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Monday, 30 October 2023

eIF3f-related neurodevelopmental disorder

 


Source: https://ojrd.biomedcentral.com/articles/10.1186/s13023-021-01744-1/figures/2


I recently received an email from a mother in New Zealand asking about what might help her adult son, recently diagnosed with an extremely rare type of “autism” called elF3f - related neurodevelopmental disorder.

This post is just based on a preliminary investigation, I think much more would be possible if a serious full-time review was made. This applies to all the other single gene autisms that are “untreatable”.

 

eIF3f (eukaryotic translation initiation factor 3 subunit f)

elF3f is one of the more complicated genes/proteins with multiple functions. In layman’s terms it is involved in making all the other proteins.

eIF3f is a subunit of the eIF3 complex, hence the “f” on the end. It is required for several steps in the initiation of protein synthesis.

We saw how elF4 plays a role in how Fragile X causes intellectual disability. eIF4 is another translation initiation factor that plays a key role in the initiation of protein synthesis.

The eIF4 complex and the eIF3 complex interact with each other to form the translation initiation complex. This complex is responsible for bringing together the mRNA, the ribosome, and the initiator tRNA, which allows protein synthesis to begin.  I did warn you it gets complicated!

eIF4 and eIF3 are both essential for the initiation of protein synthesis.

eIF3f is also involved in the regulation of cell growth and proliferation, making it a target gene in cancer therapy, where eIF3f can be overexpressed or under-expressed.

 

In spite of what the Simon’s Foundation’s Searchlight project


Simons Search - Partnering with families. Understanding genetic changes.

Driven by science. United by hope

In order to create scientific breakthroughs for rare genetic neurodevelopmental disorders, families and scientists must come together. Simons Searchlight‘s mission is to shed light on these disorders by collecting high-quality, standardized natural history data and building strong partnerships between researchers, industry and families. Families like yours are the key to making meaningful progress.

 

and others say that “at this point, there are no medicines designed to treat the syndrome”, there certainly are potential treatment strategies available.

The mother did question whether there are similarities with Rett syndrome.  You can apparently reduce expression of eIF3f using the common supplement EGCG (Epigallocatechin Gallate). EGCG has been found to benefit Rett syndrome.

I think what is likely required for eIF3f-related neurodevelopmental disorder is the exact opposite, which is to increase expression of eIF3f.

 

Sources of data:-

 

GeneCards - EIF3F Gene - Eukaryotic Translation Initiation Factor 3 Subunit F

https://www.genecards.org/cgi-bin/carddisp.pl?gene=EIF3F

RGD - EIF3F (eukaryotic translation initiation factor 3 subunit F) Homo sapiens

https://rgd.mcw.edu/rgdweb/report/gene/main.html?id=1314535

 

The above two sites do provide a great deal of information, but I think a lot is auto-generated and there are mistakes.

What we are looking for are safe substances that change expression of the gene eIF3f.

According to GeneCards there is only one substance - quercetin.

According to RGD there is a long list.  This did look very promising, but when I looked at the linked references I did not always find that the supporting data exists.  This is a problem with AI (artificial intelligence), it can make things up.

Sometimes you have to go back to the basic science.

There is evidence that activating the PI3K/AKT/mTOR signaling pathway will increase eIF3f expression.

One known was to do that would be via increasing IGF-1 – insulin-like growth factor 1. You can inject IGF-1 and it has even been trialed in autism.

In New Zealand there is an OTC supplement called CGPMax that claims to increase IGF-1.

I checked and indeed there is some evidence that CGPMax may also increase the expression of eIF3f.

“There is some evidence that CGPMax may also increase the expression of eIF3f. In a study of ER-positive breast cancer cells, CGPMax was shown to increase the expression of eIF3f mRNA and protein. This was thought to be due to the inhibition of CDK4/6, which led to the activation of the PI3K/AKT/mTOR signaling pathway.”

AI generated

Since our reader is in New Zealand and wants a supplement rather than a drug, I think CGPMax is a good fit and certainly worth a trial.

One of the substances suggested by the RGD site was valproic acid.  This looked great news because valproic acid, an anti-epileptic drug (AED), is often used to safely treat even young children.

Why does Valproic acid apparently increase eIF3f mRNA?  That would highly likely be down to it being an HDAC inhibitor which causes it to make epigenetic changes that turn on/off our genes.

We know that some single gene autism can be treated by HDAC inhibitors, at least in mouse models. The potent HDAC inhibitors are now used to treat cancer. One parent I met at the Thinking Autism conference was desperate to access one of these potent drugs for her child’s single gene autism, similar to Kabuki syndrome.

Broccoli sprouts produce an HDAC inhibitor, called sulforaphane.

I could not find any supporting data why valproic acid was listed, the linked reference did not actually refer to eIF3f.

Nonetheless it is harmless to try broccoli sprouts.

 

Quercetin

Another common product popped up in my brief review and that was Quercetin. I had not expected to find that. There is a reaction between quercetin and eIF3f. It is not fully understood. 

Quercetin is a widely available OTC product and simple to trial.

 

Estradiol

It is known that estradiol can increase the expression of eIF3f.

The effect of estradiol on eIF3f expression is likely mediated by the estrogen receptor alpha (ERα).  We have seen that estrogen receptor beta (ERβ) is under-expressed in autism.

Increasing estradiol, or indeed reducing testosterone, has been proposed as an autism therapy. This is not a simple strategy.  In cancer therapy radical steps are taken to reduce sex hormones, because it is the only way to stop the growth of certain types of cancer.

Disturbing the level of male/female hormones will have body-wide effects.  The “men” who currently take large doses of female hormones are going to have consequences later in life.

There is dietary therapy in the form of phytoestrogens that is known to be safe.  The Japanese eat a lot of soy products.

Soy is a particularly good source of phytoestrogens, especially a type of phytoestrogen called isoflavones. Isoflavones are similar in structure to estrogen, but they are much weaker.

Incorporating more soy products into diet would seem a reasonable strategy.

 

Others

There is some evidence that the antibiotic gentamicin can activate the gene eIF3f.  It is given by injection.

Among the list of substance that can increase eIF3f mRNA are some quite toxic substances like BPA found in plastic packaging.  Another interesting option was listed under “anti-rheumatic drugs”, this actually refers to tocilizumab. This is an anti-arthritis drug given to people over the age of two.  Since it ends in -mab, we can infer that it contains monoclonal antibodies, in this case to interleukin-6.

Tocilizumab would likely be helpful in many people with other kinds of autism with a strong auto-immune component.

 

eIF3f-specific treatments vs treat as idiopathic autism

We know from readers with children with different single gene autisms, that are supposed to be untreatable, that these children often respond well to therapies in use for autism of unknown origin (idiopathic autism).

Almost all autism features neuroinflammation, activated microglia etc. Most autism features oxidative stress.  Most autism features impaired myelination. Much autism features mitochondrial dysfunction.

There are specific insights that a genetic diagnosis does give you.  In the case of eIF3f, we are dealing with hypo-active (REDUCED) pro-growth signaling. That means the opposite to the kids born with macrocephaly (big heads).

 


This excellent framework was explained in this old post

https://www.epiphanyasd.com/2015/12/one-of-thousands-autism.html

IGF-1 was mentioned earlier as a possible therapy.  Note that growth hormone (GH) is made in the anterior pituitary gland, it is released into the blood stream, and then stimulates the liver to produce IGF-1. IGF-1 then stimulates systemic body growth, and has growth-promoting effects on almost every cell in the body.

More IGF-1 would lead to more growth. Even in an adult you can increase the density of dendritic spines.

As shown in the chart above on the lower right, in today’s disorder we have decreased protein synthesis.

Now back to the science and the basics of this syndrome. 

eIF3f-related neurodevelopmental disorder (EIF3F-RND) is a rare genetic disorder that causes a variety of neurological and developmental problems. It is caused by mutations in the eIF3f gene, which provides instructions for making a protein that is involved in protein synthesis. It has to be inherited from both parents.

If both parents are carriers, there is a 25% chance that each child will have EIF3F-RND, a 50% chance that each child will be a carrier, and a 25% chance that each child will not have EIF3F-RND and will not be a carrier.

If only one parent is a carrier of the mutated gene, there is a 50% chance that each child will be a carrier, and a 50% chance that each child will not be a carrier and will not have EIF3F-RND.

The incidence of EIF3F-related neurodevelopmental disorder (EIF3F-RND) is unknown. However, it is estimated to be a very rare disorder, affecting less than 1 in 100,000 people. This is likely due to the fact that EIF3F-RND is caused by mutations in a single gene. In order for a child to be affected, both parents must carry a copy of the mutated gene. If only one parent is a carrier, the child will be a carrier, but will not be affected.

The incidence of EIF3F-RND may also be underestimated, as it is a relatively newly identified disorder. As more people are diagnosed with the disorder, the incidence rate may increase. 

EIF3F-RND is caused by under-expression of the eIF3f protein.

Symptoms of EIF3F-RND can vary widely from person to person, but may include:

  • Intellectual disability
  • Developmental delay
  • Seizures
  • Hypotonia (low muscle tone)
  • Microcephaly (small head size)
  • Autism spectrum disorder
  • Facial dysmorphism

 

 



Source: https://ojrd.biomedcentral.com/articles/10.1186/s13023-021-01744-1/figures/2

 

Interactions with other genes/proteins 

One feature of the GeneCards website is that you can see a representation of which are the most important interactions of a gene/protein.

This can sometimes suggest a possible therapy, since one of these related genes might be easier to treat.

In the case of eIF3f almost all the interactions are with other elF-somethings.

The RPS-somethings below are all genes that translate mRNA into proteins.

So, everything below is part of the machinery cells have to make proteins.

 

 


 

EIF3F-related neurodevelopmental disorder research

The EIF3F-NDR research is still in its infancy.

There need to be a models made that can suggest which downstream genes are affected and hence might be treatable.

An eIF3f activator is a drug or other compound that can increase the expression or activity of the eIF3f protein.

Currently, there are no known eIF3f activators that are approved for clinical use. However, researchers are developing a number of different approaches to activating EIF3F, including:

  • Small molecule drugs: Researchers are screening libraries of small molecules to identify compounds that can bind to eIF3f and increase its activity.
  • Gene therapy: Gene therapy could be used to deliver a working copy of the eIF3f gene to cells in the nervous system.
  • CRISPR gene editing: CRISPR gene editing could be used to correct mutations in the eIF3f gene.

In addition to the above approaches, there are a number of other things that could potentially be done to activate eIF3f, such as:

  • Identifying and targeting upstream regulators of eIF3f: Researchers could identify and target other proteins or genes that regulate the expression or activity of eIF3f. This could lead to the development of new drugs or other therapies that could be used to activate eIF3f indirectly.
  • Understanding the role of eIF3f in different cell types: Researchers are still learning about the role of eIF3f in different cell types in the nervous system. This knowledge could be used to develop targeted therapies that activate eIF3f in the specific cell types where it is needed most.

  

EIF3F-related neurodevelopmental disorder: refining the phenotypic and expanding the molecular spectrum

 

Background

An identical homozygous missense variant in EIF3F, identified through a large-scale genome-wide sequencing approach, was reported as causative in nine individuals with a neurodevelopmental disorder, characterized by variable intellectual disability, epilepsy, behavioral problems and sensorineural hearing-loss. To refine the phenotypic and molecular spectrum of EIF3F-related neurodevelopmental disorder, we examined independent patients.

Results

21 patients were homozygous and one compound heterozygous for c.694T>G/p.(Phe232Val) in EIF3F. Haplotype analyses in 15 families suggested that c.694T>G/p.(Phe232Val) was a founder variant. All affected individuals had developmental delays including delayed speech development. About half of the affected individuals had behavioral problems, altered muscular tone, hearing loss, and short stature. Moreover, this study suggests that microcephaly, reduced sensitivity to pain, cleft lip/palate, gastrointestinal symptoms and ophthalmological symptoms are part of the phenotypic spectrum. Minor dysmorphic features were observed, although neither the individuals’ facial nor general appearance were obviously distinctive. Symptoms in the compound heterozygous individual with an additional truncating variant were at the severe end of the spectrum in regard to motor milestones, speech delay, organic problems and pre- and postnatal growth of body and head, suggesting some genotype–phenotype correlation.

Conclusions

Our study refines the phenotypic and expands the molecular spectrum of EIF3F-related syndromic neurodevelopmental disorder.

 

The cancer research

Cancer research is much more advanced and better funded than autism research.

As you can see in the table below, decreased expression of eIF3f is feature of several common cancers. If you can upregulate eIF3f you might have a viable cancer therapy.

As in many types of autism, the potential exists to repurpose cancer drugs as and when they get developed and approved. HDAC inhibition is perhaps the best example. So far people are too scared to try the new potent HDAC inhibitors in human single-gene (monogenic) autism.

  

https://theses.hal.science/tel-01679873/document



 


Alternatively, an indirect regulation of the activity of eIF3 is performed by association of its subunits with other proteins involved in the regulation of protein synthesis. For example, the subunit eIF3e binds p56 in interferon-treated or virus-infected mammalian cells, and inhibits the translation in vitro and in vivo [43, 44]. The subunit eIF3g interacts with Paip1, a Poly (A)-binding protein and stimulates translation initiation [45] whereas the subunits eIF3h and eIF3f interact with TRC8, a ubiquitin E3 ligase, and inhibit protein synthesis, possibly through ubiquitilation of eIF3 or some other translational components [46]. These mechanisms and interacting partners render eIF3 a pivotal player in controlling the protein synthesis and degradation. 

All these data confirm that eIF3f has a multileveled control of multiple functions in the cells, outside its usual function in translation. Keeping it in mind, targeting eIF3f may be a strategy to reorganize different intracellular pathways and alter the basis of the balance between cell proliferation and apoptosis. Thus, eIF3f represents a lead candidate to use for biotherapeutic applications both for inhibiting the growth of cancer cells or muscle atrophy and thus preventing its progression into irreversible cachexia.

 

Conclusion

Personally, I would treat EIF3F-NDR with two parallel approaches:

·        As idiopathic autism with hypo-active pro-growth sigaling autism (small heads/microcephaly)

·        Gene specific with clever ideas targeting the effects of eIF3f under-expression.

Is the cognitive impairment responding to bumetanide?  In the models of Rett syndrome and Fragile-X this is the case. For EIF3F-NDR you could just make your own trial.

For sure there will be oxidative stress in EIF3F-NDR due to the malfunctioning in the protein synthesis “machinery”.  NAC is the antioxidant of choice and is OTC.

EIF3F-NDR can be associated with GI dysfunction, as is much of broader autism.  When treated this often leads to improvements in behavior.

Increasing IGF-1 looks achievable.

Nerve growth factor (NGF) may be upregulated by Lion’s Mane mushrooms, according to the research.

BDNF (brain derived neurotropic factor) can be up regulated. Certain foods and nutrients have been shown to increase BDNF levels. For example, one study found that lutein supplementation increased BDNF levels in the blood. Other foods and nutrients that have been shown to increase BDNF levels include omega-3 fatty acids, magnesium, and zinc.  Some drugs increase BDNF such as lithium, SSRIs, modafinil. Statins such as Simvastatin and Atorvastatin are known to increase BDNF.

 

 



Tuesday, 17 October 2023

Takeaways from Thinking Autism 2023


I did present at the Thinking Autism 2023 conference in London recently.  I was last there in 2019 and there were many familiar faces.

Emotions were very much on show - joy, desperation, bewilderment, hope, fear, frustration and more.

The United Kingdom is amongst the worst countries in the world if you want to treat autism.  Even the idea of treating autism can get you into trouble. For severe autism it is much better to say treating ID (intellectual disability) – what sane person could object to that?

My takeaways are very specific to me, but here they are anyway.

 

So many doctors!

This year I was approached by many doctors who have children with ASD.  Among them were GPs, pediatricians, a neurologist, and a psychiatrist.

When you understand the basis of autism it is not surprising that so many doctors have kids with autism, particularly doctors married to a doctor.

 

Fertility treatment increasing the risk of autism

I did mention in my book the link between difficulty conceiving and having children with autism. Mothers who have had miscarriages are at risk of having a child with autism and children produced via IVF therapy have an elevated chance of autism.

One of the speakers at the conference, who uses diet as a therapy, told us that 30-40% of her patients where conceived by IVF therapy.  Wow – I thought. They are mainly children with milder autism, only 10% of her patients have severe autism.

 

From struggling to get on IVIG to how to come off it

Many parents struggle to get onto IVIG therapy for their child.  It is very expensive and, being an intravenous therapy, it is not so easy to administer to a child with severe autism.

Having finally got on IVIG therapy and responded well to it, how do ever wean the child off it, without losing all those gains?

This was a side issue arising from the conference and is an issue to some other readers of this blog.

What is very interesting is the potential to give IVIG therapy just once to very young children who developed normally but then suffer a regression into “autism.”  It seems to work for some. You might get it in Russia, but don’t bother asking in the UK.

 

My son is 14, I have tried everything else now I am ready for pills

Some people do respond well enough to dietary modification and OTC supplements, but more severe autism likely needs pharmaceuticals. For one mother at the conference she had come to this conclusion.  It is never too late to start to treat severe autism. Good luck to her!

 

Never give up

Never give up was the last point on my talk.

One mother at the conference was a very good example. She had finally had her twins examined at the UK’s top children’s hospital, Great Ormond Street Hospital (GOSH).  They have had MRIs, lumbar punctures to get spinal fluid samples and they have had genetic testing.  That is a triumph in the UK health system.

As she told us, she had to play the cancer card. She told her doctors “why do you go to such great lengths to save my life from cancer and yet do nothing for my twin boys with severe autism?”

Now one has a diagnosis of cerebral folate deficiency and one has a mutation is DISC1, a schizophrenia gene already covered, with therapy ideas, in my blog.  High dopamine in spinal fluid was only to be expected - it is a feature of schizophrenia. Light is at the end of the tunnel.  This mother was also very helpful to other mothers present.

 

School reporting on parent treating autism

I was disappointed to hear that a school had reported one mother for treating her child’s autism.

 

Ketones really do benefit some!

I did write a lot about the multiple possible benefits of ketones/BHB in autism.

The week before the conference one mother wrote to tell me that both she and her child with autism respond well to HVMN Ketone-IQ.

I knew our doctor reader Agnieska was a big fan of the BHB ester product Ketoforce, which seems to have disappeared during Covid.

At the conference a Spanish psychiatrist was listing the therapies in my blog that have helped his son and they included NAC, Bumetanide and BHB.

There are several new ketone products based on diol ketone esters, like HVMN Ketone-IQ.

Our reader Daniel mentioned very recently that he is using a product called DeltaG, a proprietary blend of diol ketone esters. HVMN Ketone-IQ is a pure diol ketone ester, while DeltaG is a proprietary blend of diol ketone esters.

The active ingredient in Ketone-IQ is R-1,3 Butanediol, also referred to as R-1,3-Butylene glycol, which maintains FDA GRAS status as a flavor molecule.

 

https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfcfr/CFRSearch.cfm?fr=173.220

 

1,3-Butylene glycol (1,3-butanediol) may be safely used in food in accordance with the following prescribed conditions:

(a) The substance meets the following specifications:

(1) 1,3-Butylene glycol content: Not less than 99 percent.

(2) Specific gravity at 20/20 deg.C: 1.004 to 1.006.

(3) Distillation range: 200deg.-215 deg.C.

(b) It is used in the minimum amount required to perform its intended effect.

(c) It is used as a solvent for natural and synthetic flavoring substances except where standards of identity issued under section 401 of the act preclude such use.

 

This raw ingredient is very cheap.

Once it is packaged up as a supplement, it becomes very expensive.

As Agnieszka mentioned on the conference sidelines, you do have to look at the ingredients. In HVMN Ketone-IQ there is potassium benzoate as the preservative.  Potassium benzoate is a DAO inhibitor. DAO, or diamine oxidase, is an enzyme that breaks down histamine, a compound that can cause a variety of symptoms in histamine-sensitive people, such as headache, flushing, hives, and diarrhea.

 

“If my son can take the bus aged 20, I’d be happy”

One doctor mother showed me a video of her untreated young son with severe autism.  I told her how I have treated my son since 2012 and what the result has been. He passed his high school exams (GCSEs) in maths, science, geography, and English.  Now he has learnt how to travel independently from home by bus.  Time for those pills.






Thursday, 5 October 2023

The Guardian of the Genome – the role of P53 in Cancer Prevention and in increasing/decreasing Autistic Behaviors



 

The p53 protein is called the guardian of the genome because it plays a critical role in maintaining genomic stability. It does this by surveying the genome for signs of DNA damage. If p53 detects DNA damage, it activates a number of different cellular responses to prevent the damaged cell from dividing and passing on that damage. These responses can include:

  • p53 can halt the cell cycle giving the cell time to repair the damaged DNA.
  • p53 can activate genes that are involved in DNA repair.
  • If the DNA damage cannot be repaired, p53 can trigger cell death.

p53 protects your genome by preventing damaged cells from dividing and passing on DNA damage.

 

What about p53 and autism?

We have seen many times that cancer genes overlap with autism genes; that is the case today with p53. The protein p53 acts like a transcription factor turning on or off key genes in the brain that affect learning and behavior. 


Protein p53’s Role in Autism-like Behavior and Memory

Scientists have discovered a direct link between the protein p53 and autism-like behavior in mice. The researchers studied the effects of manipulating p53 levels in the mouse hippocampus.

Reduced levels resulted in repetitive behavior, diminished sociability, and impaired learning, especially in male mice. This pivotal work uncovers the intricate role of p53 in neurodevelopmental disorders like autism.

Key Facts:

1.     Lowered hippocampal p53 levels in mice led to repetitive behavior, decreased sociability, and hindered hippocampus-dependent learning.

2.     Elevated p53 levels were observed during periods of enhanced communication between hippocampal neurons, related to positive learning outcomes.

3.     Previous research from 2018 identified p53’s significant role in irregular brain cell activity seen in both ASD and epilepsy.

 

In this study, Tsai and his colleagues lowered hippocampal p53 levels in mice, looking for changes in gene expressions related to behavior. They observed that the decreased p53 levels: 

·        Promoted repetitive behavior in mice.

·        Reduced sociability in mice.

·        Impaired hippocampus-dependent learning and memory, especially in male mice.

The researchers also observed that p53 levels were elevated after a period of active communication between hippocampal neurons called long-term potentiation. Flexible neuron firing — known as plasticity — is related to positive learning and memory outcomes. 

In a 2018 study, Tsai and his colleagues identified p53 as a key protein involved in the irregular brain cell activity seen in ASD and epilepsy. In future studies, they aim to explore how p53 coordinates the expression of those autism-linked genes to guide behavior. 

 

The full paper: 

Tumor suppressor p53 modulates activity-dependent synapse strengthening, autism-like behavior and hippocampus-dependent learning

Synaptic potentiation underlies various forms of behavior and depends on modulation by multiple activity-dependent transcription factors to coordinate the expression of genes necessary for sustaining synaptic transmission. Our current study identified the tumor suppressor p53 as a novel transcription factor involved in this process. We first revealed that p53 could be elevated upon chemically induced long-term potentiation (cLTP) in cultured primary neurons. By knocking down p53 in neurons, we further showed that p53 is required for cLTP-induced elevation of surface GluA1 and GluA2 subunits of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR). Because LTP is one of the principal plasticity mechanisms underlying behaviors, we employed forebrain-specific knockdown of p53 to evaluate the role of p53 in behavior. Our results showed that, while knocking down p53 in mice does not alter locomotion or anxiety-like behavior, it significantly promotes repetitive behavior and reduces sociability in mice of both sexes. In addition, knocking down p53 also impairs hippocampal LTP and hippocampus-dependent learning and memory. Most importantly, these learning-associated defects are more pronounced in male mice than in female mice, suggesting a sex-specific role of p53 in these behaviors. Using RNA sequencing (RNAseq) to identify p53-associated genes in the hippocampus, we showed that knocking down p53 up- or down-regulates multiple genes with known functions in synaptic plasticity and neurodevelopment. Altogether, our study suggests p53 as an activity-dependent transcription factor that mediates the surface expression of AMPAR, permits hippocampal synaptic plasticity, represses autism-like behavior, and promotes hippocampus-dependent learning and memory.

  

How to upregulate p53?

It is important to note that increasing p53 levels does not guarantee that p53 will be activated.

Researchers are still in the early stages of developing drugs that can specifically activate p53.

There are a number of food products that have been shown to increase p53 levels in cells, such as cruciferous vegetables like broccoli.

If you refer to the excellent Gene Cards resource, you will find that very many drugs can help activate p53. Almost 500 are listed – too many for me to review here.


https://www.genecards.org/cgi-bin/carddisp.pl?gene=TP53

 

One example is the old antihistamine Clemastine that has been recommended in this blog, for completely different reasons. A paper in 2023 suggests “Repurposing Clemastine to Target Glioblastoma (brain cancer)”.

Indole-3-carbinol (I3C) gets listed as does Epigallocatechin gallate (EGCG).

I have mentioned previously that I3C is one reason (unrelated to sulforaphane) that broccoli can be beneficial in some autism.

The last time I mentioned EGCG, a catechin found in green tea, a doctor reader contacted me to tell me that he has taken it for 20 years for its antiangiogenic properties. Antiangiogenic means that something prevents or slows down the growth of new blood vessels. Cancer cells need a blood supply to grow and spread. They produce proteins called angiogenic factors, which stimulate the growth of new blood vessels. Antiangiogenic drugs work by blocking the effects of angiogenic factors or by targeting the cells that produce them. This can starve cancer cells of the blood they need to grow and spread.  It seems to have worked well for our reader!

We have seen that EGCG has been proposed to treat girls with Rett syndrome.

EGCG has been shown to have a number of beneficial effects in cells and animal models of Rett syndrome. For example, EGCG has been shown to: 

·        Increase levels of the p53 tumor suppressor protein

·        Reduce oxidative stress

·        Improve mitochondrial function

·        Promote synaptic plasticity

·        Protect neurons from damage

One of our readers finds that Broccoli powder (Broccomax) provides a boost to his daughter with Rett syndrome. Is it the sulforaphane or it the Indole-3-carbinol (I3C)? My bet would be on the I3C from the broccoli.  You can buy I3C itself.

 

Conclusion

More p53 please!

Eating well is much more than just about vitamins.  Eating all those healthy foods mentioned above that many people avoid will boost your p53 levels.

Ultimately there will be an expensive new drug to boost p53 in cancer patients.

Very many old drugs do have secondary effects that include boosting or activating p53.

Curcumin, not surprisingly, boosts p53 and helps protect people of Indian origin from cancer via their traditional diet.

Genistein, resveratrol, EGCG, broccoli powder are all supplements that boost p53.

It is nice to see that Clemastine, my favorite old antihistamine that may promote myelination in some, stabilize activated microglia in some, many also increase p53 sufficiently to be seen as a potential anti-cancer therapy.

Maybe keep an eye out for Dr Tsai, particularly if you are interested in Fragile X or p53. Here he is: 

https://mcb.illinois.edu/directory/profile/nptsai