For many years, autism research has
focused primarily on neurotransmitters such as GABA and glutamate.
More recently, however, increasing attention has turned to another major
contributor to brain function: the immune system.
Numerous studies have reported
evidence of chronic microglial activation and elevated inflammatory cytokines
in at least a subset of autistic people. The obvious question has always been:-
Can
reducing neuro-inflammation improve the core features of autism?
A newly published study from
researchers at the University of Naples suggests we may be edging closer to
answering that question.
Rather than simply suppressing
inflammation, they have taken a much more sophisticated approach by activating
one of the body's own inflammation-resolution pathways. Their target is a
receptor called Formyl Peptide Receptor 2 (FPR2), which has not been covered in
previous posts.
Agonist
MR-39 Supports Synaptic Health in the BTBR Mouse and Features a Favorable
Safety Profile
Chronic unresolved inflammation is a common feature of several Central Nervous System (CNS) disorders, including autism spectrum disorder (ASD). We previously demonstrated that Formyl Peptide Receptor 2 (FPR2) activation by our agonist MR-39 reduced several inflammatory markers and improved social behavior in two validated animal models of ASD. Therefore, we decided to delve deeper into the potential of MR-39 as a drug for treating ASD. We first investigated the molecular mechanisms underlying the beneficial effects of MR-39 in BTBR mice. MR-39 significantly normalized pro-inflammatory cytokine release and NF-κB expression in the hippocampus and cortex, resulting in upregulation of synaptophysin protein levels, which, in turn, promote plasticity and correct abnormalities in dendritic spine morphology. Next, we characterized the safety and pharmacokinetic profile of MR-39 with respect to potential advancement for further pre- and clinical studies. We found that MR-39 was not genotoxic and safe to use since it had limited interaction with the majority of the targets associated with the adverse drug reaction. Consistently, a repeated-dose administration study evidenced no clinical signs attributable to treatment-related toxicity. On the other hand, MR-39 exhibited rapid hepatocyte clearance and interaction with efflux systems in vitro, suggesting possible limitations due to its pharmacokinetic properties. Finally, we explored multiple strategies to overcome MR-39’s low aqueous solubility, finding that the cosolvent approach can greatly enhance solubility and wettability. Overall, our study confirmed that promoting inflammation resolution with MR-39 can open new therapeutic options for ASD and that this compound has potential as a drug.
Why FPR2 is
different
Most anti-inflammatory therapies work
by blocking inflammatory pathways.
For example:
- statins reduce inflammatory signalling
through multiple mechanisms
- pioglitazone shifts microglia towards a
more reparative state via PPAR-γ
- ibudilast suppresses activated microglia
- low-dose naltrexone appears to reduce
chronic glial activation through TLR4
- clemastine may reduce microglial
activation while simultaneously promoting remyelination.
These are all potentially useful
approaches, but fundamentally they are trying to dampen inflammation.
FPR2 works differently.
Inflammation is not simply switched on
and then allowed to fade away. The body possesses an active programme that
tells the immune system when the danger has passed and it is time to stop
fighting and begin repairing damaged tissue.
FPR2 is one of the master regulators
of this resolution of inflammation.
This distinction may prove extremely important in neurological disorders where persistent inflammation itself may be preventing normal synaptic development and plasticity.
Where is FPR2
found?
One reason FPR2 has attracted so much
attention is that it is expressed in many of the cells involved in both
inflammation and tissue repair.
Within the brain, FPR2 is found on:
- microglia - the brain's resident immune cells that
monitor the environment, remove debris and regulate inflammation
- astrocytes - which support neurons, maintain the
blood-brain barrier and participate in immune signalling
- neurons - suggesting FPR2 may influence synaptic plasticity and
neuronal survival directly as well as indirectly through the immune system
- brain endothelial cells - which regulate communication between
the bloodstream and the brain
Outside the brain it is expressed on
many components of the innate immune system including neutrophils, macrophages,
monocytes and several other immune cell types.
This broad distribution explains why
FPR2 is now being investigated in such diverse conditions as Alzheimer's
disease, stroke, multiple sclerosis, inflammatory bowel disease, rheumatoid
arthritis, myocardial infarction and now autism.
Unlike many receptors that are
confined to a single tissue, FPR2 appears to function as one of the body's
master regulators of inflammation resolution. It helps coordinate the
transition from an active immune response to tissue repair and restoration of normal
homeostasis.
For autism this is particularly
interesting because activating FPR2 could simultaneously calm activated
microglia, reduce inflammatory cytokines, improve blood-brain barrier function
and create an environment in which neurons and synapses can remodel more
effectively.
Its widespread expression suggests
that FPR2 is not simply controlling inflammation—it is coordinating the body's
transition from defence to repair.
The experimental
drug MR-39
The researchers tested a small
molecule called MR-39, an activator of FPR2.
Interestingly, MR-39 was not
originally developed as an autism therapy.
It emerged from research into
neuro-inflammatory disorders, particularly Alzheimer's disease, illustrating an
increasingly important trend in autism research: extending therapies developed
for one neurological disorder into another when they target shared biological
mechanisms.
Rather than developing drugs
specifically "for autism", researchers are increasingly asking:
Which
biological pathways are abnormal in autism, and are there drugs already being
developed for those pathways?
This strategy has already given us
therapies such as bumetanide, metformin, pioglitazone, statins and
calcium-channel blockers.
MR-39 is another example.
An additional reason this approach is
particularly attractive is that several studies have reported reduced
circulating levels of Lipoxin A4 (LXA₄) in autistic children. LXA₄ is not just
another anti-inflammatory molecule—it is one of the body's own specialised
pro-resolving mediators (SPMs) and one of the principal activators of FPR2,
already present in your body.
Decreased
plasma levels of lipoxin A4 in children with autism spectrum disorders
The aim of this study was to evaluate the plasma levels of lipoxin A4 (LXA4), a mediator involved in the resolution of inflammation in Chinese children with autism spectrum disorders (ASD). From January 2013 to June 2014, a total of 150 children (75 confirmed ASD cases and 75 their age-matched and sex-matched control cases) participated in this study after consent was obtained from their parents. Clinical information was collected. Plasma levels of LXA4 were measured at baseline. The severity of ASD was assessed at admission using the Childhood Autism Rating Scale total score. The results indicated that the mean plasma levels of LXA4 were significantly lower in autistic children compared with the normal children (P<0.0001). There was a significant negative relationship between circulating LXA4 levels and severity of autism evaluated by Childhood Autism Rating Scale scores (P=0.006) after adjustment for the possible covariates.
These
results suggested that autistic children had lower plasma LXA4 levels,
suggesting an increased susceptibility to recurring inflammation in these
samples.
In other words, the body already
possesses a natural mechanism for activating this receptor and switching
inflammation into its resolution phase.
If LXA₄ levels are indeed reduced in
at least some autistic individuals, that natural "stop fighting, start
repairing" signal may be weakened. MR-39 can therefore be viewed not as
introducing an entirely artificial pathway, but as pharmacologically replacing
or amplifying a biological signal that may already be deficient.
This provides a much stronger
biological rationale for targeting FPR2 in autism than simply identifying it as
another interesting receptor.
What did the new
Italian study find?
Using the well-established BTBR mouse
model of autism, the researchers found that after only eight days of treatment
MR-39:
- significantly reduced the inflammatory
cytokines IL-1β and TNF-α
- normalised NF-κB signalling
- increased levels of synaptophysin, an
important marker of healthy synapses
- corrected abnormalities in dendritic
spine morphology
- built upon previous work from the same
laboratory showing improvements in social behaviour
One particularly encouraging finding
was that MR-39 did not simply increase the number of synapses.
Instead, it appeared to improve their
maturity.
The abnormal dendritic spines seen in
the BTBR mice became much more like those found in healthy animals.
This is important because many forms
of autism are characterised not simply by having too many or too few synapses,
but by synapses that have failed to mature normally.
The findings therefore suggest that
reducing chronic neuro-inflammation may allow existing neural connections to
complete a more normal developmental programme, rather than simply creating new
ones.
This may explain why MR-39 improved
synaptic proteins and dendritic spine morphology without dramatically altering
synapse number. Rather than forcing neurons to form new connections, the drug
appears to create the biological conditions that allow normal developmental and
repair processes to resume.
More than another
mouse study
Many animal studies simply report
behavioural improvements.
This paper goes considerably further.
The authors also examined:
- pharmacokinetics
- liver toxicity
- cardiac safety
- off-target effects
- genotoxicity
- metabolism
- formulation chemistry
In other words, they were already
thinking like drug developers rather than purely academic scientists.
That makes this one of the more
substantial preclinical autism studies published in recent years.
The challenges
MR-39 is not yet ready for human
trials.
The authors identified several
important limitations including poor oral bioavailability, rapid metabolism and
potential cardiac and liver toxicity.
Fortunately, none of these appear
insurmountable, and the compound was well tolerated in mice at therapeutic
doses.
Like many first-generation research
compounds, MR-39 itself may never become the final medicine.
Its greatest contribution may simply
be demonstrating that FPR2 is a worthwhile therapeutic target.
Autism as a
network disorder
One theme that has appeared repeatedly
on this blog is that autism is probably best viewed not as a single biochemical
defect, but as a network disorder.
Genes, mitochondria, immune
activation, metabolism, ion channels, neurotransmitters and synaptic plasticity
all interact to produce a stable pattern of brain function. Once established,
that pattern may become a new homeostasis—a stable but abnormal equilibrium.
This helps explain why there is
unlikely ever to be a single "autism drug".
A calcium-channel blocker may improve
neuronal excitability.
A statin may reduce
neuro-inflammation.
Pioglitazone may reprogramme
microglia.
Clemastine may promote remyelination.
Bumetanide may restore inhibitory
signalling.
Each addresses one part of the
network.
The hope is not that one intervention
completely resets the brain, but that multiple interventions gradually shift
the network towards a healthier and more stable state.
Viewing autism as a network disorder naturally leads to a different therapeutic philosophy.
Instead of expecting one drug to
correct every abnormality, the aim becomes rational polytherapy—combining
carefully selected interventions that each influence a different component of
the biological network.
One treatment might reduce
neuro-inflammation.
Another might improve mitochondrial
metabolism.
Another might restore inhibitory
neurotransmission.
Another might promote remyelination.
Another might improve synaptic
plasticity.
Individually these therapies may each
produce only modest benefits.
Together, however, they may shift the
entire network towards a healthier and more stable equilibrium.
This approach is already becoming
familiar in other areas of medicine. Multiple sclerosis (MS) provides an
excellent example. Twenty years ago, the primary goal of treatment was to
suppress immune attack on myelin. Today, researchers increasingly recognise
that long-term success also requires promoting remyelination, protecting
neurons and encouraging the brain's own repair mechanisms. As a result,
therapies such as clemastine, specialised pro-resolving mediators,
neuroprotective agents and regenerative approaches are being investigated
alongside traditional immunomodulatory drugs.
The philosophy is changing from simply
stopping damage to actively promoting recovery.
I believe autism research is beginning
to move in the same direction.
FPR2 is particularly interesting
because it sits relatively high in the hierarchy of inflammatory regulation.
Rather than blocking one inflammatory pathway, it appears to activate one of
the brain's own programmes for restoring homeostasis. As such, future FPR2 activators/agonists
may eventually become one component of a broader polytherapy approach that aims
not merely to suppress symptoms, but to help the brain repair and reorganise
itself.
Linking FPR2 with
the Cell Danger Response
One striking aspect of this work is
how well it fits with Robert Naviaux's Cell Danger Response (CDR) hypothesis.
Naviaux proposes that when cells
encounter infection, toxins, trauma or metabolic stress they switch into a
protective emergency programme.
Mitochondria alter their metabolism.
ATP is released outside cells as a
danger signal.
Inflammatory pathways become
activated.
Normal cellular communication becomes
secondary to survival.
This response is entirely normal.
The problem arises if cells fail to
exit this emergency state after the original danger has passed.
Viewed in this way, FPR2 could
represent one of the mechanisms that helps cells transition out of the Cell
Danger Response and back towards normal homeostasis.
Although this link remains
speculative, it provides an intriguing framework that connects mitochondrial
signalling, neuroinflammation and synaptic repair.
Interestingly, the two fields approach
the problem from opposite directions.
Naviaux focuses on danger
signalling—how cells detect injury and enter an emergency programme.
The FPR2 researchers focus on
resolution signalling—how the immune system recognises that the danger has
passed and initiates tissue repair.
These may simply represent different
stages of the same biological programme.
One explains how the emergency begins.
The other may explain how it ends.
Ultimately, both point towards the
same biological transition:
Stop defending.
Start repairing.
Rather than directly repairing
neurons, FPR2 activation may simply remove one of the major barriers preventing
the brain from repairing itself.
Helping the body
repair itself
Perhaps the most interesting lesson
from this paper extends well beyond autism.
For decades drug development has
largely focused on blocking abnormal pathways.
Block
an enzyme
Block
a receptor
Block
a cytokine
Increasingly, medicine appears to be
moving towards a different philosophy.
Many of the body's repair mechanisms
already exist.
Stem cells migrate to damaged tissue.
Microglia clear cellular debris.
Specialised lipid mediators resolve
inflammation.
Neurons remodel synaptic connections.
Oligodendrocytes repair myelin.
The challenge is often not that these
systems are absent, but that they have become stalled or trapped in an abnormal
steady state.
FPR2 appears to be one of the
molecular switches that tells the immune system:
"The danger
has passed. Stop fighting. Start rebuilding."
That may explain why FPR2 is
attracting attention not only in autism, but also in Alzheimer's disease,
stroke, multiple sclerosis and cardiovascular disease.
Rather than overriding biology, it
appears to encourage biology to resume doing what evolution designed it to do.
Can we simply
increase Lipoxin A4 instead?
An obvious question is: if autistic
children have reduced levels of Lipoxin, why not simply treat with Lipoxin? Unfortunately,
this is not practical. Like many of the body's own signalling molecules, Lipoxin
is chemically unstable and has a biological half-life measured in minutes. It
is rapidly broken down after being produced, making it a poor drug candidate.
This is the main reason researchers focus on developing stable FPR2 activators like MR-39, which are engineered to mimic the beneficial effects of Lipoxin while remaining active in the body for much longer.
Another strategy is to encourage the body to produce more of its own Lipoxin. Unlike the resolvins, which are derived from omega-3 fatty acids, Lipoxin is synthesised from arachidonic acid (AA)—an omega-6 fatty acid that is already abundant in most people's cell membranes. The limiting factor here is not the availability of raw materials, but the activity of the specific enzymes required to convert that arachidonic acid into Lipoxin. At present, no supplement has been convincingly shown to raise Lipoxin levels in humans.
However, there is growing evidence that regular aerobic exercise promotes the
production of the body's broader family of specialised pro-resolving mediators
(SPMs). For now, until stable analogues or molecular activators clear clinical
trials, optimizing these natural physiological pathways remains our best
practical tool.
Conclusion
MR-39 itself may never become an
approved medicine. What encourages me far more is the direction in which
neuroscience is moving. Research is gradually shifting away from searching for
a single defective molecule and towards understanding the brain as a dynamic
biological network capable of adaptation, repair and recovery.
The same trend is appearing across
medicine. Many of today's most exciting therapies no longer attempt to repair
the body themselves. Instead, they help the body repair itself. Whether through
inflammation-resolution pathways such as FPR2, remyelination with clemastine,
metabolic reprogramming with pioglitazone, restoration of inhibitory signalling
with bumetanide, or perhaps one day therapies based on the Cell Danger
Response, the underlying philosophy is becoming remarkably similar. The
objective is not simply to suppress disease. It is to restore the conditions
under which the brain can heal itself.
Increasingly, researchers are
discovering that many chronic diseases are characterized not simply by
excessive inflammation, but by a failure of that inflammation to resolve
properly. Rather than continually developing stronger anti-inflammatory drugs
to stomp out symptoms, the future lies in identifying the biological signals
that tell the brain it is finally safe to stop defending itself and start
developing normally again. If that philosophy proves correct, future autism
treatment may consist of carefully selected combinations of therapies, each
nudging a different part of the network in the same direction. Individually
they may produce modest improvements, but together they may help the brain
escape an abnormal equilibrium and settle into a healthier one.
In my specific case, I think we have already
achieved this with my son’s Polypill therapy.
Peter, the future is not that far off.
ReplyDeleteProbiotic Lactobacilli activate Formyl-Peptide Receptor 2
https://www.biorxiv.org/content/10.1101/2024.05.07.592932v1.abstract
Stephen, that is interesting and may explain some of the beneficial effects of these probiotics. These bacteria produce signaling peptides which activate the FPR2 receptors in the gut. The peptides are broken down and do not reach the bloodstream. Nonetheless the effect in the gut is helpful.
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