Advances in Autism Research
compiled by Teresa Binstock for
Autism Research Institute
April 2008

Mitochondria in Autism

Two categories: disorder and dysfunction
 

That the US HHS conceded vaccine-induced autism symptoms (Hannah Poling, 2007) renewed and widened interest in mitochondrial issues in autism - despite years of ongoing research. Furthermore, Hannah Poling receive 9 vaccinations in one day and prompted concern for what types of increased susceptibility might incline an infant or toddler toward developing adverse effects from vaccinations.

Since HHS conceded in regard to Hannah Poling's vaccination-induced regression into an autism symptoms profile, the CDC has insisted that her case is extremely rare and unique. However, a case report by Hannah's father and colleagues (1) presented lab data from Hannah and from a large group of autistic children and suggested that instead of Hannah's condition being"unique", many children might have pre-vaccination susceptibility related to mitochrondrial dysfunction (MtD; 2), which in many cases is different from classically described, genetically identified mitochondrial disorder.

A review by Dan Rossignol, M.D., and Jeff Bradstreet, M.D., is free online, has numerous citations, and is useful for understanding differences between mito disorder and the perhaps more common mito dysfunction (2).

see also:
Mitochondria and Pollutants including Thimerosal
Air Pollution and Mitochondria
Antibiotics and Mitochondria
 

1. Developmental regression and mitochondrial dysfunction in a child with autism

Poling JS, Frye RE, Shoffner J, Zimmerman AW.
J Child Neurol. 2006 Feb;21(2):170-2

Autistic spectrum disorders can be associated with mitochondrial dysfunction. We present a singleton case of developmental regression and oxidative phosphorylation disorder in a 19-month-old girl. Subtle abnormalities in the serum creatine kinase level, aspartate aminotransferase, and serum bicarbonate led us to perform a muscle biopsy, which showed type I myofiber atrophy, increased lipid content, and reduced cytochrome c oxidase activity. There were marked reductions in enzymatic activities for complex I and III. Complex IV (cytochrome c oxidase) activity was near the 5% confidence level. To determine the frequency of routine laboratory abnormalities in similar patients, we performed a retrospective study including 159 patients with autism (Diagnostic and Statistical Manual of Mental Disorders-IV and Childhood Autism Rating Scale) not previously diagnosed with metabolic disorders and 94 age-matched controls with other neurologic disorders. Aspartate aminotransferase was elevated in 38% of patients with autism compared with 15% of controls (P <.0001). The serum creatine kinase level also was abnormally elevated in 22 (47%) of 47 patients with autism. These data suggest that further metabolic evaluation is indicated in autistic patients and that defects of oxidative phosphorylation might be prevalent.
    PMID: 16566887

2. Specification of autistic children similar to Hannah Poling

DR. JON POLING TO DR. STEVEN NOVELLA ON AGE OF AUTISM
03/11/2008
http://www.ageofautism.com/2008/03/dr-jon-poling-o.html#more

[Dr. Poling's eloboration is worth reading in its entirety. Here is a quote therefrom.]

" The best estimate to date of the prevalence of mitochondrial dysfunction in autistic patients comes from Oliviera et al. in a population of 120, 5 of 69 (or 7.2%) showed mitochondrial dysfunction.  If this is generalized to the US estimate of 1 million patients with ASDs, then the number of kids like Hannah could be 72,000!"

3. Evidence of Mitochondrial Dysfunction in Autism and Implications for Treatment

Daniel A. Rossignol and J. Jeffrey Bradstreet
Am J of Biochem Biotech 4(2): 208-217 , 2008
http://www.scipub.org/fulltext/ajbb/ajbb42208-217.pdf

Classical mitochondrial diseases occur in a subset of individuals with autism and are usually caused by genetic anomalies or mitochondrial respiratory pathway deficits. However, in many cases of autism, there is evidence of mitochondrial dysfunction (MtD) without the classic features associated with mitochondrial disease. MtD appears to be more common in autism and presents with less severe signs and symptoms. It is not associated with discernable mitochondrial pathology in muscle biopsy specimens despite objective evidence of lowered mitochondrial functioning. Exposure to environ-mental toxins is the likely etiology for MtD in autism. This dysfunction then contributes to a number of diagnostic symptoms and comorbidities observed in autism including: cognitive impairment, language deficits, abnormal energy metabolism, chronic gastrointestinal problems, abnormalities in fatty acid oxidation, and increased oxidative stress. MtD and oxidative stress may also explain the high male to female ratio found in autism due to increased male vulnerability to these dysfunctions. Biomarkers for mitochondrial dysfunction have been identified, but seem widely under-utilized despite available therapeutic interventions. Nutritional supplementation to decrease oxidative stress along with factors to improve reduced glutathione, as well as hyperbaric oxygen therapy (HBOT) represent supported and rationale approaches. The underlying pathophysiology and autistic symptoms of affected individuals would be expected to either improve or cease worsening once effective treatment for MtD is implemented.

4. Mitochondrial Energy-Deficient Endophenotype in Autism

J. Jay Gargus and Faiqa Imtiaz
Am J Biochem Biotech 4(2): 198-207 , 2008
http://www.scipub.org/fulltext/ajbb/ajbb42198-207.pdf

While evidence points to a multigenic etiology of most autism, the pathophysiology of the disorder has yet to be defined and the underlying genes and biochemical pathways they subserve remain unknown. Autism is considered to be influenced by a combination of various genetic, environmental and immunological factors; more recently, evidence has suggested that increased vulnerability to oxidative stress may be involved in the etiology of this multifactorial disorder. Furthermore, recent studies have pointed to a subset of autism associated with the biochemical endophenotype of mitochondrial energy deficiency, identified as a subtle impairment in fat and carbohydrate oxidation. This phenotype is similar, but more subtle than those seen in classic mitochondrial defects. In some cases the beginnings of the genetic underpinnings of these mitochondrial defects are emerging, such as mild mitochondrial dysfunction and secondary carnitine deficiency observed in the subset of autistic patients with an inverted duplication of chromosome 15q11-q13. In addition, rare cases of familial autism associated with sudden infant death syndrome (SIDS) or associated with abnormalities in cellular calcium homeostasis, such as malignant hyperthermia or cardiac arrhythmia, are beginning to emerge. Such special cases suggest that the pathophysiology of autism may comprise pathways that are directly or indirectly involved in mitochondrial energy production and to further probe this connection three new avenues seem worthy of exploration: 1) metabolomic clinical studies provoking controlled aerobic exercise stress to expand the biochemical phenotype, 2) high-throughput expression arrays to directly survey activity of the genes underlying these biochemical pathways and 3) model systems, either based upon neuronal stem cells or model genetic organisms, to discover novel genetic and environmental inputs into these pathways.

5: Mitochondrial dysfunction in autism spectrum disorders: a population-based study

Oliveira G et al.
Dev Med Child Neurol. 2005 Mar;47(3):185-9.

A minority of cases of autism has been associated with several different organic conditions, including bioenergetic metabolism deficiency. In a population-based study, we screened associated medical conditions in a group of 120 children with autism (current age range 11y 5mo to 14y 4mo, mean age 12y 11mo [SD 9.6mo], male:female ratio 2.9:1). Children were diagnosed using Diagnostic and Statistical Manual of Mental Disorders criteria, the Autism Diagnostic Interview--Revised, and the Childhood Autism Rating Scale; 76% were diagnosed with typical autism and 24% with atypical autism. Cognitive functional level was assessed with the Griffiths scale and the Wechsler Intelligence Scale for Children and was in the normal range in 17%. Epilepsy was present in 19 patients. Plasma lactate levels were measured in 69 patients, and in 14 we found hyperlactacidemia. Five of 11 patients studied were classified with definite mitochondrial respiratory chain disorder, suggesting that this might be one of the most common disorders associated with autism (5 of 69; 7.2%) and warranting further investigation.
PMID: 15739723

6: Should autistic children be evaluated for mitochondrial disorders?

Lerman-Sagie T, Leshinsky-Silver E, Watemberg N, Lev D.
J Child Neurol. 2004 May;19(5):379-81.

Autism is etiologically heterogeneous; medical conditions are implicated in only a minority of cases, whereas metabolic disorders are even less common. Recently, there have been articles describing the association of autism with mitochondrial abnormalities. We critically review the current literature and conclude that mitochondrial disorders are probably a rare and insignificant cause of pure autism; however, evidence is accumulating that both autosomal recessive and maternally inherited mitochondrial disorders can present with autistic features. Most patients will present with multisystem abnormalities associated with autistic behavior. Finding biochemical or structural mitochondrial abnormalities in an autistic child does not necessarily imply a primary mitochondrial disorder but can also be secondary to technical inaccuracies or another genetic disorder. Clinicians should be careful in diagnosing a mitochondrial disorder in an autistic child because it has important implications for accurate genetic counseling, prognosis, and therapy.
PMID: 15224710

7.  Mitochondrial DNA abnormalities and autistic spectrum disorders

Pons R et al.
J Pediatr. 2004 Jan;144(1):81-5.

OBJECTIVES: To further characterize mtDNA defects associated with autistic features, especially the A3243G mtDNA mutation and mtDNA depletion.Study design Five patients with autistic spectrum disorders and family histories of mitochondrial DNA diseases were studied. We performed mtDNA analysis in all patients and magnetic resonance spectroscopy in three. RESULTS: Three patients manifested isolated autistic spectrum features and two had additional neurologic symptoms. Two patients harbored the A3243G mutation. In two others, the A3243G mutation was not found in accessible tissues but was present in tissues from their mothers. The fifth patient had 72% mtDNA depletion in skeletal muscle. CONCLUSIONS: Autistic spectrum disorders with or without additional neurologic features can be early presentations of the A3243G mtDNA mutation and can be a prominent clinical manifestation of mtDNA depletion. Mitochondrial dysfunction should be considered in patients who have autistic features and associated neurologic findings or who have evidence of maternal inheritance.
PMID: 14722523

8: Linkage and association of the mitochondrial aspartate/glutamate carrier SLC25A12 gene with autism

Ramoz N et al.
Am J Psychiatry. 2004 Apr;161(4):662-9. free online
http://ajp.psychiatryonline.org/cgi/reprint/161/4/662

OBJECTIVE: Autism/autistic disorder (MIM number 209850) is a complex, largely genetic psychiatric disorder. The authors recently mapped a susceptibility locus for autism to chromosome region 2q24-q33 (MIM number 606053). In the present study, genes across the 2q24-q33 interval were analyzed to identify an autism susceptibility gene in this region. METHOD: Mutation screening of positional candidate genes was performed in two stages. The first stage involved identifying, in unrelated subjects showing linkage to 2q24-q33, genetic variants in exons and flanking sequence within candidate genes and comparing the frequency of the variants between autistic and unrelated nonautistic subjects. Two single nucleotide polymorphisms (SNPs) that showed evidence for divergent distribution between autistic and nonautistic subjects were identified, both within SLC25A12, a gene encoding the mitochondrial aspartate/glutamate carrier (AGC1). In the second stage, the two SNPs in SLC25A12 were further genotyped in 411 autistic families, and linkage and association tests were carried out in the 197 informative families. RESULTS: Linkage and association were observed between autistic disorder and the two SNPs, rs2056202 and rs2292813, found in SLC25A12. Using either a single affected subject per family or all affected subjects, evidence for excess transmission was found by the Transmission Disequilibrium Test for rs2056202, rs2292813, and a two-locus G*G haplotype. Similar results were observed using TRANSMIT for the analyses. Evidence for linkage was supported by linkage analysis with the two SNPs, with a maximal multipoint nonparametric linkage score of 1.57 and a maximal multipoint heterogeneity lod score of 2.11. Genotype relative risk could be estimated to be between 2.4 and 4.8 for persons homozygous at these loci. CONCLUSIONS: A strong association of autism with SNPs within the SLC25A12 gene was demonstrated. Further studies are needed to confirm this association and to decipher any potential etiological role of AGC1 in autism.
PMID: 15056512

9: Mitochondrial dysfunction in patients with hypotonia, epilepsy, autism, and developmental delay: HEADD syndrome

Fillano JJ et al.
J Child Neurol. 2002 Jun;17(6):435-9.

A group of 12 children clinically presenting with hypotonia, intractable epilepsy, autism, and developmental delay, who did not fall into previously described categories of mitochondrial encephalomyopathy, were evaluated for mitochondrial respiratory enzyme activity levels, mitochondrial DNA, and mitochondrial structural abnormalities. Reduced levels in specific respiratory activities were found solely in enzymes with subunits encoded by mitochondrial DNA in seven of eight biopsied skeletal muscle specimens evaluated. Five cases exhibited increased levels of large-scale mitochondrial DNA deletions, whereas pathogenic point mutations previously described in association with mitochondrial encephalomyopathies were not found. Mitochondrial structural abnormalities were present in three of four patients examined. Our findings suggest that mitochondrial dysfunction, including extensive abnormalities in specific enzyme activities, mitochondrial structure, and mitochondrial DNA integrity, may be present in children with a clinical constellation including hypotonia, epileptic seizures, autism, and developmental delay. The acronym HEADD is presented here to facilitate pursuit of mitochondrial defects in patients with this clinical constellation after other causes have been excluded.
PMID: 12174964

10. Mitochondrial dysfunction, oxidative stress and neurodegeneration

Mancuso M et al.
J Alzheimers Dis. 2006 Sep;10(1):59-73.

Mitochondria play a critical role in several metabolic processes and apoptotic pathways, regulating life cycle from the cradle to the grave. Despite the evidence of morphological, biochemical and molecular abnormalities in mitochondria in various tissues of patients with neurodegenerative disorders, the question "is mitochondrial dysfunction a necessary step in neurodegeneration?" is still unanswered. Moreover, a growing body of evidence seems to indicate that oxidative stress, which is increased in damaged mitochondria, is an earlier event associated with neurodegeneration. Here we examine the current evidences in this field, which indicate a key role of mitochondria and oxidative stress in contributing to the neurodegenerative processes.
    PMID: 16988483

11:  Autism: a mitochondrial disorder?

Lombard J.
Med Hypotheses. 1998 Jun;50(6):497-500.

Autism is a developmental disorder characterized by disturbance in language, perception and socialization. A variety of biochemical, anatomical and neuroradiographical studies imply a disturbance of brain energy metabolism in autistic patients. The underlying etiology of a disturbed bioenergetic metabolism in autism is unknown. A likely etiological possibility may involve mitochondrial dysfunction with concomitant defects in neuronal oxidative phosphorylation within the central nervous system. This hypothesis is supported by a frequent association of lactic acidosis and carnitine deficiency in autistic patients. Mitochondria are vulnerable to a wide array of endogenous and exogenous factors which appear to be linked by excessive nitric oxide production. Strategies to augment mitochondrial function, either by decreasing production of endogenous toxic metabolites, reducing nitric oxide production, or stimulating mitochondrial enzyme activity may be beneficial in the treatment of autism.
PMID: 9710323

see also:

Mitochondria and Pollutants including Thimerosal
Air Pollution and Mitochondria
Antibiotics and Mitochondria

Return to Table of Contents