Embryo development

What’s the origin of the problem of being fat?

gettingwell4 4-5 stars Advanced knowledge, Brain development, Epigenetics , , ,

This 2016 UK human study attempted to replicate the DNA methylation and adiposity associations found by studies on a long-term longitudinal UK cohort:

“We tested for replication of associations between previously identified CpG sites at HIF3A [the hypoxia inducible factor 3 alpha subunit gene] and adiposity in ∼1,000 mother-offspring pairs from the Avon Longitudinal Study of Parents and Children.”

The researchers had sufficient data to test the unidirectional and causal findings of previous studies:

“Availability of methylation and adiposity measures at multiple time points, as well as genetic data, allowed us to assess the temporal associations between adiposity and methylation and to make inferences regarding causality and directionality.”

The analyses didn’t replicate the previous studies’ findings, and a new finding was indicated:

“Our results were discordant with those expected if HIF3A methylation has a causal effect on BMI [body mass index, derived from height and weight] and provided more evidence for causality in the reverse direction i.e. an effect of BMI on HIF3A methylation.

These results are based on robust evidence from longitudinal analyses and were also partially supported by Mendelian randomization analysis, although this latter analysis was underpowered to detect a causal effect of BMI on HIF3A methylation.

Our results also highlight an apparent long-lasting inter-generational influence of maternal BMI on offspring methylation at this locus, which may confound associations between own [offspring] adiposity and HIF3A methylation.”

A person’s parents contributed all of their genetic material and the prenatal environment, and usually almost all of their postnatal and childhood development environment. If a person has a health problem that may have genetic and developmental origins, this is where to look for causes and preventive actions.

That these distant causes can no longer be addressed is a hidden assumption of research and treatment of effects of health problems. Aren’t such assumptions testable here in the current year?

http://diabetes.diabetesjournals.org/content/early/2016/02/01/db15-0996.long (pdf) “DNA methylation and body mass index: investigating identified methylation sites at HIF3A in a causal framework”

Epigenetic effects of diet, and reversing DNA methylation

gettingwell4 2-3 stars Required further work, Acetylcholine, Brain development, Cerebellum, Cerebrum, Cortisol, Dopamine, Epigenetics, Hippocampus, Limbic system, Lower brain, Neurochemicals, Stress , , , , , ,

This 2015 French review focused on:

“The role of maternal health and nutrition in the initiation and progression of metabolic and other disorders.

The effects of various in utero exposures and maternal nutritional status may have different effects on the epigenome. However, critical windows of exposure that seem to exist during development need to be better defined.

The epigenome can be considered as an interface between the genome and the environment that is central to the generation of phenotypes and their stability throughout the life course.”

The reviewer used the term “transgenerational” to refer to effects that were more appropriately termed parental or intergenerational. Per the definition in A review of epigenetic transgenerational inheritance of reproductive disease, for the term to apply there needed to be evidence in at least the next 2 male and/or 3 female generations of:

“Altered epigenetic information between generations in the absence of continued environmental exposure.”

The review had separate sections for animal and human studies.

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4663595/ “Impact of Maternal Diet on the Epigenome during In Utero Life and the Developmental Programming of Diseases in Childhood and Adulthood”

I arrived at the above review as a result of it citing the 2014 Harvard Reversing DNA Methylation: Mechanisms, Genomics, and Biological Functions. I’ll quote a few items from that review’s informative “Role of DNA demethylation in neural development” section:

“Distinct parts of mammalian brains, including frontal cortex, hippocampus, and cerebellum, all exhibit age-dependent acquisition of 5hmC [an oxidized derivative of 5mC [methylation of the fifth position of cytosine]].

In fact, the genome of mature neurons in adult central nervous system contains the highest level of 5hmC of any mammalian cell-type (~40% as abundant as 5mC in Purkinje neurons in cerebellum). These observations indicate that 5mC oxidation and potentially DNA demethylation may be functionally important for neuronal differentiation and maturation processes.

A comprehensive base-resolution analyses of 5mC and 5hmC in mammalian frontal cortex in both fetal and adult stages indicate that non-CpG methylation (mCH) and CpG hydroxymethylation (hCG) drastically build up in cortical neurons after birth, coinciding with the peak of synaptogenesis and synaptic pruning in the cortex. This study demonstrated that mCH could become a dominant form of cytosine modifications in adult brains, accounting for 53% in adult human cortical neuronal genome.

In mature neurons, intragenic mCH is preferentially enriched at inactive non-neuronal lineage-specific genes, indicating a role in negative regulation of the associated transcripts. By contrast, genic hCG is positively correlated with gene expression levels.”

Epigenetics research that was designed to fall one step short of wonderful

gettingwell4 2-3 stars Required further work, Epigenetics

This 2015 Edinburgh rodent study found:

“In utero exposure of rats to the analgesics indomethacin or acetaminophen, both of which target PG [prostaglandin] pathways, alters fetal germ cell number and development in both male and female fetuses. This results in modest but detrimental effects on F1 [children] female, but not F1 male, fertility in adulthood.

Fetal (F1) exposure of rats to either analgesic resulted in an effect in the second generation (F2 grand-daughters) that manifested as reduced ovarian size and markedly reduced follicle number in females but with evidence of increased follicle activation. The impact on F2 fertility (which was not studied) is unclear.

Our analgesic exposure regimen coincided with the period of chromatin/epigenetic remodelling of the (F1) fetal germ cells in both sexes, events which also occur in the human in the first trimester of pregnancy. The analgesic effects on F2 ovaries were transmitted via both paternal and maternal F1 lines.”

The limitations section showed that the rodents’ acetaminophen dosage was equivalent to a human overdose:

“We administered only a single dose of analgesics. The dose of acetaminophen which we used, resulted in blood levels of acetaminophen 2.5- to 8-fold higher than the levels reported in humans after normal therapeutic dosing (~60 mg/kg/day, divided into 4 doses) during pregnancy.”

I’m puzzled that the researchers didn’t take one more step, and design a great study. They knew what the additional effort would be, per statements such as:

“The impact on F2 fertility (which was not studied) is unclear.

The analgesic-induced reduction in fetal ovarian germ cell number was of particular concern, as the lifetime complement of oocytes is formed in utero at/around the time of birth in women and rodents.”

F3 great-grandchildren were needed to demonstrate “the impact on F2 fertility.” Testing of F3 great-grandchildren may have also provided evidence for or against transgenerational epigenetic inheritance, because those subjects’ cells would have had no direct exposure effects from analgesics.

Weren’t the researchers at the MRC Centre for Reproductive Health, The Queen’s Medical Research Institute University of Edinburgh, interested in understanding whether or not a pregnant woman who overdosed during her fetus’ early development on an analgesic available to billions of people, could potentially adversely affect not only her (F0) and her children’s (F1) and grandchildren’s (F2) reproductive health, but also her F3 great-grandchildren?

Weren’t the researchers interested in being a part of a great study, one that may have advanced science, one that may have shown whether or not epigenetic information was transmitted between generations in the absence of continued analgesic exposure?

http://www.nature.com/articles/srep19789 “Analgesic exposure in pregnant rats affects fetal germ cell development with inter-generational reproductive consequences”

Lifelong effects of stress

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A 2016 commentary A trilogy of glucocorticoid receptor actions that included two 2015 French rodent studies started out:

Glucocorticoids (GCs) belong to a class of endogenous, stress-stimulated steroid hormones. They have wide ranging physiologic effects capable of impacting metabolism, immunity, development, stress, cognition, and arousal.

GCs exert their cellular effects by binding to the GC receptor (GR), one of a 48-member (in humans) nuclear receptor superfamily of ligand-activated transcription factors.”

The French studies were exceedingly technical. The first GR SUMOylation and formation of an SUMO-SMRT/NCoR1-HDAC3 repressing complex is mandatory for GC-induced IR nGRE-mediated transrepression:

“GCs acting through binding to the GR are peripheral effectors of circadian and stress-related homeostatic functions fundamental for survival.

Unveils, at the molecular level, the mechanisms that underlie the GC-induced GR direct transrepression function mediated by the evolutionary conserved inverted repeated negative response element. This knowledge paves the way to the elucidation of the functions of the GR at the submolecular levels and to the future educated design and screening of drugs, which could be devoid of undesirable debilitating effects on prolonged GC therapy.”

The companion study Glucocorticoid-induced tethered transrepression requires SUMOylation of GR and formation of a SUMO-SMRT/NCoR1-HDAC3 repressing complex stated:

“GCs have been widely used to combat inflammatory and allergic disorders. However, multiple severe undesirable side effects associated with long-term GC treatments, as well as induction of glucocorticoid resistance associated with such treatments, limit their therapeutic usefulness.”

Even when researchers study causes, they often justify their efforts in terms of outcomes that address effects. Is an etiologic advancement in science somehow unsatisfactory in and of itself?

Once in a while I get a series of personal revelations while reading scientific publications. Paradoxically, understanding aspects of myself has seldom been sufficient to address historical problems.

Thoughts are only where some of the effects of problems show up, and clarifying my understanding can – at most – tamp down these effects. The causes are elsewhere, and addressing them at the source is what ultimately needs to happen.

A few glucocorticoid-related items to ponder:

  • How has stress impacted my life? When and where did it start?
  • Why do I feel wonderful after taking prednisone or other anti-inflammatories? What may be the originating causes of such effects?
  • Why have prolonged periods of my life been characterized by muted responses to stress? How did I get that way?
  • Have I really understood why I’ve reflexively put myself into stressful situations? What will break me out of that habit?
  • Why do the feelings I experience while under stressful situations feel familiar? Does my unconsciousness of their origins have something to do with “homeostatic functions fundamental for survival?”
  • Why haven’t I noticed that symptoms of stress keep showing up in my life? There are “physiologic effects capable of impacting metabolism, immunity,” etc. but I don’t do something about it?
  • How else may stress impact my biology? Brain functioning? Ideas and beliefs? Behavior?

The purpose of many epigenetic processes is to control virus-like material

gettingwell4 4-5 stars Advanced knowledge, Brain development, Epigenetics ,

This 2016 Swiss human review’s subject was:

“Transposable elements (TEs) may account for up to two-thirds of the human genome, and as genomic threats they are subjected to epigenetic control mechanisms engaged from the earliest stages of embryonic development.

TEs are present in all organisms from bacteria to humans, and they constitute essential motors of evolution. TEs are phylogenetically and biologically related to viruses.

TEs can disrupt genes, provide novel coding activities, exert a wide range of transcriptional influences, and, because of their repetitive nature, create grounds for recombination events leading to genomic deletions and duplications, yet only a very small minority of TEs present in the human genome are still transposition-competent, accounting for one new germline integrant in 20 to 50 human births, and none is capable of horizontal transfer.

A vast majority of these DNA-binding proteins, including many of those expressed in human differentiated cells, primarily recognize sequences contained within TEs..controlling the transcriptional potential of their TE targets well beyond the early embryonic period..modulating the transcriptional impact of TE-residing sequences that are co-opted to regulate the expression of cellular genes.

A large fraction of the recognizable mobile elements in our genome are unique to humans or close relatives. The impact of this phenomenon on speciation might be particularly pronounced in organs subjected to environmental constraints that are not overly coercive, such as the brain..the central nervous system.”

The author presented evidence that the purpose of many ongoing epigenetic processes is to silence or otherwise “tame” TEs “to regulate the expression of cellular genes.” The author contrasted his view with the view that:

“Beyond this early embryonic period, TEs become permanently silenced, and that the evolutionary selection of TE controllers is the result of a simple evolutionary arms race between the host and these genetics invaders.”

http://symposium.cshlp.org/content/early/2016/01/13/sqb.2015.80.027573.long “Transposable Elements, Polydactyl Proteins, and the Genesis of Human-Specific Transcription Networks”

A problematic study of testosterone’s influence on behavior and brain measurements

gettingwell4 < 0 Detracted from science, Amygdala, Brain development, Cerebrum, Epigenetics, Limbic system, Testosterone , , , , , ,

This 2015 US/Canadian human study of people ages 6 to 22 years found:

“Testosterone-specific associations between amygdala volume and key prefrontal areas involved in emotional regulation and impulse control:

  1. Testosterone-specific modulation of the covariance between the amygdala and medial prefrontal cortex (mPFC);
  2. A significant relationship between amygdala-mPFC covariance and levels of aggression; and
  3. Mediation effects of amygdala-mPFC covariance on the relationship between testosterone and aggression.

These effects were independent of sex, age, pubertal stage, estradiol levels and anxious-depressed symptoms.

For the great majority of individuals in this sample, higher thickness of the mPFC was associated with lower aggression levels at a given amygdala volume. This effect diminished greatly and disappeared at more extreme amygdala values.”

The study provided noncausal associations among the effects (behavioral, hormonal, and brain measurements).

From the Limitations section:

“No umbilical cord or amniotic measurements were available in this study and we therefore cannot control for testosterone levels in utero, a period during which significant testosterone-related changes in brain structure are thought to occur.”

There’s evidence that too much testosterone for a female fetus and too little testosterone for a male fetus both have lifelong adverse effects. The researchers dismissed this etiologic line of inquiry with a “supporting the notion” referral to noncausal studies.

The researchers were keen to establish:

“A very specific, aggression-related structural brain phenotype.”

This putative phenotype hinged on:

  • Older subjects’ behavioral self-reports, and
  • Parental assessments of younger subjects’ behavior

exhibited during the previous six months, and within six months of their fMRI scan.

These self-reports and interested-party observations were the entire bases for the “aggressive behavior” and “anxious–depressed” associations! The researchers disingenuously provided multiple references and models for the reliability of these assessments.

Experimental behavioral measurements – such as those done to measure performance in decision studies – may have been more accurate and informative than what the older subjects chose to self-report about their own behavior over the previous six months.

People of all ages have an imperative to NOT be completely honest about their own behavior. One motivation for this condition is that some of our historical realities are too painful to enter our conscious awareness and inform us about our own behavior. As a result, our feelings, thoughts, and behavior are sometimes driven by our histories without us being aware of it.

For example, would a teenager/young adult subject self-report an impulsive act, even if they didn’t fully understand why they acted that way? Maybe they would if the act could be viewed as prosocial, but what if it was antisocial?

What are the chances that the lives of these teenager/young adult subjects were NOT filled with impulsive actions during the six months before their fMRI scans? Could complete and accurate self-reports of such behaviors be expected?

Experimental behavioral measurements may have also been more accurate and informative than second-hand, interested-party observations of the younger subjects. Could a parent who provided half of the genes and who was responsible for many of their child’s epigenetic changes make anything other than subjective observations of their handiwork’s behavior?

Epigenetic studies have shown that adaptations to environments are among the long-lasting causes for effects that include behavior, hormones, and brain measurements. Why, in 2015, did researchers spend public funds developing what they knew or should have known would be noncausal associations, while not investigating possible causes for these effects?

Why weren’t the researchers interested enough to gather and assess etiologic genetic and epigenetic evidence? Was it that difficult to get blood samples at the same time the subjects gave saliva samples, and perform selected genetic and DNA methylation analyses?

What did the study contribute towards advancing science? Who did the study really help?

My judgment: less than nothing; and nobody. The researchers only wasted public funds advancing a meme, giving it an imprimatur of science.

http://www.psyneuen-journal.com/article/S0306-4530%2815%2900924-5/fulltext “A testosterone-related structural brain phenotype predicts aggressive behavior from childhood to adulthood”

Epigenetic effects of cow’s milk

gettingwell4 2-3 stars Required further work, Brain development, Cerebrum, Epigenetics, Glutamate, Hypothalamus, Limbic system, Neurochemicals, Stress, Telomeres , , , , ,

This 2015 German paper with 342 references described:

“Increasing evidence that milk is not “just food” but represents a sophisticated signaling system of mammals.

This paper highlights the potential role of milk as an epigenetic modifier of the human genome paying special attention to cow milk-mediated overactivation of FTO [a gene associated with fat mass and obesity] and its impact on the transcriptome of the human milk consumer.”

The author declared “no competing interests” and “There are no sources of funding.” He presumably wasn’t pressured into writing this paper.

The paper wasn’t agenda-free, however. The main thesis was:

“Persistent milk-mediated epigenetic FTO signaling may explain the epidemic of age-related diseases of civilization.”

There were separate sections on how milk may promote:

  • Breast cancer
  • Prostate cancer
  • Obesity
  • Metabolic syndrome
  • Coronary heart disease
  • Early menarche
  • Type 2 diabetes
  • Neurodegenerative diseases

I don’t eat or drink dairy products because I’m lactose-intolerant. I coincidentally don’t have any of the diseases mentioned in the paper.

My life experiences haven’t led me to share the author’s sense of alarm, or to attribute other people’s problems to their consumption of milk products. However, more than a few problems I’ve had are things I’ve done to myself through actions or inaction that may have turned out differently if I had better information.

So I curated this article in case we’re insufficiently informed about the harmful epigenetic effects of milk. What do you think?

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4687119/ “Milk: an epigenetic amplifier of FTO-mediated transcription? Implications for Western diseases”

Epigenetic consequences of early-life trauma: What are we waiting for?

gettingwell4 4-5 stars Advanced knowledge, Amygdala, Brain development, Cerebrum, Cortisol, Epigenetics, Hippocampus, Hypothalamus, Limbic system, Neurochemicals, Stress, Vasopressin , , , , ,

This 2015 UK human review discussed:

“The progress that has been made by studies that have investigated the relationship between depression, early trauma, the HPA axis and the NR3C1 [glucocorticoid receptor] (GR) gene.

Gene linkage studies for depression, as well as for other common complex disorders, have been perceived by some to be of only limited success; hence the focus on GWAS [genome-wide association studies]. However, even for simple traits, genetic variants identified by GWAS are rarely shown to account for more than 20% of the heritability.

Epigenetic changes are potentially reversible and therefore amenable to intervention, as has been seen in cancer, cardiovascular disease and neurological disorders.”

Five of the review’s references included FKBP5 (a gene that produces a protein that dampens glucocorticoid receptor sensitivity) in their titles, but it wasn’t mentioned in the review itself. A search on FKBP5 also showed human studies such as the 2014 Placental FKBP5 Genetic and Epigenetic Variation Is Associated with Infant Neurobehavioral Outcomes in the RICHS Cohort that found:

“Adverse maternal environments can lead to increased fetal exposure to maternal cortisol, which can cause infant neurobehavioral deficits. The placenta regulates fetal cortisol exposure and response, and placental DNA methylation can influence this function.

Placental FKBP5 methylation reduces expression in a genotype specific fashion, and genetic variation supersedes this effect. These genetic and epigenetic differences in expression may alter the placenta’s ability to modulate cortisol response and exposure, leading to altered neurobehavioral outcomes.”

The authors listed seven human studies conducted 2008-2015 “investigating interactions between methylation of NR3C1, depression and early adversity”:

“Newborn offspring exposed to maternal depression in utero had increased methylation at [a GR CpG site] as well as adverse neurobehavioural outcomes.

Unlike the majority of animal studies examining NR3C1 methylation, many types of potential stressors, sometimes at different developmental stages, have been used to represent early human adversity.

Substantial differences can be expected in the nature of stresses prenatally compared with postnatally, as well as their developmental consequences.”

Seven human studies over the past eight years was a very small number considering both the topic’s importance and the number of relevant animal studies during the period.

Is the topic too offensive for human studies? What makes people pretend that adverse prenatal and perinatal environments have no lasting consequences to the child?

“Many more studies will be needed before effects directly attributable to early life trauma can be separated from those relating to tissue type.

Although investigators have amassed a considerable amount of evidence for an association between differential methylation and HPA axis function in humans, a causal relationship still needs to be fully established.”

Factors that disrupt neurodevelopment may be the largest originators of epigenetic changes that are sustained throughout an individual’s entire lifespan.

Are the multitude of agendas that have resources thrown at them more important than ensuring the well-being of a human before and after they are born?

https://www.researchgate.net/publication/282048312_Early_life_trauma_depression_and_the_glucocorticoid_receptor_gene_-_an_epigenetic_perspective “Early life trauma, depression and the glucocorticoid receptor gene–an epigenetic perspective”

Assessing epigenetic origins of allergies and asthma

gettingwell4 2-3 stars Required further work, Epigenetics, Immune system, Memory, Primal Therapy, Stress , , , ,

This 2015 German paper described the study design of a birth cohort that’s being established to:

“Assess potential associations between early-life exposures and onset of childhood asthma and allergies taking into account epigenetics.

The study builds upon an existing cohort which has been recruited [1995] and in the meantime has been followed up twice [2002 and 2007].

This approach provides the unique opportunity to assess the effects of genetic predisposition, epigenetic factors, and environmental factors such as exposure to environmental tobacco smoke, living conditions, and parental occupation in a prospective and cross-generational study.”

The paper had informative references, one of which was the 2013 Epigenetic mechanisms and models in the origins of asthma:

“We need to determine whether epigenetics should be considered as a major integrator of multiple signals, or, alternatively, whether DNA methylation acts differently at various developmental stages conditional on genetic variants and exposures.

In addition, since there is a lack of critical knowledge on which genes are programmed or re-programmed at what time during gestation and in which developmental phase, birth cohort studies need to trace DNA methylation over time, and ideally over generations.

This will provide critical information about which phases in the course of life are most suitable to prevent deviant DNA methylation (preventive epigenomics) or intervene to normalize DNA methylation to prevent disease (pharmaco-epigenomics).”

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4670515/ “Establishing a birth cohort to investigate the course and aetiology of asthma and allergies across three generations – rationale, design, and methods of the ACROSSOLAR study”

I was encouraged by the referenced review’s emphasis that researchers start their investigations at the beginning of human life for causes that produce later-life effects. Subsequent emphasis on prevention was commendable.

The review also revealed a prevalent researcher bias, that causal and curative results of human disease will be found on the molecular level rather than in human experiences. This preconception leads to ignoring human elements that generate epigenetic changes that manifest themselves in symptoms such as asthma and allergies.

I don’t know how including human emotions in studies became viewed as unscientific, but here we are. I didn’t see any indication that its study design included investigating emotional states other than possibly work-related stress.

These researchers will have to pretend that proven etiologic factors such as emotional states of a pregnant woman have no affect on nervous and immune system development of her fetus. These human elements are unjustified exclusions from a study designed in 2015, but they’re easily ignored when they aren’t measured.

Here’s a search of what Dr. Arthur Janov had to say about allergies over the past eight years. A representative sample from earlier this month was:

“Every therapy we try will be temporary, something we need to do over and over again. It can be nothing else because the imprint has the force of survival, of a lifesaving memory and must endure until the life-endangering imprint is finally fully felt and resolved.

Clearly this applies to many problems, from high blood pressure to asthma and allergies. That is why it is urgent that we re-focus on the real problem.”

Where do our beliefs about our children come from? An autism example

gettingwell4 < 0 Detracted from science, Beliefs, Brain development, Cerebrum, Epigenetics, Glutamate, Limbic system, Neurochemicals, Primal Therapy , , , ,

A 2015 case study by Ohio physicians highlighted:

“Although only a small minority of patients with autism have a mitochondrial disease, many patients with mitochondrial myopathies have autism spectrum disorder symptoms.

These symptoms may be the presenting symptoms, which presents a diagnostic challenge for clinicians.

The case of a 15-year-old boy with a history of autism spectrum disorder and neurocardiogenic syncope, admitted to the inpatient unit for self-injury, whose young mother, age 35, was discovered to suffer from mitochondrial myopathy, dysautonomia, neurocardiogenic syncope, Ehler-Danlos syndrome, and other uncommon multisystem pathologies likely related to mitochondrial dysfunction.”

I was somewhat taken aback by the Abstract and Introduction statements:

“All autism spectrum disorders are known to be heritable, via genetic and/or epigenetic mechanisms, but specific modes of inheritance are not well characterized.

This form of ASD is known to be heritable, as are all forms of ASD, despite the previous belief to the contrary, though the mechanisms of inheritance, both genetic and epigenetic, are not well characterized.”

The definition of heritable as used was “able to be passed from parent to child before birth.” The reference provided was a 2014 French review Gene × Environment Interactions in Autism Spectrum Disorders: Role of Epigenetic Mechanisms.

I didn’t see the “known to be heritable” phrase mentioned in the referenced review. However, I also didn’t see anything stated in the review or cited from its 217 references that disproved this phrase.

I shouldn’t have been surprised by “despite the previous belief to the contrary” in the above quotation. I’d guess that the physicians frequently encountered parents who needed such beliefs when faced with their child’s condition.

A relevant hypothesis of Dr. Arthur Janov’s Primal Therapy is: a major function that our cerebrums have evolutionarily adapted is to use ideas and beliefs to repress pain and make us more comfortable.

I value this inference as an empathetic method of interpreting people’s behaviors and expressions of thoughts and feelings.

When a “known to be heritable” phrase can unleash pain, it likely won’t be understood in its appropriate context. Among the physicians’ challenges was a barrier that kept the parent’s pain from being felt – the belief.

http://innovationscns.com/autism-in-the-son-of-a-woman-with-mitochondrial-myopathy-and-dysautonomia-a-case-report/ “Autism in the Son of a Woman with Mitochondrial Myopathy and Dysautonomia: A Case Report”

2023 update – After all the medical gaslighting on display this decade, I don’t what it would take for me to trust a medical professional anymore. These doctors ‘knew’ somehow that autism was heritable, yet couldn’t describe mechanisms of inheritance? Please. Why were medical professionals trusted in the first place?

Trapped, suffocating, unable to move – a Primal imprint

gettingwell4 5+ stars Premium, Brain development, Brainstem, Epigenetics, Limbic system, Lower brain, Memory, Neurochemicals, Primal Therapy, Serotonin , , , , , , ,

“The malady of needing to move constantly: organizing trips, making reasons to go here and there, and in general, keeping on the move..below all that movement is a giant, silent scream.

The price we pay is never knowing our feelings or where they come from.

We have the mechanism for our own liberation inside of us, if we only knew it.

When we see constant motion we understand, but we never see the agony. Why no agony? Because it is busy being acted-out to relieve the agony before it is fully felt.”

http://cigognenews.blogspot.com/2015/11/epigenetics-and-primal-therapy-cure-for_30.html “The Miracle of Memory – Epigenetics and Primal Therapy: The Cure for Neurosis (Part 13/20)”

A review of genetic and epigenetic approaches to autism

gettingwell4 0-1 star Wasted resources, Beliefs, Brain development, Cerebrum, Cortisol, Epigenetics, Glutamate, Hippocampus, Immune system, Limbic system, Neurochemicals, Serotonin, Stress, Telomeres, Thalamus , , , , , , , ,

This 2015 Chicago review noted:

“Recent developments in the research of ASD [autistic spectrum disorder] with a focus on epigenetic pathways as a complement to current genetic screening.

Not all children with a predisposing genotype develop ASD. This suggests that additional environmental factors likely interact with the genome in producing ASD.

Increased risk of ASD is associated with mutations in genes that overlap with chromatin remodeling proteins, transcriptional regulators and synapse-associated proteins. Interestingly, these genes are also targets of environmentally induced changes in gene expression.”

Evidence was discussed for both broad and specific epigenetic ASD causes originating in the prenatal environment:

  • Maternal stress:

    “Prenatal stress exerts a profound epigenetic influence on GABAergic interneurons by altering the levels of proteins such as DNMT1 and Tet1 and decreasing the expression of various targets such as BDNF.

    Ultimately, this results in reducing the numbers of fully functional GABAergic neurons postnatally and a concomitant increased susceptibility toward hyperexcitability. The delayed migration of GABAergic interneuron progenitors results in reduced gene expression postnatally which is likely the consequence of increased amounts of DNA methylation.

    The net effect of stress during early development is to disrupt the balance of excitatory/inhibitory neuronal firing due to the loss of function associated with disrupted neuronal migration and maturation.”

  • Prenatal nutrition:

    “Exposure to a wide range of environmental toxins that impact neurodevelopment also result in global DNA hypomethylation. This model was extended to connect pathways between dietary nutrition and environmental exposures in the context of DNA hypomethylation. More recently, this hypothesis was expanded to show how dietary nutrients, environmental toxins, genome instability and neuroinflammation interact to produce changes to the DNA methylome.”

  • Maternal infections:

    “Inflammation, autoimmunity and maternal immune activation have long been suspected in the context of aberrant neurodevelopment and ASD risk.”

  • Exposure to pollutants, medications, alcohol

This was a current review with many 2015 and 2014 references. However, one word in the reviewers’ vernacular that’s leftover from previous centuries was “idiopathic,” as in:

“Idiopathic (nonsyndromic) ASD, for which an underlying cause has not been identified, represent the majority of cases.”

It wasn’t sufficiently explanatory to use categorization terminology from thousands of years ago.

Science has progressed enough with measured evidence from the referenced studies that the reviewers could have discarded the “idiopathic” category and expressed probabilistic understanding of causes. They could have generalized conditional origins of a disease, and not reverted to “an underlying cause has not been identified.”

Another word the reviewers used was “pharmacotherapeutic,” as in:

“The goal for the foreseeable future is to provide a better understanding of how specific genes function to disrupt specific biological pathways and whether these pathways are amenable to pharmacotherapeutic interventions.”

Taking “idiopathic” and “pharmacotherapeutic” together – causes for the disease weren’t specifically identified, but the goal of research should be to find specific drug treatments?

Of course reviewers from the Department of Psychiatry, The Psychiatric Institute, University of Illinois at Chicago are biased to believe that “the design of better pharmacotherapeutic treatments” will fulfill peoples’ needs.

Are their beliefs supported by evidence? Without using drugs, are humans largely incapable of therapeutic actions such as:

  • Preventing epigenetic diseases from beginning in the prenatal environment?
  • Treating epigenetic causes for and alleviating symptoms of their own disease?

http://www.futuremedicine.com/doi/full/10.2217/epi.15.92 “Merging data from genetic and epigenetic approaches to better understand autistic spectrum disorder”

An interview with Dr. Rachel Yehuda on biological and conscious responses to stress

gettingwell4 4-5 stars Advanced knowledge, Brain development, Cortisol, Epigenetics, Memory, Neurochemicals, Stress , , , ,

How Trauma and Resilience Cross Generations

“The purpose of epigenetic changes, I think, is simply to increase the repertoire of possible responses.

So let’s say, for some reason, your parents transmitted to you biologic changes that are very appropriate to starvation, but you don’t live in a culture where food is not plentiful.

You’re just not optimized, but I think that if we develop an awareness of what the biologic changes from stress and trauma are meant to do, then I think we can develop a better way of explaining to ourselves what our true capabilities and potentials are.

What I hear from trauma survivors — what I’m always struck with is how upsetting it is when other people don’t help, or don’t acknowledge, or respond very poorly to needs or distress.

Feel it instead of running to someone to give you a sleeping pill.”

Transcript: http://www.onbeing.org/program/rachel-yehuda-how-trauma-and-resilience-cross-generations/transcript/7791

Telomere dynamics, stress, and aging across generations

gettingwell4 2-3 stars Required further work, Brain development, Cortisol, Dopamine, Epigenetics, Hippocampus, Hypothalamus, Limbic system, Neurochemicals, Serotonin, Stress, Telomeres , , ,

This 2015 Pennsylvania/North Dakota animal and human review noted:

“The mechanisms linking stress exposure to disease progression and ageing either within individuals or across generations are still unclear, but recent work suggests that telomere dynamics (length and loss rate) may play an important role.

Parental stress may directly influence the parental germline telomeres pre-fertilization, affecting the telomere length inherited by offspring. Alternatively, parental stress may affect telomere dynamics indirectly either pre- or post-natally. The physiological mechanisms by which stress elicits changes in telomere length are also diverse.

We need more information about how these effects vary between developmental stages, among individuals, and within tissues of individuals..to mitigate the effects of early life adversity on human health.”

I was disappointed that the reviewers chose Problematic research with telomere length as a reference. Then again, maybe their statement:

“how these traits are related to one another clearly deserves more study”

is a polite way of saying that study’s methodology was flawed?

Regarding evolutionary biology:

“While most evidence suggests that the effect of parental stress exposure on offspring telomeres is negative, it is important to remember that this is just one trait that can contribute to parental and offspring fitness.

Investment in traits that increase fitness is expected to be favoured, even if they come at a cost to traits associated with longevity, such as telomere length.”

A similar point was made in a reference of A study of DNA methylation and age that:

“Aging has no purpose (neither for individuals nor for group), no intention. Nature does not select for quasi-programs. It selects for robust developmental growth.”

 

http://rsbl.royalsocietypublishing.org/content/11/11/20150396 “Telomere dynamics may link stress exposure and ageing across generations”

A review of epigenetic transgenerational inheritance of reproductive disease

gettingwell4 2-3 stars Required further work, Brain development, Epigenetics, Stress , , ,

This 2015 Washington review of epigenetic transgenerational inheritance of reproductive disease defined transgenerational effects as follows:

“In considering transgenerational phenomena it is important to distinguish between direct exposure effects versus germline (sperm or egg) mediated transgenerational events.

When a gestating F0 generation female is exposed the F0 generation female, the F1 generation fetus and the germ cell (sperm or egg) that is inside the fetus and that will produce the F2 generation are all directly exposed. Any effects in the F0, F1 and F2 generations may be due to direct exposure toxicity or to environmentally induced epigenetic changes in the directly exposed cells. Examination of the F3 generation (great grand-offspring) is needed to determine if a transgenerational phenomenon has occurred, since the F3 generation has had no direct exposure effects.

In contrast, in the event an adult male or non-pregnant female is exposed, the F0 generation adult and the germ cells that will generate the F1 generation are directly exposed, such that examination of the F2 generation (grand-offspring) is required to demonstrate a transgenerational phenomenon.”

This review was an example of a government agency commissioning science that narrowly supported their view. NIEHS funded this review, and the authors interpreted “environment” in “Environmentally Induced Epigenetic Transgenerational Inheritance of Reproductive Disease” to fit this conduit of public funds.

The problem was that this interpretation of “environment” limited the subject to the categories pictured in this Venn diagram. The authors’ tailoring of “environmentally induced” to the government agency’s interests should have similarly restricted the title.

F3 sperm epimutations

Other interpretations of “environment” were in studies such as:

and their references. Such studies demonstrated both that:

  1. Environmental factors like stress and nutrition – especially in early life – cause diseases in later life; and
  2. These diseases may be inherited by the subjects’ descendants.

The authors elsewhere referred generally and specifically (nutrition) to studies of other environmental factors.

Have you ever heard that our children and then their children could possibly inherit our diseases caused by stressful environments? Wouldn’t that research be of equal to or greater importance in our lives than pesticides’ harmful effects?

http://www.bioone.org/doi/10.1095/biolreprod.115.134817 “Environmentally Induced Epigenetic Transgenerational Inheritance of Reproductive Disease”