Showing posts with label DHEA. Show all posts
Showing posts with label DHEA. Show all posts

Monday 4 November 2013

Central Serotonergic Hypoactivity in Autism & Degradation of Tryptophan

Today’s post has an impressive title and a year ago I would not have understood it, but it summarizes exactly what may be going on inside the autistic brain.  It fits into the wider puzzle of hormonal imbalances in autism that then manifest themselves into behaviours ranging from qwerky to extreme self-injury.

Human emotions and behaviours are influenced by parallel signals from the nervous system (i.e. the brain) and the endocrine system.  The two systems are interconnected and so your state of mind in controlled by hormones that you cannot directly control and the nervous system which you can learn to control.  For example, you can make yourself happy, unhappy, or depressed with the power of your mind.  You can train yourself to overcome fear.  Some people are clearly very much better at doing this than others; but the potential to do so lies within all of us, autistic or neurotypical.  This also explains why singing makes you happy and rapidly reduces cortisol, your stress hormone, as we learnt in an earlier post.
So on the one hand we need to understand any in-built hormonal disturbances in autism and then see how to best tackle them using the hormonal system and the nervous system.  This may sound like fantasy but the more you learn about it, the more plausible it becomes.

Most people have heard of Serotonin; it is frequently thought of as the “happy hormone”.

As we have learnt in this blog, the human body is not like any man-made invention, it seems to function in quite irrational ways.  Serotonin is found mainly in the intestines and less than 10% is in the brain (and CNS), but it is not the same serotonin.  Serotonin cannot cross the blood brain barrier.  In autism serotonin in the blood (produced in the intestines) tends to be elevated, but the level of serotonin in the brain appears to be reduced.  So there appears to be a failure in the entire serotonin system, the one for the brain and the one for the blood.
Drugs that lower brain serotonin are often used to treat the symptoms of autism.  Even Temple Grandin admits (on her own website) to being on a low dose of Prozac to control her anxiety.  In spite of a long list of side effects, many children with ASD living in the US are prescribed this serotonin lowering drug.  Prozac is a heavily prescribed antidepressant drug and is a selective serotonin reuptake inhibitor (SSRI).

Somewhat bizarrely, Prozac is linked to an increase in suicidal tendencies.  As is often the case, many drugs have secondary or tertiary modes of action; you will experience all of them.
In the language of your doctor, low brain serotonin would be called central serotonergic hypoactivity, but don’t go asking him to test it, because he cannot.  All he can do is measure the level of serotonin in the blood or urine, and probably tell you that it is slightly elevated and not to worry.

Researchers have known about this serotonin paradox in autism for many years.  To my surprise a researcher at Yale University even made a mathematical model to better understand it. 

Since the early 1960s, the most consistent pathophysiological finding in autistic individuals has been their statistically elevated blood 5-hydroxytryptamine (5-HT, serotonin) levels. However, many autistic individuals have normal blood 5-HT levels, so this finding has been difficult to interpret. The serotonin transporter (SERT) controls 5-HT uptake by blood platelets and has been implicated in autism, but recent studies have found no correlation between SERT polymorphisms and autism. Finally, autism is considered a brain disorder, but studies have so far failed to find consistent serotonergic abnormalities in autistic brains. A simple mathematical model may account for these paradoxes, if one assumes that autism is associated with the failure of a molecular mechanism that both regulates 5-HT release from gut enterochromaffin cells and mediates 5-HT signaling in the brain. Some 5-HT receptors may play such a dual role. While the failure of such a mechanism may lead to consistent abnormalities of synaptic transmission with no alteration of brain 5-HT levels, its effects on blood 5-HT levels may appear paradoxical.

 The figure below sums up what appears to be going wrong.

A great all-in-one overview
If you only want to read one paper on serotonin and autism, and one that is not too science heavy, the one for you is:-

If you have more interest, then read on …

Research on Serotonin in the Autistic Brain
A recurring problem in all brain research is the lack of physical samples.  You cannot just open up someone's head and take a brain biopsy.  Research is either carried out on the tiny number of autistic brains donated to medical research, or it is non-invasive (MRIs and EEGs etc.), or it is very indirect.  An example of this latter type is the following paper from Belgium, home of kriek, a beer made from cherries and French fries served with mayonnaise.

"Some studies have suggested that disorders in the central serotonergic function may play a role in the pathophysiology of autistic disorder. In order to assess the central serotonergic turnover in autism, this study examines the cortisol and prolactin responses to administration of L-5-hydroxy-tryptophan (5-HTP), the direct precursor of 5-HT in 18 male, post-pubertal, Caucasian autistic patients (age 13-19 y.; I.Q.>55) and 22 matched healthy volunteers. Serum cortisol and prolactin were determined 45 and 30 minutes before administration of 5-HTP (4 mg/kg in non enteric-coated tablets) or an identical placebo in a single blind order and, thereafter, every 30 minutes over a 3-hour period. The 5-HTP-induced increases in serum cortisol were significantly lower in autistic patients than in controls, whereas there were no significant differences in 5-HTP-induced prolactin responses between both study groups. In baseline conditions, no significant differences were found in serum cortisol and prolactin between autistic and normal children. The results suggest that autism is accompanied by a central serotonergic hypoactivity and that the latter could play a role in the pathophysiology of autism."
Tryptophan and DHEA
Just to complicate things a little further, I now introduce you to Tryptophan and DHEA.

Tryptophan is an essential amino acid, meaning that it is essential for human life, cannot be synthesized by the organism, and therefore must be part of your diet.
Tryptophan functions as a biochemical precursor for the following compounds:

The disorders fructose malabsorption and lactose intolerance cause improper absorption of tryptophan in the intestine, reduced levels of tryptophan in the blood and depression

What you will not find on Wikipedia, is that perhaps Tryptophan is in fact also a bona fide neurotransmitter in its own right.

Tryptophan as an evolutionarily conserved signal to brain serotonin: molecular evidence and psychiatric implications.


The role of serotonin (5-HT) in psychopathology has been investigated for decades. Among others, symptoms of depression, panic, aggression and suicidality have been associated with serotonergic dysfunction. Here we summarize the evidence that low brain 5-HT signals a metabolic imbalance that is evolutionarily conserved and not specific for any specific psychiatric diagnosis. The synthesis and neuronal release of brain 5-HT depends on the concentration of free tryptophan in blood and brain because the affinity constant of neuronal tryptophan hydroxylase is in that concentration range. This relationship is evolutionarily conserved. Degradation of tryptophan, resulting in lower blood levels and impaired cerebral production and release of serotonin, is enhanced by inter alia inflammation, pregnancy and stress in all species investigated, including humans. Consequently, tryptophan may not only serve as a nutrient, but also as a bona fide signaling amino acid. Humans suffering from inflammatory and other somatic diseases accompanied by low tryptophan levels, exhibit disturbed social behaviour, increased irritability and lack of impulse control, rather than depression. Under particular circumstances, such behaviour may have survival value. Drugs that increase brain levels of serotonin may therefore be useful in a variety of psychiatric disorders and symptoms associated with low availability of tryptophan. 

This paper is open access, it gets quite technical but here is a summary of the conclusion. 

Our findings support a possible mitochondrial dysfunction as a result of impaired tryptophan metabolism in cells from patients with ASDs
Although approximately 99% of the dietary tryptophan intake is metabolized via the kynurenine pathway, tryptophan is also the main precursor for both serotonin and melatonin
Melatonin plays a critical role in the regulation of the circadian rhythm, and anomalies of this rhythm have been associated with some of the signs in the autistic spectrum, like seizures or sleep disorders
Serotonin is a neurotransmitter involved in multiple aspects of brain functions, ranging from the regulation of mood to the control of appetite and social interactions and its production has been reported as deficient in ASD brains.
Tryptophan levels have been demonstrated to directly influence central nervous system (CNS) serotonin levels and behavior, and altered tryptophan transport has been described in fibroblasts from boys with attention deficit/hyperactivity disorder (ADHD)
Patients with ASDs, on average, are less capable of utilizing tryptophan as an energy source than controls.
Decreased tryptophan metabolism in patients with ASDs may alter metabolic pathways involved in the regulation of the early stages of brain development (first month of gestation), mitochondrial homeostasis and immune system activity in the brain.
Disruption of such pathways can primarily be caused either by insufficient serotonin production by placental cells, mitochondrial dysfunction and/or impaired balance between quinolinic and kynurenic acid in fetal cells. The combined effects of these events could lead to abnormal organization of neurons , particularly in specific brain regions, determining the imbalance between the short- and long-term circuitry that has been considered to be one of the fundamentals of the ASD neuropathology
Even though the ideal target tissue, brain, could not be investigated, our observation of decreased tryptophan metabolism in cells from patients with ASDs may provide a unifying model that could help explain the genetic heterogeneity of ASDs.
Tryptophan is a precursor of important compounds, such as serotonin, quinolinic acid, and kynurenic acid, which are involved in neurodevelopment and synaptogenesis. In addition, quinolinic acid is the structural precursor of NAD+, a critical energy carrier in mitochondria. Also, the serotonin branch of the tryptophan metabolic pathway generates NADH. Lastly, the levels of quinolinic and kynurenic acid are strongly influenced by the activity of the immune system. Therefore, decreased tryptophan metabolism may alter brain development, neuroimmune activity and mitochondrial function. Our finding of decreased tryptophan metabolism appears to provide a unifying biochemical basis for ASDs and perhaps an initial step in the development of a diagnostic assay for ASDs.

DHEA  (didehydroepiandrosterone) It is the most abundant circulating steroid in humans, importantly for us to know it is also produced in the brain.  It has a variety of potential biological effects in its own right, binding to an array of nuclear and cell surface and acting as a neurosteroid.

Faulty serotonin--DHEA interactions in autism: results of the5-hydroxytryptophan challenge test. 



Autism is accompanied by peripheral and central disorders in the metabolism of serotonin (5-HT). The present study examines plasma dehydroepiandrosterone-sulphate (DHEA-S) and the cortisol/DHEA-S ratio following administration of L-5-hydroxytryptophan (5-HTP), the direct precursor of 5-HT, to autistic patients.


Plasma DHEA-S levels were determined both before and after administration of 5-HTP or placebo, on two consecutive days in a single blind order in 18 male autistic patients and 22 matched healthy controls.


The 5-HTP-induced DHEA-S responses were significantly higher in autistic patients than in controls. In baseline conditions, the cortisol/DHEA-S ratio was significantly higher in autistic patients than in controls. Discussion: The results suggest that autism is accompanied by a major disequilibrium in the serotonergic system. The increased Cortisol (neurotoxic) versus DHEA-S (neuroprotective) ratio suggests that an increased neurotoxic potential occurs in autism.


It is concluded that disequilibrium in the peripheral and central turnover of serotonin and an increased neurotoxic capacity by glucocorticoids are important pathways in autism.
Mice Studies
For the mice lovers amongst you, they also get their vitamin P (Prozac).

Serotonin Defects Identified in "Autistic" Mice

Serotonin modulators mitigate some BTBR behaviors
The researchers tested the effects of acute doses of fluoxetine (Prozac) (an SERT blocker), risperidone (a 5-HT2A receptor antagonist), and buspirone (a partial 5-HT1A receptor agonist) on social and repetitive behaviors of BTBR mice. These three compounds regulate serotonin activity and have inconsistent, limited, and sometimes harmful effects in rodent models of and people with autism. Only buspirone and fluoxetine were found to make BTBR mice significantly more social: treated mice spend proportionally more time socializing with a strange mouse than do saline-treated controls. Interestingly, BTBR mice treated with either buspirone or fluoxetine show a reduced interest in social novelty: when introduced to a second stranger mouse, they do not show a preference for either stranger. In contrast, the saline-treated controls spend more time investigating the newer mouse. Compared to either buspirone- or fluoxetine-treated mice and saline-treated controls, Risperidone-treated mice spend less time investigating strange mice and novel surroundings.
Regardless of treatment, BTBR mice spend comparable amounts of time burying marbles (an index of repetitive behavior). However, eliminating from the analysis one saline-treated control that did not bury any marbles suggests that risperidone-treated mice bury significantly fewer marbles than the saline-treated controls.
In summary, Daws and her team concluded that the autism-like behaviors of BTBR mice are likely due in part to an altered hippocampal SERT serotonin transporter and/or an altered 5-HT1A serotonin receptor. These findings may lead to the identification of additional therapeutic targets for treating human autism.
There was a lot of science in this post and it was clear that the mechanisms involved are only very partially understood by researchers.
It is clear that interventions increasing central (brain) serotonin levels are likely to reduce autistic behaviours.  Prozac was mentioned, but there is a much wider class of drugs called serenic, many of which could potentially be helpful.  As mentioned earlier, the big problem with most of the drugs created for psychiatrists is side effects.  Autism is supposed to be very common, but you would not think so by looking at way new drugs are developed.  As a result, the drugs currently used in ASD and the majority of those in the pipeline are ones developed for other conditions (depression, bi-polar, psychosis , anxiety, ADHD, schizophrenia, Alzheimer’s etc.) many of which share some similar characteristics, but are essentially different conditions, with the exception of ADHD.  It is akin to trying to fix your Ford car with a parts bin filled with Toyota components; it is possible, but not a wise idea.
In my opinion, all the hormone dysfunctions in autism can eventually be traced back to damage caused by oxidative stress and neuroinflammation.  The brain has just adjusted to find a new homeostasis, which happens to be an autistic one.  The list of metabolic disturbances in autism is long and getting longer; but they are just consequences.  I very much doubt it is ever going to be possible to go hormone by hormone, neurotransmitter by neurotransmitter “correcting” them.   I think the best solution is to go further back up the chain and look at how hormones and neurotransmitters themselves are jointly regulated.  I do not believe anyone fully understands the molecular basis on which this is carried out, but as I have pointed out earlier in this blog, you can get the right answer for the wrong reasons and also without showing your workings.  As long as it works, perhaps understanding why does not matter.  A much less intellectual approach might indeed prove effective.
I will continue with my problem solving, but less intellectual, approach and see where it leads.

Just to show how all the hormones are interrelated, I added the paper below from Japan.  They investigate the relationship between Oxytocin and Serotonin:

Evidence That Oxytocin Exerts Anxiolytic Effects via Oxytocin Receptor Expressed in Serotonergic Neurons in Mice

"It is thus possible that oxytocin modulates not only anxiety-related behavior but also social behavior via serotoninergic transmission. These observations may provide new insights into psychiatric disorders associated with disruptions in social and emotional behavior, including autism, anxiety disorders, and depression."