Today’s post was driven by another attempt not to take a statin.
Statins are
among the world’s most prescribed, and yet most maligned, drugs. Hundreds of millions of people take a statin
drug every day to lower their cholesterol, but a small, vocal minority
complain about muscle pains, memory loss and even type 2 diabetes.
Since my
Polypill is evidently a therapy, and not a cure, for autism, the odds are that
it will be needed life-long. Regardless
of the apparent lack of side-effects, nobody should be taking drugs/supplements
that are not really needed. Atorvastatin (Lipitor/Sortis) is part of my Polypill for the type of autism affecting Monty, aged 11, with ASD.
Every time I
stop the statin part of my Polypill therapy, I end up starting it again after only
a one day break. I notice all sorts of
little behavioral changes that I really do not want to see.
These
changes involve loss of initiative, flexibility and motivation. I really do not see how these would be
measured in any existing behavioral assessment of autism. These little changes make a big difference in
daily life, so-called adaptive behavior.
In case you
are wondering, the types of people with autism that I think might benefit from
statins, have high cholesterol and some of the following:-
·
Non-verbal,
or people who are slightly verbal, but choose not to speak
·
Poor
ability to generalize skills already mastered in 1:1 therapy
·
Great
difficulty in separating
·
Great
difficulty in coping with change
As with some
other elements of the Polypill, there are numerous reasons why statins
could/should help in autism. Today I
found yet another one and an interesting non-drug alternative.
Why
Statins?
I originally
choose statins as a possible therapy, based on their ability to control pro-inflammatory
cytokines (e.g. cytokine storms), and their known neuro-protective properties (e.g.
reduce mortality after a traumatic brain injury).
I did also
note that statins were being researched to treat Neurofibromatosis, a single
gene condition that is frequently comorbid with an “autism” diagnosis.
Today’s post
is really about why statins should help in Neurofibromatosis and what else
shares the same mechanism of action.
Putting aside
cytokines, PTEN and BCL-2, this new mechanism (excessive RAS/ERK signaling) might
also be active in broader autism and Intellectual Disability / MR.
The other
recent development was a study at UCLA that looked at a rare condition called Noonan Syndrome. Noonan Syndrome and Neurofibromatosis are members of a group of conditions called RASopathies.
The RASopathies
are developmental syndromes caused by mutations in genes that alter the Ras subfamily
and Mitogen-activated protein kinases
that control signal transduction.
Drawing upon Silva’s
previous research on neurofibromatosis 1, another Ras-influenced disease,
the UCLA team treated the mice with lovastatin, an FDA-approved statin drug
currently in wide clinical use.
When adult mice with Noonan were treated
with lovastatin in the UCLA study, the drop in Ras activity dramatically improved their memory and ability
to remember objects and navigate mazes.
“We were amazed to see that statin treatment restored the adult animals’
cognitive functions to normal. Traditionally, science assumes that
therapy needs to start in the fetal stage to be effective,” explained Silva. “Our research suggests that the
leading gene mutation responsible for Noonan syndrome plays critical roles not
only in fetal development, but also in how well the adult brain functions.”
According to Silva, UCLA’s approach could help the estimated 35
million Americans who struggle with learning disabilities
The paper itself:-
RAS/ERK Inhibitors
For those of
you more interested in the implications, rather than the science, here they
are.
Known RAS
inhibitors include:-
· Statins, the popular cholesterol reducing drugs. The “lipophilic” statins (Simvastatin, Lovastatin, Atorvastatin) can cross the blood brain barrier
·
Farnesyltransferase inhibitors, these are mainly anti-cancer
research compounds, but one is the flavonoid Gingerol
Gingerol, is the
active constituent of fresh ginger. It is normally found as a pungent yellow oil,
but also can form a low-melting crystalline solid.
Cooking ginger transforms gingerol into zingerone,
which is less pungent and has a spicy-sweet aroma. When ginger is dried,
gingerol undergoes a dehydration reaction forming shogaols,
which are about twice as pungent as gingerol. This explains why dried ginger is
more pungent than fresh ginger.
Ginger also contains 8-gingerol, 10-gingerol,
and 12-gingerol.
Physiological effects
Gingerol seems to be effective in an animal
model of rheumatoid arthritis.
Gingerol has been investigated for its effect
on cancerous tumors in the bowel, breast tissue, ovaries, the pancreas, among
other tissues, with positive results.
Neurofibromatosis, Behavioral
dysfunction and RAS signaling
Neurofibromatosis Type 1: Modeling CNS Dysfunction
Neurofibromatosis type 1 (NF1) is the most common monogenic
disorder in which individuals manifest CNS abnormalities. Affected individuals
develop glial neoplasms (optic gliomas, malignant astrocytomas) and neuronal
dysfunction (learning disabilities, attention deficits). Nf1 genetically engineered mouse
models have revealed the molecular and cellular underpinnings of gliomagenesis,
attention deficit, and learning problems with relevance to basic neurobiology.
Using NF1 as a model system, these studies have revealed critical roles for the
NF1 gene in non-neoplastic cells in
the tumor microenvironment, the importance of brain region heterogeneity, novel
mechanisms of glial growth regulation, the neurochemical bases for attention
deficit and learning abnormalities, and new insights into neural stem cell
function. Here we review recent studies, presented at a symposium at the 2012
Society for Neuroscience annual meeting, that highlight unexpected cell biology
insights into RAS and cAMP pathway effects on neural progenitor signaling,
neuronal function, and oligodendrocyte lineage differentiation.
Working memory, which, like attention, depends on intact prefrontal
circuitry, is also impaired in both Nf1+/− mice and in
individuals with NF1. Functional imaging studies showed that the working memory
impairments of NF1 subjects correlated with hypoactivation in the prefrontal
cortex, which may reflect increased GABA-mediated inhibition in prefrontal
cortical circuits of Nf1+/− mice. Remarkably, a dose of a GABA receptor inhibitor
(picrotoxin), which caused deficits in working memory in control mice, rescued
the working memory deficits of Nf1+/− mice, a result
consistent with the hypothesis that increased inhibition is at the root of the
working memory deficits associated with NF1.
Increases in RAS/ERK signaling
in Nf1+/− mice have been implicated in the working memory,
attention, and spatial learning deficits of these mice. Genetic and pharmacological
manipulations that target the RAS/ERK signaling pathway were shown to rescue
the physiological and behavioral deficits of Nf1+/− mice. Importantly, pharmacological
manipulations that impair the isoprenylation of RAS (statins, farnesyl transferase
inhibitors), and therefore decrease the levels of RAS/ERK signaling, also
rescue key electrophysiological and behavioral phenotypes of Nf1+/−
mice. Indeed, at concentrations that do not affect signaling,
physiology, or behavior of wild-type controls, statins reverse the signaling, electrophysiological,
attention, and spatial learning deficits of Nf1+/− mice.
Prompted by these findings, clinical studies are currently underway to test the
efficacy of statins as a treatment for the behavioral and cognitive deficits in
individuals with NF1.
Similar to individuals with NF1, Nf1 mutant mice also show
attention deficits. These deficits are thought to be key contributors to
academic and social problems in children with NF1. Using an additional Nf1
GEM strain to study attention, in which the Nf1+/− mutation
is combined with Cre-driven homozygous Nf1 gene deletion in
GFAP-expressing cells (Nf1 OPG mouse), it was found that reduced
striatal dopamine was responsible for the observed attention deficits.
Treatment with methylphenidate (but not with drugs that affect RAS) reversed
the attention deficits of these Nf1 OPG mutants, suggesting that defects in brain catecholamine
homeostasis contribute to the attention deficits observed. These results
suggest that, in addition to drugs that affect RAS/ERK signaling, drugs that
manipulate dopaminergic function could also be used to treat the cognitive
deficits associated with NF1.
Treatments and future directions
With the availability of genetically engineered mouse models for
NF1-associated CNS pathology, it now becomes possible to envision a pipeline in
which fundamental basic science discoveries lead to the identification of new
cellular and molecular targets for therapeutic drug design, culminating in
preclinical evaluation before testing in patients with NF1. First, the success
of Nf1 mouse model implementation has already resulted in the clinical
evaluation of lovastatin
in children with NF1-associated learning deficits and rapamycin analogs for the
treatment of glioma. Second, mouse models afford an opportunity to envision
specific features of NF1 as distinct diseases defined by the timing of NF1
gene inactivation or the particular cell of origin. Similar to other cancers,
the identification of molecular or cellular subtypes of NF1-associated nervous
system tumors or learning/behavioral problems may result in more individualized
treatments with a higher likelihood of success. Third, as we further exploit
these powerful preclinical models, additional cellular and molecular targets
may emerge as candidates for future therapeutic drug design. In this regard,
one could envision more effective therapies resulting from the combined use of
targeted inhibition of multiple growth control pathways regulated by
neurofibromin in the neoplastic cell (NF1-deficient neuroglial
precursor) or dual targeting of non-neoplastic (microglia) and neoplastic cells
within NF1-associated CNS tumors.
RASopathies & Autism
Higher prevalence and severity of
autism traits in RASopathies compared to unaffected siblings suggests that
dysregulation of Ras/MAPK signalling during development may be implicated in
ASD risk. Evidence for sex bias and potential sibling correlation suggests that
autism traits in the RASopathies share characteristics with autism traits in
the general population and clinical ASD population and can shed light on
idiopathic ASDs.
This systematic study offers
empirical support that autism traits are associated with developmental Ras/MAPK
pathway dysregulation. It suggests that individuals affected by RASopathies
should be evaluated for social communication challenges and offered treatment
in these areas. This is the first strong evidence that multiple members of a
well-defined biochemical pathway can contribute to autism traits. Future
studies could explore potential modifying or epistatic factors contributing to
variation within the RASopathies and the role of Ras/MAPK activation in
idiopathic ASDs.
RAS/ERK Inhibitors
Inhibition of Ras for cancer treatment: the search continues
Discussion
Despite intensive effort, to date no
effective anti-Ras strategies have successfully made it to the clinic. We
present an overview of past and ongoing strategies to inhibit oncogenic Ras in
cancer.
Conclusions
Since approaches to directly target mutant
Ras have not been successful, most efforts have focused on indirect approaches
to block Ras membrane association or downstream effector signaling. While
inhibitors of effector signaling are currently under clinical evaluation,
genome-wide unbiased genetic screens have identified novel directions for
future anti-Ras drug discovery.
Conclusion
In some
people with “autism” statins are an effective therapy. Higher doses of statin are associated with
side effects. By knowing the principal mode
of action of statins in autism, we might be able to develop a more potent
therapy – STATIN PLUS.
On the basis
of today’s post, investigating Farnesyltransferase
inhibitors, as inhibitors of RAS signalling, looks an interesting option.
Gingerol is available as
an inexpensive, supposedly standardized, product. Ginger itself has been safely used in traditional
medicine for thousands of years.
Perhaps Gingerol is the
PLUS and for people unwilling to use a statin, perhaps Gingerol could be the
statin?
The current medical view
on ginger:-
Recent preliminary results in animals show some
effect in slowing or preventing tumor growth. While these results are not well
understood, they deserve further study. Still, it is too early in the research
process to say whether ginger will have the same effect in humans.
Note on Intellectual Disability / MR
Regular
readers may recall, I have commented that not only are many types of autism partially treatable, but so should be some types of Intellectual Disability / MR. This same theme about treating cognitive
dysfunction is raised in the paper below.
In the days
when most readers of this blog were at school, 30-50% of people with an autism
diagnosis were also diagnosed with Intellectual Disability / MR. This is no longer the case; as autism
diagnoses have skyrocketed in Western countries, diagnosis of Intellectual
Disability / MR has not followed it.
People born
today with what used to be called autism, often suffer from epilepsy and
impaired cognitive function. They do now
tend to get rather sidelined by the much wider scope of the “autism” diagnosis
used today, mainly in Anglo-Saxon countries (where most research is carried
out).
The point
where this matters is in clinical trials, since many of the milder autisms (now
even being called “quirky autism”) may be caused by entirely different
dysfunctions. The observational
diagnosis of “autism” is enough to enter most trials, but as we have seen in
this blog, autism is not a true diagnosis; it is merely a description of
symptoms. It is like going to the doctor
and saying “I think I might have a head ache” and after some questions, the
doctors sits back and says “yes, you have a headache”. You want to know why you have a head ache and
how to make it go away.
A fraction of the
cases of intellectual disability is caused by point mutations or deletions in
genes that encode for proteins of the RAS/MAP Kinase signaling pathway known as
RASopathies.
Here we examined the current understanding of the molecular mechanisms involved
in this group of
genetic disorders focusing in studies which provide evidence
that intellectual
disability is potentially treatable and curable. The evidence presented supports the idea that with
the appropriate understanding of the molecular mechanisms involved,
intellectual disability could be treated pharmacologically and perhaps
through specific mechanistic-based teaching strategies.