant cancer risk.

In essence, for most people supraphysiological concentrations of biotin will do absolutely nothing, but in a sub-group it might do a lot of good.  It is epigenetic, but you do not have to understand it to benefit from it.  It is complicated.




Transposable elements such as long terminal repeats (LTR) constitute 45% of the human genome; transposition events impair genome stability. Fifty-four promoter-active retrotransposons have been identified in humans. Epigenetic mechanisms are important for transcriptional repression of retrotransposons, preventing transposition events, and abnormal regulation of genes. Here, we demonstrate that the covalent binding of the vitamin biotin to lysine-12 in histone H4 (H4K12bio) and lysine-9 in histone H2A (H2AK9bio), mediated by holocarboxylase synthetase (HCS), is an epigenetic mechanism to repress retrotransposon transcription in human and mouse cell lines and in primary cells from a human supplementation study. Abundance of H4K12bio and H2AK9bio at intact retrotransposons and a solitary LTR depended on biotin supply and HCS activity and was inversely linked with the abundance of LTR transcripts. Knockdown of HCS in Drosophila melanogaster enhances retrotransposition in the germline. Importantly, we demonstrated that depletion of H4K12bio and H2AK9bio in biotin-deficient cells correlates with increased production of viral particles and transposition events and ultimately decreases chromosomal stability. Collectively, this study reveals a novel diet-dependent epigenetic mechanism that could affect cancer risk.

Here, we provide evidence for the existence of a novel diet-dependent epigenetic mechanism that represses retrotransposons. Importantly, we demonstrated that depletion of biotinylated histones in biotin-deficient cells increases LTR transcript levels, production of viral particles, and retrotransposition events, and ultimately decreases chromosomal stability. Both biotin deficiency and supplementation are prevalent in the US. For example, moderate biotin deficiency has been observed in up to 50% of pregnant women (35,36). About 20% of the US population reports taking biotin supplements (37), producing supraphysiological concentrations of vitamin in tissues and body fluids (23,28,35). The findings presented here suggest that altered biotin status in these population subgroups might affect chromosomal stability and cancer risk. 

Biotin and biotinidase deficiency


Biotin requirements for DNA damage prevention



  

Conclusion

I never got round to writing part 2 of my epigenetics post, but my experience of HDAC inhibitors to date has been very positive.

I would be the first to admit that this is rather hit and miss.  It was only when reading the paper on potential therapies for Pitt Hopkins, that was openly musing about HDAC inhibitors, in an equally hit and miss approach, that I thought I would write further about it.

It really seems totally haphazard, because you cannot predict the effect with any level of certainty.  If there is a self-repair mechanism trying to maintain homeostasis of the genome, haphazard may be good enough.

10mg of biotin twice a day does have a mild but noticeable stabilizing effect; is this caused by better maintaining genome stability? I have no idea. 

I will try sodium butyrate and if it works I will have to establish what dose of Miyari 588 produces the same effect.  Both are used in animal feed to reduce inflammatory disease, so you are already indirectly exposed to them if you eat meat.

Theophylline should also be investigated.  This is a very well understood drug and small doses really do seem to help people with COPD.

PKA, PKB and PKC are likely at the core of most people’s autism.  Many existing therapies can modify their expression.

Whole genome sequencing, carried out at great precision, is clearly the only satisfactory genetic testing method.  The other, cheaper, methods are just missing key data and giving many false negative results, i.e. saying there are no identifiable genetic dysfunctions, when this is not true.







Monday 23 March 2015

“Epigenopathies” in Autism and Epigenetic Therapy in Current Use - Part 1








Today’s post is about epigenetics, a complex area of science, that has been touched upon in previous posts.

Since none of us are experts in genetics we will focus on the application of epigenetics rather than going into the excruciating details.  Skip over any parts that get too technical. Some of the interesting studies, that are of more academic interest, I will put in a later post.

Epigenetics is just one way in which gene expression (whether genes are turned on or off) can be altered.  There are other ways, which may be equally important. It is evident that epigenetics plays a role in many conditions including autism, schizophrenia, inflammation, asthma, COPD and cancer.

Even based on today’s highly superficial review, there is an immediate, practical, therapeutic prospect, worthy of investigation.  Thanks to Professor Peter Barnes in London and again those irrepressible researchers in Tehran, who were actually trialing theophylline for entirely different reasons.

You do need some basic definitions to understand what is going on in epigenetics, but in essence epigenetic changes are just like bookmarks.


DNA

DNA is a molecule that encodes the genetic instructions used in the development and functioning of all known living organisms.

The problem with DNA is that there is a lot of it.  It has to be very tightly packed since it has to fit inside every cell in your body.  In order to tightly fold up all that DNA you need Chromatin.


Chromatin

Chromatin is a complex of macromolecules found in cells, consisting of DNA, protein and RNA. The primary functions of chromatin are to:-

1) Package DNA into a smaller volume to fit in the cell
2) Reinforce the DNA macromolecule to allow mitosis
3) Prevent DNA damage
4) Control gene expression and DNA replication.

The primary protein components of chromatin are histones that compact the DNA.


Epigenetics – book marks on your DNA

Rather like you might stick post-it notes on your cookery book, or science text book, your body has various mechanism to highlight specific genes.  In effect these bookmarks turn on, or turn off that gene.

So in the jargon:-

Epigenetic changes involve non genetic changes in chromatin structure resulting in changes in gene expression

The important thing to note is that we are not talking about genetic defects, mutations, CNVs etc. which are usually what you might think about.

We all have these epigenetic markers and they are subject to change. Some of these markers become fixed and can then be inherited.  So if your ancestor lived/worked in a highly polluted place, you might have inherited some of his/her DNA tags/bookmarks, this would affect how your genes are expressed today.

The problem occurs when these markers get stuck, or are in the wrong place.  Imagine having a bookmark to remind you how long to roast your chicken and instead it takes you to the page with the recipe for pancakes.

In some inflammatory diseases, like COPD, the “good” genes are turned off and the “bad” genes have got stuck turned on.


Epigenetic change is reversible

Whereas genetic defects are irreversible, epigenetic changes are potentially reversible.  You just need to figure out how to rub them out.


Epigenetic Mechanisms

Just as you might use a variety of objects to mark pages in a book, so nature employs multiple methods to tag your DNA.


1.     DNA methylation

In this process the tag is a methyl group (CH3); to silence the bad gene you add more tags (Stimulate methylation).  To reverse a good gene that has been silenced, remove the tags (use a DNA methyltransferase inhibitors e.g. azacytidine)

Applicable to lung cancer & inflammation
Problems of specificity and targeting


I could only find a current methylation epigenetic therapy for schizophrenia:-




Recently, Satta et al. reported that nicotine decreases DNMT1 expression in GABAergic mouse neurons leading to decreased methylation at the GAD67 promoter and increased GAD67 protein expression. This effect was found to occur as a result of nicotinic receptor agonism. These improve cognitive functioning in schizophrenia, and may suggest in part why 80% of schizophrenia patients use tobacco. The specific nicotinic receptors that mediate this improved cognition have yet to be established. However, an alpha7-nicotine receptor agonist has been shown in small studies to improve cognition in schizophrenia subjects.



2. Histone modification 

Histones are the chief protein components of chromatin, acting as spools around which DNA winds.

There are several types of histone modification, that act as tags on your DNA:-

·        Lysine methylation
·        Arginine methylation
·        Lysine acetylation
·        Serine/Threonine/Tyrosine phosphorylation


The most studied variant is acetylation, this involves the addition or removal of acetyl groups (O=C-CH3)


INHIBITORS

In medicine a group of drugs already exists, called Histone Deacetylase inhibitors (HDAC inhibitors, HDIs).  HDIs are a class of compounds that interfere with the function of histone deacetylase.

HDIs have a long history of use in psychiatry and neurology as mood stabilizers and anti-epileptics. More recently they are being investigated as possible treatments for cancers, parasitic and inflammatory diseases.

The prime example of this is valproic acid, marketed as a drug under the trade names Depakene, Depakote, and Divalproex. In more recent times, HDIs are being studied as a mitigator for neurodegenerative diseases such as Alzheimer's disease and Huntington's disease.  Enhancement of memory formation is increased in mice given the HDIs sodium butyrate or SAHA.  While that may have relevance to Alzheimer's disease, it was shown that some cognitive deficits were restored in actual transgenic mice that have a model of Alzheimer's disease (3xTg-AD) by orally administered nicotinamide, a competitive HDI of Class III sirtuins.



Autism and HDIs 

There is research in mouse models showing that HDIs can improve autism.

Readers of this blog who are using the Supersprouts broccoli powder may not realize that the Sulforaphane produced, is a potent HDI (Histone Deacetylase Inhibitor).

In the autism world, the HDI research is still generally on mice, where social cognition is seen to improve.




Follow up study by Foley:-


In utero exposure of rodents to valproic acid (VPA) has been proposed to induce an adult phenotype with behavioural characteristics reminiscent of those observed in autism spectrum disorder (ASD). Our previous studies have demonstrated the social cognition deficits observed in this model, a major core symptom of ASD, to be ameliorated following chronic administration of histone deacetylase (HDAC) inhibitors. Using this model, we now demonstrate pentyl-4-yn-VPA, an analogue of valproate and HDAC inhibitor, to significantly ameliorate deficits in social cognition as measured using the social approach avoidance paradigm as an indicator of social reciprocity and spatial learning to interrogate dorsal stream cognitive processing. The effects obtained with pentyl-4-yn-VPA were found to be similar to those obtained with SAHA, a pan-specific HDAC inhibitor. Histones isolated from the cerebellar cortex and immunoblotted with antibodies recognising lysine-specific modification revealed SAHA and pentyl-4-yn-VPA to enhance the acetylation status of H4K8. Additionally, the action of pentyl-4-yn-VPA, could be differentiated from that of SAHA by its ability to decrease H3K9 acetylation and enhance H3K14 acetylation. The histone modifications mediated by pentyl-4-yn-VPA are suggested to act cooperatively through differential acetylation of the promoter and transcription regions of active genes.



ACTIVATORS

Histone modification is also implicated in inflammation.  We know that Autism is an inflammatory condition and of course we know which are the much better studied inflammatory conditions.

In terms of the brain, schizophrenia and even sometimes ADHD are better studied.

In the rest of the body arthritis, asthma and COPD are interesting.  Thanks to Peter Barnes at Imperial College, the COPD research is again leading the way.

COPD is like a severe drug resistant form of asthma.  Barnes has almost completely figured out the mechanism and how to best treat it.  One of the findings is to use a common drug called Theophylline in low doses as a HDAC activator.



The usual modes of action of Theophylline are:-

1.     competitive nonselective phosphodiesterase inhibitor, which raises intracellular cAMP, activates PKA, inhibits TNF-alpha  and inhibits leukotriene  synthesis, and reduces inflammation and innate immunity

2.     nonselective adenosine receptor antagonist


The usual dosage involves concentration of 10-20 micrograms/mL blood.  At this level there can be some side effects.

Barnes found that at sub-therapeutic doses (<8 micrograms/mL) , Theophylline actually has a different mode of action; it behaves as a HDAC activator; because the other modes of action were no longer present, no longer were their side effects.  He also showed that as the dose increases, the HDAC activation actually fades.  Another case of less being more.

Once deacetylated, DNA is repackaged so that the promoter regions of inflammatory genes are unavailable for binding of transcription factors such as NF-κB that act to turn on inflammatory activity. It has recently been shown that the oxidative stress associated with cigarette smoke can inhibit the activity of HDAC2, thereby blocking the anti-inflammatory effects of corticosteroids.)

Theophylline is a novel form of adjunct therapy in improving the clinical response to steroids in smoking asthmatics and people with COPD (some of whom do never smoked).


By using a low dose of Theophylline, steroid medication became much more effective allowing lower doses of steroids to be used.

Below is a presentation and one of Barnes’ many papers on this subject:-



Targeting the epigenome in the treatment of asthma and chronicobstructive pulmonary disease.

Abstract

Epigenetic modification of gene expression by methylation of DNA and various post-translational modifications of histones may affect the expression of multiple inflammatory genes. Acetylation of histones by histone acetyltransferases activates inflammatory genes, whereas histone deacetylation results in inflammatory gene repression. Corticosteroids exert their anti-inflammatory effects partly by inducing acetylation of anti-inflammatory genes, but mainly by recruiting histone deacetylase-2 (HDAC2) to activated inflammatory genes. HDAC2 deacetylates acetylated glucocorticoid receptors so that they can suppress activated inflammatory genes in asthma. In chronic obstructive pulmonary disease (COPD), there is resistance to the anti-inflammatory actions of corticosteroids, which is explained by reduced activity and expression of HDAC2. This can be reversed by a plasmid vector, which restores HDAC2 levels, but may also be achieved by low concentrations of theophylline. Oxidative stress causes corticosteroid resistance by reducing HDAC2 activity and expression by activation of phosphoinositide-3-kinase-delta, resulting in HDAC2 phosphorylation via a cascade of kinases. Theophylline reverses corticosteroid resistance by directly inhibiting oxidant-activated PI3Kdelta and is mimicked by PI3Kdelta knockout or by selective inhibitors. Other treatments may also interact in this pathway, making it possible to reverse corticosteroid resistance in patients with COPD, as well as in smokers with asthma and some patients with severe asthma in whom similar mechanisms operate. Other histone modifications, including methylation, tyrosine nitration, and ubiquitination may also affect histone function and inflammatory gene expression, and better understanding of these epigenetic pathways could led to novel anti-inflammatory therapies, particularly in corticosteroid-resistant inflammation.


COPD and Autism

COPD is not autism, but there are some similarities.  Both conditions are associated with chronic oxidative stress and inflammation.

The antioxidant NAC is effective in both conditions.

The Nrf2 activator Sulforaphane (from broccoli) is being trialed for both conditions and is shown effective in much autism.

Inhaled steroids keep people with COPD alive, and oral steroids are beneficial to many people with autism.  Their use in autism is severely limited by side effects of long term oral steroid use.

Some HDI drugs improve autism and some HDI drugs improve COPD.

It would seem that the Epigenopathies of autism and COPD may well overlap.  Could the COPD epigenetic therapy be effective in some autism?

  

Theophylline for Neurological Disorders?

You might have realized that epigenetic therapy should be highly focused, since some genes need to be switched on while others need to be switch off.

Nonetheless that natural question to ask is what is the effect of Theophylline on neurological disorders like autism.

I cannot answer that question; but we can see the effect on ADHD (autism-lite).

It should be noted that the below trial was nothing related to epigenetics and the dosage was the more typical high dosage.  The histone modifying (epigenetic) effect would have been greater at a slightly lower dosage.

At these doses Theophylline would act as a mild stimulant;  note that Theophylline is very closely related to caffeine.  Somewhat counter-intuitively, psychiatrists treat hyperactive people with stimulants.




A total of 32 children with ADHD as defined by DSM IV were randomized
to theophylline and methylphenidate dosed on an age and weight-adjusted basis at 4 mg/kg/day (under 12 years) and 3 mg/kg/day theophylline
(over 12 years) (group 1) and 1 mg/kg/day methylphenidate
(group 2) for a 6-week double-blind and randomized clinical trial. The principal measure of the outcome was the Teacher and Parent ADHD Rating Scale. Patients were assessed by a child psychiatrist, at baseline and at 14, 28 and 42 days after start of the medication.

The results suggest that theophylline may be a useful for the treatment of ADHD. In addition, a tolerable side-effect profile is one of the advantages of theophylline in the treatment of ADHD.



In autism it would be nice if somebody made a trial with 2mg/kg


Let us digress a little and see just what is Theophylline:-


Theophylline is naturally found in cocoa beans. Amounts as high as 3.7 mg/g have been reported in Criollo cocoa beans.

Trace amounts of theophylline are also found in brewed tea, although brewed tea provides only about 1 mg/L, which is significantly less than a therapeutic dose.


As a member of the xanthine family, it bears structural and pharmacological similarity to theobromine and caffeine


Derivatives of xanthine (known collectively as xanthines) are a group of alkaloids commonly used for their effects as mild stimulants and as bronchodilators, notably in the treatment of asthma symptoms. In contrast to other, more potent stimulants like sympathomimetic amines, xanthines mainly act to oppose the actions of the sleepiness-inducing adenosine, and increase alertness in the central nervous system. They also stimulate the respiratory centre, and are used for treatment of infantile apnea. Due to widespread effects, the therapeutic range of xanthines is narrow, making them merely a second-line asthma treatment. The therapeutic level is 10-20 micrograms/mL blood; signs of toxicity include tremor, nausea, nervousness, and tachycardia/arrhythmia.


Theophylline degrades to caffeine.



Inhibitor or Activator of HDAC ?

You may be wondering why we would want an HDAC activator for autism, if we know that Sulforaphane (broccoli) does just the opposite; it is an inhibitor.  The reason is that we have made a few simplifications in the science; there are many types of HDAC, and you might need an inhibitor of one type of HDAC and an activator of another.  Worse still, you might need something on one part of your body and something quite different in another part.

The HDACs can be divided into 3 classes based on their structure and sequence homology: class I consists of HDACs 1, 2, 3, 8, and 11; class II includes HDACs 4, 5, 6, 7, 9, and 10; and class III enzymes are HDACs originally found in yeast and include Sir2-related proteins. Increased HDAC activity and expression are common in many cancers and can result in repression of transcription that results in a deregulation of differentiation, cell cycle, and apoptotic mechanisms. Moreover, tumor suppressor genes, such as p21 appear to be targets of HDACs and are “turned off” by deacetylation. Prostate cancer cells also exhibit aberrant acetylation patterns. The use of class I and class II HDAC inhibitors in cancer chemoprevention and therapy has gained substantial interest.

   
Epigenopathies

When the epigenetic bookmarks appear in the wrong place, trouble will follow.  Genes that should be “off” are turned on and vice versa.

These events have recently been a new name “Epigenopathies”

Just as we can look at many dysfunctions in autism as Channelopathies; those dysfunctions in ion channels and ion transporters, we will be able to consider others as Epigenopathies.

Who first came up with this terminology is not certain, but it might be a clever Frenchman called Mark Millan who works at the Unit for Research and Discovery in Neuroscience, Institut de Recherches Servier, beside the river Seine.

The good news is that here is a very clever neuroscientist with an interest in autism, but not obsessed by it.

France generally has quite an old fashioned view of autism, you will not find much in the way of ABA in France, and the State is certainly not going to be the one paying for it.




Millan nicely summarizes the implications:-

Neurodevelopmental Disorders (NDDs) are accompanied by aberrant "epigenetic" regulation of processes critical for normal and orderly development of the brain. Epigenetics refers to potentially-heritable (by mitosis and/or meiosis) mechanisms controlling gene expression without changes in DNA sequence. In certain NDDs, prototypical epigenetic processes of DNA methylation and covalent histone marking are impacted. Conversely, others involve anomalies in chromatin-modelling, mRNA splicing/editing, mRNA translation, ribosome biogenesis and/or the regulatory actions of small nucleolar RNAs and micro-RNAs. Since epigenetic mechanisms are modifiable, this raises the hope of novel therapy …


In the next post on epigenetics we will look at the research that is specific to  neurodevelopmental disorders.  It is interesting, but does not really have any obvious therapeutic implications.  One point I will highlight in this current post is the following:-

ASD is not associated with systemic differences in global DNA methylation



What this means is that, as far as one key type of epigenetics is concerned, autism is not characterized by too many or too few epigenetic tags; the problem is that they are not all in the right place.  Many alternative therapies in autism are rather simplistic.  It is not a case of too much methylation, or too little.

In the twin study the ASD Twin and his unaffected sibling has almost the same amount of total DNA methylation.