nach oben

Molecular Autism

Erschienen in:

Open Access 01.12.2013 | Research

Impairment of fragile X mental retardation protein-metabotropic glutamate receptor 5 signaling and its downstream cognates ras-related C3 botulinum toxin substrate 1, amyloid beta A4 precursor protein, striatal-enriched protein tyrosine phosphatase, and homer 1, in autism: a postmortem study in cerebellar vermis and superior frontal cortex

verfasst von: SHossein Fatemi, Timothy D Folsom, Rachel E Kneeland, Mahtab K Yousefi, Stephanie B Liesch, Paul D Thuras

Erschienen in: Molecular Autism | Ausgabe 1/2013

Abstract

Background

Candidate genes associated with idiopathic forms of autism overlap with other disorders including fragile X syndrome. Our laboratory has previously shown reduction in fragile X mental retardation protein (FMRP) and increase in metabotropic glutamate receptor 5 (mGluR5) in cerebellar vermis and superior frontal cortex (BA9) of individuals with autism.

Methods

In the current study we have investigated expression of four targets of FMRP and mGluR5 signaling - homer 1, amyloid beta A4 precursor protein (APP), ras-related C3 botulinum toxin substrate 1 (RAC1), and striatal-enriched protein tyrosine phosphatase (STEP) - in the cerebellar vermis and superior frontal cortex (BA9) via SDS-PAGE and western blotting. Data were analyzed based on stratification with respect to age (children and adolescents vs. adults), anatomic region of the brain (BA9 vs. cerebellar vermis), and impact of medications (children and adolescents on medications (n = 4) vs. total children and adolescents (n = 12); adults on medications (n = 6) vs. total adults (n = 12)).

Results

There were significant increases in RAC1, APP 120 kDa and APP 80 kDa proteins in BA9 of children with autism vs. healthy controls. None of the same proteins were significantly affected in cerebellar vermis of children with autism. In BA9 of adults with autism there were significant increases in RAC1 and STEP 46 kDa and a significant decrease in homer 1 vs. controls. In the vermis of adult subjects with autism, RAC1 was significantly increased while APP 120, STEP 66 kDa, STEP 27 kDa, and homer 1 were significantly decreased when compared with healthy controls. No changes were observed in vermis of children with autism. There was a significant effect of anticonvulsant use on STEP 46 kDa/β-actin and a potential effect on homer 1/NSE, in BA9 of adults with autism. However, no other significant confound effects were observed in this study.

Conclusions

Our findings provide further evidence of abnormalities in FMRP and mGluR5 signaling partners in brains of individuals with autism and open the door to potential targeted treatments which could help ameliorate the symptoms of autism.

Additional file 1: Table S1: Western blotting results for RAC1, homer 1, APP, STEP, NSE, and β-actin and their ratios in the cerebellar vermis: controls versus people with autism not on medicationsa (anticonvulsant, antidepressant, and antipsychotic drugs). RAC1, Ras-related C3 botulinum toxin substrate 1; APP, amyloid beta A4 precursor protein; STEP, striatal-enriched protein tyrosine phosphatase; NSE, neuronal specific enolase. (DOC 61 KB)

Additional file 2: Table S2: Western blotting results for RAC1, homer 1, APP, STEP, NSE, and β-actin and their ratios in BA9: controls versus people with autism not on medicationsa (anticonvulsant, antidepressant, and antidepressant drugs). RAC1, Ras-related C3 botulinum toxin substrate 1; APP, amyloid beta A4 precursor protein; STEP, striatal-enriched protein tyrosine phosphatase; NSE, neuronal specific enolase; BA9, Brodmann Area 9. (DOC 63 KB)

Authors’ original file for figure 1

Authors’ original file for figure 2

Authors’ original file for figure 3

Authors’ original file for figure 4

Authors’ original file for figure 5

Electronic supplementary material

The online version of this article (doi:10.1186/2040-2392-4-21) contains supplementary material, which is available to authorized users.

Competing interests

The authors declare that they have no competing interests. SH Fatemi has several patents on the use of Reelin as a diagnostic marker for neuropsychiatric disorders but has not derived any financial gains from these patents.

Authors’ contributions

SHF conceived the study, participated in its design, supervised the conduct of all experiments, and contributed to the drafting of the manuscript and its revisions. SBL, REK, and MKH performed western blotting experiments. TDF performed western blotting experiments and contributed to the drafting of the manuscript. PDT contributed to statistical analyses of data. All authors read and approved the final manuscript.

Aβ

Beta amyloid

AMPA

2-Amino-3-(5-methyl-3-oxo-1,2- oxazol-4-yl)propanoic acid

APD

Antipsychotic drug

APP

Amyloid beta A4 precursor protein

BA9

Brodmann area 9

CDC

Centers for disease control and prevention

CTEP

2-Chloro-4-((2,5-dimethyl-1-(4-(trifluoromethoxy)phenyl)-1H-imidazol-4-yl)ethynyl)pyridine

CYFIP

Cytoplasmic FMRP interacting proteins

ERK

Extracellular signal-regulated kinases

FMR1

Fragile X mental retardation 1

FRMP

Fragile X mental retardation protein

FXS

Fragile X syndrome

GABA

Gamma aminobutyric acid

GABRα

GABA_A receptor subunit alpha

GABRβ

GABA_A receptor subunit beta

GFAP

Glial fibrillary acidic protein

GKAP

Guanylate kinase associated protein

GRD

Glycine-like receptor of Drosophila

GTP

Guanine triphosphate

Knockout

LCCH3

Ligand-gated chloride channel homolog 3

LTD

Long-term depression

mGluR5

Metabotropic glutamate receptor 5

MPEP

2-Methyl-6-(phenylethynyl)-pyridine

NMDA

N-methyl-D-aspartate

NSE

Neuronal specific enolase

PBS

Phosphate-buffered saline

PMI

Postmortem interval

PSD

Postsynaptic density

RAC1

Ras-related C3 botulinum toxin substrate 1

RDL

Resistant to dieldrin

Room temperature

STEP

Striatal-enriched protein tyrosine phosphatase

TCI

Transitory cognitive impairment.

Background

Autism is a neurodevelopmental disorder that is characterized by impairments in social reciprocal interaction, communication, and repetitive and stereotyped patterns of behavior, interests, and activities [1]. A number of neuropathologic abnormalities have been characterized in brains from individuals with autism including macrocephaly, volumetric and cellular abnormalities of the frontal cortex, parietal cortex, the limbic structures, and cerebellum, and cortical minicolumnar disorganization [2‐4]. Recently, the Centers for Disease Control and Prevention (CDC) reported a prevalence for autism of 11.3 per 1,000 (one in 88) children aged eight years in the United States in 2008 [5]. This represents a 78% increase in incidence over the previously reported finding of 6.4 per 1,000 in 2002 [5].

Beyond core symptoms, people with autism display a number of comorbidities including seizure disorder, intellectual disability, and other cognitive impairments [6]. The presence of seizure disorder has been estimated from 5% to 40% [6]. Epileptiform activity has been shown to cause brief episodes of impaired cognitive function known as transitory cognitive impairment (TCI) [7, 8] and may contribute to cognitive deficits in individuals with autism. Due to the heterogeneous nature of autism spectrum disorders, it is not surprising that multiple gene families have been implicated in the pathology of autism [9‐11] with 50 gene or gene variants accounting for approximately 30% of autism spectrum cases [11]. Many of these candidate genes overlap with those of other disorders with autistic behavioral deficits including tuberous sclerosis [12], fragile X syndrome (FXS) [13], Rett syndrome [14], and Angelman syndrome [15].

There is a wide degree of overlap between behavioral deficits of autism and FXS, the most common inherited form of intellectual disability. Indeed, approximately 25% to 47% of people with FXS display a comorbid diagnosis of autism [16, 17]. Similar to those diagnosed with autism, people diagnosed with FXS display learning deficits, delayed language acquisition, impaired motor skills, and repetitive behavior [18]. FXS is caused by mutations in the fragile X mental retardation 1 gene (FMR1) leading ultimately to the loss of fragile X mental retardation protein (FMRP) expression. FMRP binds approximately 4% of all mRNAs expressed in brain [19, 20] and acts primarily as a translational repressor. FMRP is expressed in both glia and neurons [21, 22] and in neurons is highly localized to the dendrites and spines [23‐25].

FMRP acts as a negative regulator of group I metabotropic glutamate signaling, particularly metabotropic glutamate receptor 5 (mGluR5) and it is believed that runaway glutamatergic signaling, particularly in the dendrites, is ultimately responsible for the deficits associated with FXS [26]. An anatomical abnormality of neurons from brains of individuals with FXS, autism, and Fmr1 knockout (KO) mice are dendrites with an overabundance of immature long, thin spines [27‐29]. The profusion of dendritic spines could lead to an abnormally large amount of synapse formation and result in the cognitive impairments associated with FXS as well autism. In individuals with autism, greater spine density has been correlated with lower cognitive function [29].

We have previously observed reductions in FMRP in the cerebellar vermis and superior frontal cortex (Brodmann Area 9 (BA9)) of adults with autism and increased expression of mGluR5 in the vermis and BA9 of children with autism [30, 31]. These represent the first findings of altered FMRP and mGluR5 in individuals with autism who do not have a comorbid diagnosis of FXS. In the current study, we have expanded upon our initial studies to examine protein expression of four known targets of FMRP and mGluR5 signaling that may play a role in regulating spine density, protein synthesis, and synaptic transmission: homer 1, amyloid beta A4 precursor protein (APP), ras-related C3 botulinum toxin substrate 1 (RAC1), and striatal-enriched protein tyrosine phosphatase (STEP) in the same brain regions. We hypothesized that targets of FMRP would display altered expression, further implicating this signaling pathway in the etiology of autism. Alterations in levels of these targets of FMRP could potentially be corrected therapeutically to ameliorate symptoms of autism.

Methods

Tissue preparation

The Institutional Review Board of the University of Minnesota, School of Medicine approved all experimental procedures for this study. Frozen postmortem blocks of the superior frontal cortex (BA9) and cerebellar vermis were obtained from the NICHD Brain and Tissue Bank for Developmental Disorders, University of Maryland, Baltimore, MD; the Harvard Brain Tissue Resource Center; the Brain Endowment Bank, Miami, Florida; and the Autism Tissue Program. The tissue samples (Table 1) were prepared as described previously [30, 31] and each sample included both grey and white matter. None of the controls had a history of neuropsychiatric disorders, seizure disorder, or intellectual disability.

Table 1

Demographic data for individuals with autism and controls

Case	Dx	Sex	Age	PMI (hrs)	Ethnicity	Medication history	Cause of death	Seizure	ID	Side of brain	Brain region
UMB-4670	Control	M	4	17	Caucasian	None	Commotio cordis	No	No	Unknown	BA9, Vermis
UMB-4898	Control	M	7	12	Caucasian	Methylphenidate; clonidine	Drowning	No	No	Unknown	Vermis
UMB-1674	Control	M	8	36	Caucasian	None	Drowning	No	No	Unknown	BA9, Vermis
UMB-4787	Control	M	12	15	African American	Montelukast; albuteral; prednisone, loratadine	Asthma	No	No	Unknown	BA9, Vermis
UMB-1823	Control	M	15	18	Caucasian	None	MVA	No	No	Unknown	BA9, Vermis
AN17425	Control	M	16	26.16	Unknown	None	Heart attack	No	No	Left	BA9
AN15105	Control	M	18	19.83	Unknown	None	Unknown	No	No	Unknown	BA9, Vermis
AN03217	Control	M	19	18.58	Caucasian	None	Pneumonia	No	No	Left	BA9
UMB-1846	Control	F	20	9	Caucasian	None	MVA	No	No	Unknown	BA9, Vermis
AN07176	Control	M	21	29.91	Unknown	None	MVA	No	No	Left	BA9
AN14368	Control	M	22	24.2	Unknown	None	Unknown	No	No	Left	BA9
AN19760	Control	M	28	23.25	Unknown	None	Unknown	No	No	Left	BA9
AN15566	Control	F	32	28.92	Unknown	None	Unknown	No	No	Left	BA9, Vermis
UMB-1169	Control	M	33	27	African American	Metoclopramide; loratadine	Dilated cardiomyopathy (morbid obesity)	No	No	Unknown	BA9, Vermis
UMB-1376	Control	M	37	12	African American	None	ASCVD	No	No	Unknown	BA9, Vermis
AN15151	Control	M	41	30.4	Unknown	None	Heart attack	No	No	Unknown	BA9, Vermis
AN19440	Control	F	50	20.25	Unknown	None	Heart attack	No	No	Unknown	BA9
AN12240	Control	M	51	4.75	Caucasian	None	Heart attack	No	No	Right	BA9
AN13295	Control	M	56	22.12	Unknown	None	Unknown	No	No	Right	BA9
AN08873	Autism	M	5	25.5	Caucasian	None	Drowning	No	No	Left	BA9
AN13872	Autism	F	5	32.73	Asian	None	Drowning	No	No	Left	BA9, Vermis
UMB-1349	Autism	M	5	39	Caucasian	None	Drowning	No	No	Unknown	Vermis
UMB-1174	Autism	F	7	14	Caucasian	None	Seizure disorder	Yes	No	Unknown	BA9
UMB-4231	Autism	M	8	12	African American	Olanzapine; galantamine	Drowning	No	Yes	Unknown	BA9, Vermis
AN19511	Autism	M	8	22.16	Caucasian	None	Cancer	Yes	No	Left	BA9, Vermis
UMB-4721	Autism	M	8	16	African American	None	Drowning	No	No	Unknown	Vermis
AN16641	Autism	M	9	27	Caucasian	Carbamazepine; methylphenidate; clonidine	Seizure disorder	Yes	Yes	Left	BA9
AN16115	Autism	F	11	12.88	Caucasian	Carbamazepine; lamotrigine; dextroamphetamine; topiramate	Seizure/drowning	Yes	Yes	Right	Vermis
UMB-4899	Autism	M	14	9	Caucasian	None	Drowning	No	No	Unknown	BA9, Vermis
AN17138	Autism	M	16	24	Asian	Fexofenadine; buspirone; topiramate	Seizure disorder	Yes	No	Left	BA9, Vermis
AN01570	Autism	F	18	6.75	Caucasian	None	Seizure disorder	Yes	No	Right	BA9
AN00764	Autism	M	20	23.66	Caucasian	Erythromycin gel; minocycline	MVA	No	Yes	Left	BA9
UMB-1638	Autism	F	20	50	Caucasian	None	Seizure disorder	Yes	Yes	Unknown	BA9
AN09730	Autism	M	22	25	Caucasian	Aripiprazole; lamotrigine; zonisamide	Aspiration	Yes	No	Left	BA9, Vermis
AN08166	Autism	M	29	43.25	Caucasian	Fexofenadine; ziprasidone HCl; carbamazepine	Seizure (suspected)	Yes	No	Left	BA9, Vermis
AN12457	Autism	F	29	17.83	Caucasian	Fluvoxamine	Seizure disorder	Yes	No	Left	BA9, Vermis
AN11989	Autism	M	30	16.06	Caucasian	None	Heart failure (congestive)	No	No	Left	BA9
AN08792	Autism	M	30	20.33	Caucasian	Cisapride; clorazepate; sodium valproate; phenytoin; folic acid; primidone; phenobarbital; omeprazole; metoclopramide	Gastrointestinal bleeding	Yes	No	Left	BA9, Vermis
UMB-5027	Autism	M	37	26	African American	None	Obstruction of bowel due to adhesion	No	No	Unknown	BA9, Vermis
AN06420	Autism	M	39	13.95	Caucasian	None	Cardiac tamponade	No	No	Left	BA9, Vermis
AN14613	Autism	M	39	22.75	Caucasian	None	Sudden unexpected death	Yes	No	Unknown	BA9
AN17777	Autism	F	49	16.33	Caucasian	Wafarin; venlafaxine; erythromycin; lansoprazole; risperidone; metformin; gabapentin; propranolol; levothyroxine	Pulmonary arrest	No	Yes	Left	BA9, Vermis
AN01093	Autism	M	56	19.48	Caucasian	Benztropine mesylate; haloperidol; lithium; chlorpromazine; alprazolam	Anoxic encephalopathy	Yes	No	Right	BA9, Vermis
Children		Control			Autistic		Change	P -value		d
Age ± SD (years)		11.4 ± 5.22			9.5 ± 4.38		↓16.6%	ns		nd
PMI ± SD (years)		20.6 ± 8.1			20.1 ± 9.94		↓2.4%	ns		nd
Gender		7M			8M:4F		nd	nd		nd
Adults		Control			Autistic		Change	P- value		d
Age ± SD (years)		34.2 ± 13			33.3 ± 11.2		↓2.6%	ns		nd
PMI ± SD (years)		20.9 ± 8.41			24.6 ± 11.1		↑17.7%	ns		nd
Gender		9M:3F			9M:3F		nd	nd		nd

ASCVD, Arteriosclerotic cardiovascular disease; Dx, Diagnosis; Hrs, Hours; PMI, Postmortem interval; M, Male; F, Female; EtOH, Alcohol; ID, Intellectual disability; MVA, Motor vehicle accident; nd, Not determined; ns, Not significant; d, Cohen’s test statistic.

Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and western blot analysis

Tissue samples from the cerebellar vermis (vermal lobule unknown) (in adults, n = 5 controls and 8 autistic adults; in children, n = 6 controls and 8 autistic children) and BA9 (in adults, n = 12 controls and 12 autistic adults; in children, n = 6 controls and 9 autistic children) were prepared. Children were defined as those younger than 13 years of age; adolescents were defined as those between the ages of 13 years to 18 years; and adults were defined as those 19 years of age or older. For this study, children and adolescents were grouped together. Samples were mixed with denaturing SDS sample buffer and denatured by heating at 100°C for 5 minutes. SDS-PAGE gels were prepared using standard Laemmli solutions. For experiments involving RAC1 or STEP, 12% resolving gels were used; 10% resolving gels were used for experiments involving homer 1, neuronal specific enolase (NSE), or β-actin, and for experiments involving APP, 6% resolving gels were used. In all cases, 5% stacking gels were used. Thirty μg of protein per lane was loaded onto the gel and electrophoresed for 15 minutes at 75 V followed by 55 minutes at 150 V at room temperature (RT). We minimized interblot variability by including samples from subjects of each group (control and autism) on each gel. Samples were run in duplicate. Proteins were electroblotted onto nitrocellulose membranes for 2 hrs at 300 mAmp at 4°C as previously described [30, 31]. Blots were blocked with 0.2% I-Block (Tropix, Bedford, MA, USA) in PBS with 0.3% Tween 20 for one hour at RT followed by an overnight incubation in primary antibodies at 4°C. The primary antibodies used were: anti-RAC1 (1:500; BD Transduction, San Jose, CA, USA), anti-APP (1:250; Abcam Inc., Cambridge, MA, USA), anti-homer 1 (1:500; Abnova, Taipei, Taiwan), anti-STEP (1:200; Abgent, San Diego, CA, USA), anti-NSE (1:2,000; Abcam Inc.), and anti-β-actin (1:5,000; Sigma Aldrich, St. Louis, MO, USA). Blots were washed for 30 minutes and incubated in secondary antibodies for one hour at RT as previously described [30, 31]. Secondary antibodies were goat anti-rabbit IgG (A9169, Sigma Aldrich, 1:80,000) or goat anti-mouse IgG (A9044, Sigma Aldrich, 1:80,000). Blots were washed twice in PBS supplemented with Tween-20 (PBST) and bands were visualized using the ECL plus detection system (GE Healthcare, Little Chalfont, Buckinghamshire, UK) and exposed to CL-Xposure film (Thermo Scientific, Rockford, IL, USA). The molecular weights of approximately 120 kDa and 88 kDa (APP); 66 kDa, 61 kDa, 46 kDa, 33 kDa, and 27 kDa (STEP); 46 kDa (NSE); 45 kDa (homer 1); 42 kDa (β-actin); and 21 kDa (RAC1) immunoreactive bands were quantified with background subtraction using a RioRad densitometer and BioRad MultiAnalyst software (Bio-Rad, Hercules, CA, USA). Results obtained were based on two to four independent experiments.

Statistical analysis

Statistical analysis of protein data was performed as previously described [30, 32‐34]. The independent samples t-test was used to compare people with autism to healthy controls. Separate analyses were conducted for children and adults. Analysis of covariance was used to estimate the effect of covariates on group comparisons. Effect sizes were calculated using Cohen’s d statistic, with values >0.8 considered a large effect [35]. For analysis of confounders, significance was set at P <0.06.

Results

All western blotting results were normalized against β-actin and NSE and are expressed as ratios to β-actin and NSE. In the cerebellar vermis of adults with autism we observed significantly increased expression of the RAC1/β-actin ratio (P <0.025, d = 1.62) and the RAC1/NSE ratio (P <0.016, d = 1.73) (Figures 1 and 2, Table 2). We also observed a significant reduction in expression of the APP 120 kDa/β-actin ratio (P <0.018, d = −2.04) and the APP 120 kDa/NSE ratio (P <0.012, d = −2.40) (Figures 1 and 2, Table 2). Ratios for STEP 66 kDa/β-actin (P <0.023, d = −1.51), STEP 66 kDa/NSE (P <0.018, d = −1.59), STEP 33 kDa/β-actin (P <0.024, d = −1.63) and STEP 33 kDa/NSE (P <0.020, d = −1.68) were significantly reduced in the cerebellar vermis of adults with autism (Figures 1 and 3, Table 2). STEP 27 kDa/NSE was also significantly reduced in the cerebellar vermis of subjects with autism (P <0.038, d = −1.40) (Table 2). We did not observe alterations in levels of homer 1 or APP 88 kDa in the cerebellar vermis of adults with autism and there were no significant changes for any of the proteins in the cerebellar vermis of children with autism (Figures 1, 2, 3, Table 2).

Table 2

Western blotting results for RAC1, homer 1, APP, STEP, NSE, and β-actin and their ratios in the cerebellar vermis ^a

	Control	Autistic	Change	P-value	Cohen’s d
Adults
RAC1/β-actin	0.315 ± 0.206	1.3 ± 0.714	313%↑	0.025^b	1.62^b
Homer 1/β-actin	0.237 ± 0.303	0.147 ± 0.147	38%↓	ns	0.42
APP 120 kDa/β-actin	0.091 ± 0.029	0.050 ± 0.016	45%↓	0.018^b	−2.04^b
APP 88 kDa/β-actin	0.08 ± 0.06	0.03 ± 0.02	63%↓	ns	1.26
STEP 66 kDa/β-actin	0.136 ± 0.116	0.025 ± 0.029	82%↓	0.023^b	−1.51^b
STEP 61 kDa/β-actin	0.015 ± 0.028	0.003 ± 0.004	80%↓	ns	−0.67
STEP 46 kDa/β-actin	0.03 ± 0.034	0.034 ± 0.041	13%↑	ns	0.11
STEP 33 kDa/β-actin	0.55 ± 0.38	0.17 ± 0.13	69%↓	0.024^b	−1.63^b
STEP 27 kDa/β-actin	0.70 ± 0.67	0.53 ± 0.39	24%↓	ns	−0.32
β-actin	10.2 ± 1.67	9.06 ± 3.1	11%↓	ns	nd
Children
RAC1/β-actin	1.09 ± 0.545	1.1 ± 0.471	0.9%↑	ns	0.01
Homer 1/β-actin	0.188 ± 0.13	0.218 ± 0.109	16%↑	ns	0.26
APP 120 kDa/β-actin	0.071 ± 0.029	0.077 ± 0.033	8.4%↑	ns	0.19
APP 88 kDa/β-actin	0.084 ± 0.055	0.100 ± 0.071	19%↑	ns	0.25
STEP 66 kDa/β-actin	0.01 ± 0.008	0.059 ± 0.091	490%↑	ns	0.64
STEP 61 kDa/β-actin	0.002 ± 0.002	0.023 ± 0.031	1050%↑	ns	1.15
STEP 46 kDa/β-actin	0.0022 ± 0.0011	0.024 ± 0.024	991%↑	ns	1.16
STEP 33 kDa/β-actin	0.057 ± 0.085	0.13 ± 0.17	128%↑	ns	0.51
STEP 27 kDa/β-actin	0.70 ± 0.68	0.53 ± 0.38	24%↓	ns	−0.72
β-actin	9.48 ± 1.11	9.52 ± 3.71	0.4%↑	ns	nd
Adults
RAC1/NSE	0.23 ± 0.16	0.93 ± 0.49	304%↑	0.016^b	1.73^b
Homer 1/NSE	0.18 ± 0.24	0.099 ± 0.11	45%↓	ns	−0.46
APP 120 kDa/NSE	0.062 ± 0.021	0.031 ± 0.008	50%↓	0.012^b	−2.40^b
APP 88 kDa/NSE	0.06 ± 0.05	0.02 ± 0.01	67%↓	ns	−1.22
STEP 66 kDa/NSE	0.18 ± 0.14	0.032 ± 0.04	82%↓	0.018^b	−1.59^b
STEP 61 kDa/NSE	0.018 ± 0.035	0.004 ± 0.005	78%↓	ns	−0.21
STEP 46 kDa/NSE	0.039 ± 0.041	0.037 ± 0.042	5.1%↓	ns	−0.59
STEP 33 kDa/NSE	0.72 ± 0.49	0.21 ± 0.17	71%↓	0.020^b	−1.68^b
STEP 27 kDa/NSE	1.27 ± 0.82	0.44 ± 0.38	65%↓	0.038^b	−1.40^b
NSE	7.42 ± 1.26	7.69 ± 1.3	3.6%↑	ns	nd
Children
RAC1/NSE	0.84 ± 0.51	0.69 ± 0.23	18%↓	ns	−0.38
Homer 1/NSE	0.13 ± 0.09	0.16 ± 0.07	23%↑	ns	0.33
APP 120 kDa/NSE	0.040 ± 0.025	0.056 ± 0.021	40%↑	ns	0.70
APP 88 kDa/NSE	0.054 ± 0.025	0.072 ± 0.053	33%↑	ns	0.42
STEP 66 kDa/NSE	0.014 ± 0.011	0.102 ± 0.165	628%↑	ns	0.61
STEP 61 kDa/NSE	0.0024 ± 0.001	0.037 ± 0.054	1441%↑	ns	0.96
STEP 46 kDa/NSE	0.003 ± 0.002	0.03 ± 0.047	900%↑	ns	1.02
STEP 33 kDa/NSE	0.078 ± 0.12	0.23 ± 0.33	194%↑	ns	0.55
STEP 27 kDa/NSE	0.36 ± 0.24	0.99 ± 0.93	175%↑	ns	0.77
NSE	6.97 ± 0.84	6.23 ± 1.53	10.6%↓	ns	nd

Values for control and autistic groups are presented as mean ± SD ^aRAC1, ras-related C3 botulinum toxin substrate 1; APP, amyloid beta A4 precursor protein; STEP, striatal-enriched protein tyrosine phosphatase; NSE, neuronal specific enolase; nd, not determined; ns, not significant. ^bStatistically significant.

In BA9 of adults with autism we observed significantly increased ratios for RAC1/β-actin (P <0.031, d = 1.32), RAC1/NSE (P <0.042, d = 1.24) and significantly reduced ratios for homer 1/β-actin (P <0.027, d = −1.37), homer 1/NSE (P <0.020, d = −1.43) (Figures 1 and 4, Table 3). STEP 46 kDa/β-actin ratio (P <0.012, d = 1.10) and STEP 46 kDa/NSE ratio (P <0.020, d = 1.02) were significantly increased in BA9 of adults with autism (Figures 1 and 3, Table 3). In BA9 of children with autism we observed significant increases in ratios for RAC1/β-actin (P <0.008, d = 2.74), RAC1/NSE (P <0.017, d = 2.09), APP 120 kDa/β-actin (P <0.032, d = 2.03), APP 120 kDa/NSE (P <0.017, d = 2.12), APP 88 kDa/β-actin (P <0.025, d = 2.54) and APP 88 kDa/NSE (P <0.012, d = 3.24) (Figures 1 and 4, Table 3). Finally, there was a significant reduction in STEP 61 kDa/β-actin ratio (P <0.036, d = −1.23) in BA9 of children with autism (Figures 1 and 3, Table 3).

Table 3

Western blotting results for RAC1, homer 1, APP, STEP, NSE, and β-actin and their ratios in BA9 ^a

	Control	Autistic	Change	P-value	Cohen’s d
Adults
RAC1/β-actin	0.834 ± 0.554	1.66 ± 0.65	99%↑	0.031^b	1.32^b
Homer 1/β-actin	0.512 ± 0.152	0.324± 0.132	37%↓	0.027^b	−1.37^b
APP 120 kDa/β-actin	0.41 ± 0.23	0.45 ± 0.24	9.8%↑	ns	0.17
APP 88 kDa/β-actin	0.46 ± 0.19	0.53 ± 0.24	15%↑	ns	0.29
STEP 66 kDa/β-actin	0.10 ± 0.07	0.09 ± 0.08	10%↓	ns	−0.11
STEP 61 kDa/β-actin	0.73 ± 0.17	0.74 ± 0.18	1.3%↑	ns	0.08
STEP 46 kDa/β-actin	0.0097 ± 0.006	0.035 ± 0.031	261%↑	0.012^b	1.10
STEP 33 kDa/β-actin	0.20 ± 0.13	0.18 ± 0.09	10%↓	ns	−0.25
STEP 27 kDa/β-actin	0.20 ± 0.12	0.16 ± 0.12	20%↓	ns	−0.29
β-actin	13.2 ± 2.41	13.1 ± 2.31	0.75%↓	ns	nd
Children
RAC1/β-actin	1 ± 0.616	2.8 ± 0.7	180%↑	0.008^b	2.74^b
Homer 1/β-actin	0.46 ± 0.17	0.77 ± 0.31	67%↑	ns	1.21
APP 120 kDa/β-actin	0.20 ± 0.07	0.63 ± 0.25	215%↑	0.032^b	2.03^b
APP 88 kDa/β-actin	0.22 ± 0.03	0.75 ± 0.26	241%↑	0.025^b	2.54^b
STEP 66 kDa/β-actin	0.027 ± 0.026	0.043 ± 0.031	59%↑	ns	0.54
STEP 61 kDa/β-actin	0.59 ± 0.22	0.29 ± 0.24	51%↓	0.036^b	−1.23^b
STEP 46 kDa/β-actin	0.008 ± 0.006	0.013 ± 0.014	62%↑	ns	0.45
STEP 33 kDa/β-actin	0.017 ± 0.026	0.033 ± 0.023	94%↑	ns	0.64
STEP 27 kDa/β-actin	0.17 ± 0.17	0.23 ± 0.10	35%↑	ns	0.45
β-actin	11.5 ± 1.31	11.7 ± 2.05	1.7%↑	ns	nd
Adults
RAC1/NSE	0.50 ± 0.33	0.95 ± 0.37	90%↑	0.042^b	1.24
Homer 1/NSE	0.34 ± 0.12	0.19 ± 0.10	44%↓	0.020^b	−1.43
APP 120 kDa/NSE	0.25 ± 0.12	0.27 ± 0.16	8%↑	ns	0.16
APP 88 kDa/NSE	0.28 ± 0.07	0.32 ± 0.14	14%↑	ns	0.27
STEP 66 kDa/NSE	0.17 ± 0.13	0.14 ± 0.12	18%↓	ns	−0.35
STEP 61 kDa/NSE	1.3 ± 0.34	1.18 ± 0.33	9.2%↓	ns	−0.25
STEP 46 kDa/NSE	0.017 ± 0.011	0.048 ± 0.041	182%↑	0.020^b	1.02^b
STEP 33 kDa/NSE	0.35 ± 0.20	0.28 ± 0.14	20%↓	ns	−0.46
STEP 27 kDa/NSE	0.35 ± 0.21	0.25 ± 0.17	29%↓	ns	−0.53
NSE	9.14 ± 3.73	8.59 ± 1.41	6%↓	ns	nd
Children
RAC1/NSE	0.61 ± 0.42	1.33 ± 0.21	118%↑	0.017^b	2.09^b
Homer 1/NSE	0.28 ± 0.11	0.40 ± 0.15	43%↑	ns	0.94
APP 120 kDa/NSE	0.12 ± 0.04	0.33 ± 0.12	175%↑	0.017^b	2.12^b
APP 88 kDa/NSE	0.13 ± 0.004	0.39 ± 0.11	200%↑	0.012^b	3.24^b
STEP 66 kDa/NSE	0.072 ± 0.081	0.097 ± 0.072	34%↑	ns	0.33
STEP 61 kDa/NSE	1.03 ± 0.25	0.69 ± 0.60	33%↓	ns	−0.68
STEP 46 kDa/NSE	0.021 ± 0.021	0.030 ± 0.033	43%↑	ns	0.37
STEP 33 kDa/NSE	0.050 ± 0.083	0.075 ± 0.054	50%↑	ns	0.37
STEP 27 kDa/NSE	0.49 ± 0.57	0.50 ± 0.26	2%↑	ns	0.031
NSE	6.58 ± 2.48	5.63 ± 1.3	14%↓	ns	nd

Values for control and autistic groups are presented as mean ± SD.^aRAC1, ras-related C3 botulinum toxin substrate 1; APP, amyloid beta A4 precursor protein; STEP, striatal-enriched protein tyrosine phosphatase; NSE, neuronal specific enolase; BA9, Brodmann’s area 9; nd, not determined; ns, not significant. ^bStatistically significant.

In adults, we examined ethnicity, postmortem interval (PMI), intellectual disability, history of seizures, antidepressant, antipsychotic drug (APD), and anticonvulsant use in relation to the outcome measures. PMI, gender and intellectual disability were not significantly related to any of the values expressed as ratios of β-actin or NSE. Adults using anticonvulsants displayed significantly higher STEP 46 kDa/β-actin than all adults who did not use anticonvulsants (including autistic as well as nonautistic) (t(22) = 5.23, P <0.001). Adults with autism who were taking anticonvulsants displayed significantly increased expression of STEP 46 kDa/β-actin versus adults with autism who were not taking anticonvulsants (t(10) = 2.85, P <0.017). Moreover, adults with autism who were taking anticonvulsants displayed significantly increased expression of STEP 46 kDa/β-actin than adult controls (t(15) = 5.28, P <0.001). Finally, there was no significant difference in STEP 46 kDa/β-actin when adult controls were compared against adults with autism who were not taking anticonvulsants (t(17) = 1.44, P <0.17). Increased STEP 46 kDa expression was only seen in ratios compared to β-actin but not NSE, indicating that the difference was not specific to neuronal cells. By the same token, STEP 46 kDa/β-actin value in BA9 was also significantly different in those with seizure history versus those without (t(22) = 3.00, P <0.007). However, no significant difference existed between values in adults with autism with seizure disorder versus adults with autism who did not have seizure disorder, nullifying this association (mean 0.043 ± 0.034 versus 0.023 ± 0.027, P <0.29). Adults with autism who were taking anticonvulsants displayed significantly lower homer 1/NSE in BA9 than controls and adults with autism who were not taking anticonvulsants (t(15) = 2.69, P <0.017). While a comparison of homer 1/NSE values between adults with autism who took anticonvulsants (mean of 0.13 ± 0.086) versus those who did not (mean of 0.23 ± 0.085) did not show a significant difference (P <0.063), it is possible that the reduction of homer 1/NSE is at least partly due to anticonvulsant use.

For those using APDs, there were significantly reduced expression of APP 120 kDa/NSE in BA9 (t(15) = 2.20, P <0.044), APP 88 kDa/NSE in BA9 (t(14) = 2.63, P <0.02), and STEP 33 kDa/β-actin (t(22) = 2.18, P <0.040). However, none of these values showed any significant changes in adults with autism when compared with controls (P <0.8, P <0.55, and P <0.55, respectively). STEP 46 kDa/β-actin was significantly higher (t(22) = 2.79, P <0.011) in BA9 in subjects who took APD medication than in those who did not. However, comparison of values for STEP 46 kDa/β-actin in BA9 between subjects with autism taking APDs versus subjects with autism who did not take APDs was not statistically significant (mean 0.051 ± 0.031 versus 0.027 ± 0.03, respectively, P <0.22). For antidepressant use, the single individual taking antidepressants displayed significantly higher expression of APP 88 kDa/NSE in BA9 than the others (t(14) = 2.51, P <0.025) but this difference only reflects change in one subject and is not extendable to the whole group and thus, not amenable to statistical testing. There was a confounding effect of gender on homer 1/NSE in BA9 of adults (t(14) = 2.04, P <0.060). There was a significant reduction in homer 1/NSE in BA9 of adults with autism versus controls (P <0.020) (see Table 3). The mean for male subjects with autism was 0.262 ± 0.081 and the mean for female subjects with autism was 0.417 ± 0.15 (P <0.061), which was not significantly different. Due to having only two subjects for comparison, we were unable to compare female controls with female autistic subjects. Comparing male controls to male autistic subjects resulted in a significant reduction, similar to that reported in Table 3. It is therefore unlikely that gender has a meaningful effect on homer 1/NSE values. There was also a significantly higher expression of RAC1/NSE in Caucasian than African American subjects in BA9 (t(11) = 2.86, P <0.016). However, this comparison is not relevant as the African American sample size numbered only two subjects. Finally, there was an impact of anticonvulsant use on APP 88 kDa/NSE in BA9 of adults (t(14) = 2.12, P <0.052). However, there was no significant difference between adults with autism versus controls for APP 88 kDa/NSE in BA9 of adults, so this is not meaningful.

For children, ethnicity (Caucasian versus African American), history of seizures, antidepressant, APD, and anticonvulsant use were not significantly related to any of the β-actin or NSE measures. There was significant positive correlation between PMI and APP 88 kDa/NSE in BA9 of children (R = 0.734, P <0.060). However, PMI was not significantly different between control or autistic children in BA9, so this finding is not meaningful. For gender, one female subject displayed significantly higher APP 120 kDa/NSE in BA9 than male subjects (t(6) = 3.16, P <0.02). However, this significance could not be linked to a group of subjects, and thus, was not amenable to further statistical testing. Those with intellectual disability had significantly higher ratios on STEP 46 kDa/β-actin BA9 (t(13) = 2.81, P <0.015]. However, STEP 46 kDa/β-actin in BA9 was not significantly different between controls and those with autism.

To further investigate the effect of medications on our results we performed a second analysis comparing controls to people with autism who were not taking medication (Additional files 1: Table S1 and Additional file 2: Table S2). In the cerebellar vermis of adults, RAC1/NSE and RAC1/β-actin remained significant (Additional file 1: Table S1). In BA9 of adults, RAC1/NSE and RAC1/β-actin remained significant as did RAC1/β-actin in children along with APP 120 kDa/NSE, APP 120 kDa/β-actin, APP 88 kDa/NSE and APP 88 kDa/β-actin (Additional file 2: Table S2). Omitting people with autism who were on medication reduced the total number available for analysis so that seven comparisons could no longer be made, and in fifteen comparisons with a sample of three subjects for people with autism, power was reduced thus, affecting statistical significance.

Finally, we tested to see if there were statistical correlations between levels of FMRP or mGluR5 that we had previously reported [30, 31] and levels of RAC1, STEP 66 kDa, STEP 61 kDa, STEP 46 kDa, STEP 33 kDa, STEP 27 kDa, APP120 kDa, APP 88 kDa, or homer 1. We did not find any significant statistical correlation for either FMRP or mGluR5 with any of the targets investigated in the current study (data not shown).

Discussion

The current studies demonstrated abnormal expression of several downstream biochemical targets of FMRP and mGluR5-mediated signaling in the brains of children and adults with autism. The most salient results included: 1) upregulation of RAC1 in BA9 and the vermis of adults with autism, and in BA9 only among children with autism; 2) upregulation of APP120 and 88 kDa species in BA9 of children with autism and downregulation of APP 120 kDa in the vermis of adults with autism; 3) upregulation of STEP 46 kDa in BA9 and downregulation of STEP 66 kDa, 33 kDa, and 27 kDa in the vermis of adults with autism; 4) downregulation of STEP 61 kDa in BA9 of children with autism; and 5) downregulation of homer 1 in BA9 of adults with autism. We observed more significant effects in BA9 than in the cerebellar vermis, consistent with previous findings in autism [36]. The results summarized above will be discussed further and the significant involvement of these proteins in autism will be analyzed in the following paragraphs.

RAC1 is a member of the Rho family of GTPases, a subfamily of the RAS superfamily of small guanine triphosphate (GTP)-binding proteins. Molecules in this superfamily regulate a number of cellular processes including kinase activation, cytoskeletal rearrangement, cell growth, differentiation, and survival [37]. Members of the Rho family have been implicated in cell proliferation, apoptosis, and regulation of gene expression [37]. RAC1 is involved in remodeling of the actin cytoskeleton [38] and plays an important role in the formation and maturation of dendritic spines as well as regulation of spine density and morphology [39‐43]. Mutations in the Rho GTPase pathway and their regulators have been involved in intellectual disability-related disorders [43]. For example, RAC1 partners with oligophrenin-1 and synaptojanin which have been linked to X-linked intellectual disability and Down’s syndrome, respectively [43‐45]. Overexpression of RAC1 in cultured hippocampal neurons younger than 11 days in vitro resulted in the formation of dendritic spines, clustering of 2-amino-3-(5-methyl-3-oxo-1,2- oxazol-4-yl)propanoic acid (AMPA) receptors and increased the amplitude of miniature excitatory postsynaptic currents, suggesting that RAC1 also enhances excitatory synaptic transmission [42].

RAC1 has been shown to interact with FMRP via cytoplasmic FMRP interacting proteins (CYFIP1/2) [46, 47]. RAC1-induced actin remodeling is altered in mouse fibroblasts that lack FMRP, suggesting a role for FMRP in modulating actin dynamics [48]. More recently, RAC1 expression has been demonstrated to be increased in the hippocampus, cortex, brainstem, and cerebella of Fmr1 KO mice suggesting that FMRP acts as a negative regulator of RAC1 [49]. Our results of increased expression of RAC1 in the cerebellar vermis and BA9 of adults with autism, and in BA9 of children with autism, are novel and have never previously been reported in human postmortem brains of subjects with autism; they may be the result of reduced expression of FMRP in the same regions [30, 31], and they mirror the same findings in Fmr1 KO mice. The overexpression of RAC1, particularly in BA9, may suggest increased excitatory signaling, which could impact synaptic transmission and ultimately cognitive function. This is especially true as studies using transgenic mice with a constitutively active form of RAC1 show overproduction of small abnormal supernumerary spines [43, 50, 51], indicating that overproduction of RAC1 in BA9 of both children and adults with autism is evidence of overabundance of active and abnormal neuronal spines in the brains of people with autism examined in this study. There is evidence in the literature that RAC1 may stimulate stellation of primary astrocytes [52] and increase migration of astrocytes [53]. Additionally, some residual RAC1 mRNA and protein activity has been detected in glial cells [49]. It is tempting to speculate that RAC1 overexpression in autism may also be responsible for increased glial fibrillary acidic protein (GFAP) immunoreactivity detected in the brains of subjects with autism [54]. Higher levels of RAC1 in Caucasian adults with autism compared to African American adults with autism is a novel finding that requires further investigation, and it may be due to genetic or epigenetic factors.

Studies have demonstrated significantly elevated levels of secreted APP and its cleavage products, including beta amyloid (Aβ), in individuals with autism [55‐57]. Our current results, particularly the increased expression of APP 120 kDa and 88 kDa in BA9 of children with autism, verify these earlier findings. Children with severe autism and aggression have been shown to express at least twice as much APP when compared with control children and four times as much APP when compared to children with mild autism [55]. APP translation is normally repressed by FMRP, and mGluR5 activation releases this repression, which may explain why APP increases are seen only in children and not adults [58, 59]. In support of this, levels of mGluR5 were also elevated in the same specimens as previously reported [30, 31], further buttressing the notion that activation of mGluR5 in children may be the cause of our observed increases in APP 88 and 120 kDa. Antipsychotic and antidepressant drugs can affect levels of APP [60, 61]. However, this scenario is unlikely, as evaluation of the impact of these medications on APP values proved not to be meaningful. APP is present presynaptically in the active zone where it has multiple potential interaction partners, including synaptic vesicle proteins, transporters and channels, and cell adhesion molecules [62]. APP is also present postsynaptically where it has been shown to coprecipitate with N-methyl-D-aspartate receptor (NMDAR) subunits [63], and may be involved in surface trafficking of NMDARs [64, 65]. Thus, altered expression of APP may result in altered NMDA signaling, which is crucial for learning and memory. In Fmr1 KO mice, there are excess levels of secreted APP [59]. This excess of APP may result in decreased neural pruning and increased neural proliferation, helping to account for the presence of long, immature dendrites of neurons from patients with autism and FXS [59]. In Fmr1 KO mice that have been engineered to remove one App allele, there is a significant reduction in expression of Aβ and multiple phenotypes of FXS, including the presence of audiogenic seizures, the ratio of immature dendritic spines to mature spines, and long-term depression, were partially or fully corrected after removal of the App allele [66]. While the presence of APP in this report probably reflects neuronal activity, increases in brain APP have also been correlated with increased GFAP in both Alzheimer’s disease [67] and autism [54] and these could also reflect glial activity.

STEP is a phosphatase that is implicated in multiple cellular processes. Kim et al. [68] have found increased tyrosine phosphatase activity in response to mGluR5 stimulation in Fmr1 KO mice, leading to reduced phosphorylated extracellular signal-regulated kinases 1 and 2 (ERK1/2), molecules implicated in induction and maintenance of synaptic plasticity [69]. This tyrosine phosphatase is thought to be STEP, as STEP translation is initiated in response to mGluR stimulation [70]. Alternative splicing of the protein tyrosine phosphatase, nonreceptor type 5 (PTPN5) gene, which encodes STEP, produces four isoforms, however, only two - STEP 61 kDa and STEP 46 kDa - have phosphatase activity [71, 72]. STEP 61 kDa is primarily membrane-bound and expressed in the postsynaptic density extrasynaptic sites, and the endoplasmic reticulum [73]. STEP 46 kDa is primarily cytosolic [73]. Other isoforms of STEP include STEP 66 kDa, STEP 27 kDa, and STEP 33 kDa. STEP 33 kDa is a cleavage product of STEP 61 kDa [74]. Recent investigations have implicated STEP in the etiology of neuropsychiatric disorders [74]. Carty et al. [75] reported significant increases in STEP 61 kDa in the anterior cingulate and dorsolateral prefrontal cortices of subjects with schizophrenia. STEP has roles in mediating NMDA and AMPA receptor endocytosis [70, 76], suggesting that it has a role in mGluR5-mediated long-term depression (LTD), a phenomenon that is enhanced in Fmr1 KO mice [77].

Basal levels of STEP are elevated in Fmr1 KO mice [73]. Recent studies have shown that genetic reduction of STEP improves cognition, synaptic plasticity, and NMDA receptor subunit expression in mouse models of Alzheimer’s disease [78] and reduced seizures, anti-social, and anxiety-related behaviors in Fmr1 KO mice [73]. We observed reduced expression patterns for STEP 66 kDa, 61 kDa, 33 kDa, and 27 kDa with only STEP 46 kDa showing a significant increase in BA9 of adults with autism. As there was an increase in one of the active forms of STEP and a decrease in the other active form, further experiments are needed to determine what role STEP might play in the pathology of autism. However, nonsignificant trends for increase in several isoforms of STEP were observed in the vermis of both children and adults with autism, with large effect sizes. Thus, it is possible that these increases are due to compensatory processes in response to reductions observed in FMRP. Evaluation of the impact of various confounders such as APDs, anticonvulsant drugs, and seizure disorder on STEP values did not prove to be meaningful, with the exception of an anticonvulsant effect on STEP46 kDa/β-actin in BA9. Data from Hasegawa et al. [79] show there is also minimal presence of STEP 46 kDa in reactive astrocytes of gerbil hippocampi and STEP 46 kDa/NSE data reflect STEP 46 kDa species in neuronal cells, which do not show any association with anticonvulsant use. However, evidence for seizure increasing STEP expression remains controversial [73, 80], Thus, one cannot rule out the possibility of multiple factors modulating the levels of STEP molecules [75].

Homer 1 is a postsynaptic density (PSD) scaffolding protein that interacts with mGluR5 to anchor it in the postsynaptic membrane by linking mGluRs with inositol triphosphate, Shank, and PSD-95/Guanylate kinase associated protein (GKAP) [81, 82]. Giuffrida et al. [83] found that in the postsynaptic membrane of neurons from Fmr1 KO mice there was a reduction of mGluR5 in the insoluble fraction of the membrane as well as a reduction in phosphorylated homer 1. The interaction between homer 1 and mGluR5 regulates the cell surface expression, lateral mobility, and signaling of mGluRs [84‐87]. Moreover, disruption of homer 1-mGluR5 interactions blocks mGluR5-induced long-term depression and protein synthesis in wild-type animals but not in Fmr1 KO mice [87]. The authors suggest that in Fmr1 KO mice, interactions between homer 1 and mGluR5 are sufficiently reduced for homer 1 to no longer have a role in the regulation of synaptic plasticity [87]. The observed reduction in homer 1 expression in BA9 of adults with autism may have functional consequences resulting in altered glutamatergic expression and cognitive deficits associated with both FXS and autism. A recent report [88] showed that homer 1 is a risk gene in autism, thus validating our novel finding. Recent evidence indicates that treatment with lithium or valproic acid causes reductions in expression of homer 1b/1c [89]. Thus, we cannot rule out a potential confounding effect of anticonvulsant drug use on homer 1/NSE in BA9 of adults, consistent with this previous finding.

Reduced FMRP expression has also been shown to cause reduction in expression of gamma aminobutyric acid (GABA) receptor subunits (α1, α3, α4, β1, β2, β3, γ1, γ2, δ) in Fmr1 KO mice [90‐93]. Moreover, in the Drosophila melanogaster fragile X model (dFMR1^−/−), there are significant reductions in three receptors that have a high homology with ionotropic GABA receptors: resistant to dieldrin (Rdl), GABA and glycine-like receptor of Drosophila (Grd), and ligand-gated chloride channel homolog 3 (Lcch3) [91]. Our laboratory has found significantly reduced protein expression of various GABA(A) and GABA(B) receptor subunits in three brain regions (namely, the cerebellum, parietal cortex and BA9) of subjects with autism [32‐34]. In BA9 we observed significantly reduced expression of GABA_A receptor subunit α1 (GABRα1), GABA_A receptor subunit α4 (GABRα4), GABA_A receptor subunit α5 (GABRα5), GABA_A receptor subunit β1 (GABRβ1), and GABA_B receptor subunit 1 (GABBR1) [32‐34]. In the parietal cortex we observed significantly reduced expression of GABRα1, GABA_A receptor subunit α2 (GABRα2), GABA_A receptor subunit α3 (GABRα3), GABA_A receptor subunit β3 (GABRβ3) and GABBR1 [32‐34]. In the cerebellum we observed significant reduction in expression of GABRα1, GABRβ3, GABBR1 and GABA_B receptor subunit 2 (GABBR2) [32‐34]. More recently, using a different set of tissue samples, we observed reduced expression of GABRβ3 in the cerebellar vermis of adults with autism [31]. Our consistent findings of reduced GABA receptor protein expression in multiple brain regions of people with autism can be explained by the reduced expression of FMRP.

A further connection to this pathway includes the reduction in Reelin protein in sera and blood from individuals with autism [94, 95]. Recently, mRNA for Reelin, a glycoprotein with multiple roles during development (namely, neuronal cell migration and brain lamination) and in adults (namely, modulating synaptic function), has been identified as a target of FMRP [20]. Reelin has long been considered a potential biomarker for autism due to its roles during development. Our laboratory has demonstrated reduced Reelin protein expression in sera, BA9, and the cerebella of adults with autism [94‐96], supporting the idea that Reelin deficits contribute to the pathology of autism. This reduction in Reelin expression may be due to dysregulation of FMRP expression in people with autism.

Building upon the mGluR5 theory of FXS [26] and our own findings using postmortem brain tissue from people with autism, we hypothesize that activation of mGluR5 in the brains of children with autism [30, 31, 97] leads to subsequent translocation of protein for FMRP from neuronal cell bodies to dendrites, and eventual decrease in FMRP at synapses [25]. Alternatively, an unknown mechanism of reduced expression of FMRP leads to increased mGluR5 signaling. These events may also lead to impaired GABAergic and Reelin signaling, ultimately leading to the morphological, cognitive, and behavioral deficits associated with autism (Figure 5). Deficits in the inhibitory GABAergic system could cause a perturbation in the excitatory/inhibitory balance in brain circuitry, potentially leading to the presence of seizures as well as impaired cognitive function. Deficits in Reelin function would also lead to abnormal brain development and abnormal synaptic transmission. Further evidence for impaired synaptic plasticity comes from altered expression of other targets of FMRP and mGluR5 signaling (namely APP, RAC1, and STEP), resulting in altered dendritic spine morphology and function as well as altered AMPA and NMDA receptor subunit composition (Figure 5). Taken together, abnormal FMRP and mGluR5 signaling in people with autism who do not have a diagnosis of FXS could explain the multiple pathologies of autism. We performed statistical correlations between levels of FMRP and mGluR5 previously reported [30, 31] against RAC1, APP, STEP, and homer 1, which did not result in any significant values (data not shown). However, as relationships between these proteins are neither simple, biochemically well understood, nor stoichiometrically in a 1:1 ratio, this absence of correlation does not minimize the significance of findings in this report. Moreover, as recently shown by Darnell and Klann [98], FMRP target levels may appear unchanged or even decreased due to factors such as age, brain site, increased protein turnover and protein activation state, potentially offsetting target protein increases.

Our results also may open new ways of treating people with autism. Drugs that target metabotropic glutamate receptors have been shown to reverse morphological and behavioral deficits in Fmr1 KO mice. AFQ056, 2-methyl-6-(phenylethynyl)-pyridine (MPEP), and 2-chloro-4-((2,5-dimethyl-1-(4-(trifluoromethoxy)phenyl)-1H-imidazol-4-yl)ethynyl)pyridine (CTEP), antagonists of mGluR5, have been shown to reduce the number of dendritic protrusions of cultured hippocampal neurons and primary visual cortex neurons from Fmr1 KO mice [99‐101]. In Fmr1 KO mice, treatment with MPEP or AFQ056 rescues deficits in prepulse inhibition (PPI) [99, 100], a sensorimotor gating behavior that is disrupted in subjects with autism, schizophrenia, and other psychiatric disorders. CTEP, a newer anti-mGluR5 inhibitor that is more potent and long lasting than MPEP, has been shown to correct for audiogenic seizures, hippocampal long-term depression, and cognitive deficits in Fmr 1 KO mice [101]. The application of Rac1 inhibitor NSC23766 to hippocampal slices from Fmr1 KO mice reduced long-term depression, suggesting that modulation of RAC1 could ameliorate synaptic transmission deficits associated with FXS [49]. Minocycline, a tetracycline derivative, inhibits Aβ-induced neuronal cell death, Aβ fibril formation, and microglial activation [102, 103]. Minocycline can also reverse FXS phenotypes, including dendritic spine immaturity [104]. The latter therapies represent more targeted approaches, and as there are currently no approved glutamatergic inhibitors for use in humans, treatments that focus on mGluR5, RAC1 or APP may provide safe, effective means of ameliorating the behavioral deficits of autism.

Conclusions

Taken together, the results of current postmortem studies provide novel evidence that targets of FMRP and mGluR5 signaling (RAC1, homer 1, APP, and STEP) display altered expression in the cerebellar vermis and BA9 of people with autism. There was a significant confounding effect of anticonvulant drugs on STEP 46 kDa/β-actin and a potential effect on homer 1/NSE in BA9 of adults with autism. These results are consistent with results from FXS animal models, despite the fact that none of the individuals included in the current study were diagnosed with FXS. The altered expression of proteins that may contribute to altered dendritic protein translation (homer 1), altered dendritic morphology (APP and RAC1), and receptor subunit expression (STEP), potentially contribute to the cognitive and behavioral impairments associated with autism and FXS. Our data tie in with our previous experiments, in which we have found reductions in protein expression for Reelin and GABA receptor subunit expression in multiple brain regions of people with autism. We hypothesize that reduction in FMRP and increase in mGluR5 may contribute to the dysregulation of these proteins in subjects with autism, resulting in multiple brain structural and behavioral deficits.

Acknowledgments

Human tissue was obtained from the NICHD Brain and Tissue Bank for Developmental Disorders, University of Maryland, Baltimore, MD (the role of the NICHD Brain and Tissue Bank is to distribute tissue, and therefore, cannot endorse the studies performed or the interpretation of results); the Harvard Brain Tissue Resource Center, which is supported in part by Public Health Service grant number R24 MH068855; the Brain Endowment Bank, which is funded in part by the National Parkinson Foundation, Inc., Miami, Florida; and the Autism Tissue Program, and is gratefully acknowledged. Grant support by the National Institute of Child Health and Human Development (#5R01HD052074-01A2 and 3R01HD052074-03S1) and the Minnesota Medical Foundation Alfred and Ingrid Lenz Harrison Autism Initiative Fund to SHF is gratefully acknowledged. The funding body had no role in the study design, collection, analysis and interpretation of data, in the writing of the manuscript or in the decision to submit the manuscript for publication. SH Fatemi is also supported by the Bernstein Endowed Chair in adult psychiatry.

This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Competing interests

Authors’ contributions

Electronic supplementary material

Additional file 1: Table S1: Western blotting results for RAC1, homer 1, APP, STEP, NSE, and β-actin and their ratios in the cerebellar vermis: controls versus people with autism not on medications^a (anticonvulsant, antidepressant, and antipsychotic drugs). RAC1, Ras-related C3 botulinum toxin substrate 1; APP, amyloid beta A4 precursor protein; STEP, striatal-enriched protein tyrosine phosphatase; NSE, neuronal specific enolase. (DOC 61 KB)

Additional file 2: Table S2: Western blotting results for RAC1, homer 1, APP, STEP, NSE, and β-actin and their ratios in BA9: controls versus people with autism not on medications^a (anticonvulsant, antidepressant, and antidepressant drugs). RAC1, Ras-related C3 botulinum toxin substrate 1; APP, amyloid beta A4 precursor protein; STEP, striatal-enriched protein tyrosine phosphatase; NSE, neuronal specific enolase; BA9, Brodmann Area 9. (DOC 63 KB)

Authors’ original submitted files for images

Below are the links to the authors’ original submitted files for images.

Authors’ original file for figure 1

Authors’ original file for figure 2

Authors’ original file for figure 3

Authors’ original file for figure 4

Authors’ original file for figure 5

American Psychiatric Association: Diagnostic and Statistical Manual of Mental Disorders. 1994, Washington, DC: APA Press, 4

Casanova MF, Buxhoeveden DP, Switala AE, Roy E: Minicolumnar pathology in autism. Neurology. 2002, 58: 428-432. 10.1212/WNL.58.3.428.PubMed

Palmen SJ, van Engeland H, Hof PR, Schmitz C: Neuropathological findings in autism. Brain. 2004, 127: 2572-2583. 10.1093/brain/awh287.PubMed

McCaffrey P, Deutsch CK: Macrocephaly and the control of brain growth in autistic disorders. Prog Neurobiol. 2005, 77: 38-56. 10.1016/j.pneurobio.2005.10.005.

Autism and Developmental Disabilities Monitoring Network Surveillance Year 2008 Principal Investigators; Centers for Disease Control and Prevention: Prevalence of autism spectrum disorders-Autism and Developmental Disabilities Monitoring Network, 14 sites, United States, 2008. MMWR Surveill Summ. 2012, 61: 1-19.

Canitano R: Epilepsy in autism spectrum disorders. Eur Child Adolesc Psychiatry. 2006, 16: 61-66.PubMed

Aarts JH, Binnie CD, Smit AM, Wilkins AJ: Selective cognitive impairment during focal and generalized epileptiform EEG activity. Brain. 1984, 107: 293-308. 10.1093/brain/107.1.293.PubMed

Binnie CD: Cognitive impairment during epileptiform discharges: is it ever justifiable to treat the EEG?. Lancet Neurol. 2003, 2: 725-730. 10.1016/S1474-4422(03)00584-2.PubMed

Geschwind DH: Autism: many genes, common pathways?. Cell. 2008, 135: 391-395. 10.1016/j.cell.2008.10.016.PubMedCentralPubMed

10.

Abrahams BS, Geschwind DH: Advances in autism genetics: on the threshold of a new neurobiology. Nat Rev Genet. 2008, 9: 341-355. 10.1038/nrg2346.PubMedCentralPubMed

11.

Sakai Y, Shaw CA, Dawson BC, Dugas DV, Al-Mohtaseb Z, Hill DE, Zoghbi HY: Protein interactome reveals converging molecular pathways among autism disorders. Sci Transl Med. 2011, 3: 86ra49-10.1126/scitranslmed.3002166.PubMedCentralPubMed

12.

Numis AL, Major P, Montenegro MA, Muzykewicz DA, Pulsifer MB, Thiele EA: Identification of risk factors for autism spectrum disorders in tuberous sclerosis complex. Neurology. 2011, 76: 981-987. 10.1212/WNL.0b013e3182104347.PubMedCentralPubMed

13.

Hagerman R, Au J, Hagerman P: FMR1 premutation and full mutation molecular mechanisms related to autism. J Neurodev Disord. 2011, 3: 211-224. 10.1007/s11689-011-9084-5.PubMedCentralPubMed

14.

Loat CS, Curran S, Lewis CM, Duvall J, Geschwind D, Bolton P, Craig IW: Methyl-CpG-binding protein 2 polymorphisms and vulnerability to autism. Genes Brain Behav. 2008, 7: 754-760. 10.1111/j.1601-183X.2008.00414.x.PubMedCentralPubMed

15.

Bonati MT, Russo S, Finelli P, Valsecchi MR, Cavalleri F, Roberts W, Elia M, Larizza L: Evaluation of autism traits in Angelman syndrome: a resource to unfold autism genes. Neurogenetics. 2007, 8: 169-178. 10.1007/s10048-007-0086-0.PubMed

16.

Hatton DD, Sideris J, Skinner M, Mankowski J, Bailey DB, Roberts J, Mirrett P: Autistic behavior in children with Fragile X syndrome: prevalence, stability, and the impact of FMRP. Am J Med Genet A. 2006, 140A: 1804-1813. 10.1002/ajmg.a.31286.PubMed

17.

Kauffman WE, Cortell R, Kau A, Bukelis I, Tierney E, Gray R, Cox C, Capone G, Stanard P: Autism spectrum disorder in fragile X syndrome: Communication, social interaction, and specific behaviors. Am J Med Genet A. 2004, 129A: 225-234. 10.1002/ajmg.a.30229.

18.

Hagerman RJ, Staley LW, O’Conner R, Lugenbeel K, Nelson D, McLean SD, Taylor A: Learning-disabled males with a fragile X CGG expansion in the upper premutation size range. Pediatrics. 1996, 97: 122-126.PubMed

19.

Bassell GJ, Warren ST: Fragile X syndrome: loss of local mRNA regulation alters synaptic development and function. Neuron. 2008, 60: 201-214. 10.1016/j.neuron.2008.10.004.PubMedCentralPubMed

20.

Darnell JC, Van Driesche SJ, Zhang C, Hung KY, Mele A, Fraser CE, Stone EF, Chen C, Fak JJ, Chi SW, Licatalosi DD, Richter JD, Darnell RB: FMRP stalls ribosomal translocation on mRNAs linked to synaptic function and autism. Cell. 2011, 146: 247-261. 10.1016/j.cell.2011.06.013.PubMedCentralPubMed

21.

Devys D, Lutz Y, Rouyer N, Bellocq JP, Mandel JL: The FMR-1 protein is cytoplasmic, most abundant in neurons and appears normal in carriers of a fragile X premutation. Nat Genet. 1993, 4: 335-340. 10.1038/ng0893-335.PubMed

22.

Pacey LK, Doering LC: Developmental expression of FMRP in the astrocyte lineage: implications for fragile X syndrome. Glia. 2007, 55: 1601-1609. 10.1002/glia.20573.PubMed

23.

Weiler IJ, Irwin SA, Klintsova AY, Spencer CM, Brazelton AD, Miyashiro K, Comery TA, Patel B, Eberwine J, Greenough WT: Fragile X mental retardation protein is translated near synapses in response to neurotransmitter activation. Proc Natl Acad Sci U S A. 1997, 94: 5395-5400. 10.1073/pnas.94.10.5395.PubMedCentralPubMed

24.

Bakker CE, de Diego OY, Bontekoe C, Raghoe P, Luteijn T, Hoogeveen AT, Oostra BA, Willemsen R: Immunocytochemical and biochemical characterization of FMRP, FXR1P, and FXR2P in the mouse. Exp Cell Res. 2000, 258: 162-170. 10.1006/excr.2000.4932.PubMed

25.

Krueger DD, Bear MF: The mGluR theory of fragile X syndrome. Autism Spectrum Disorders. Edited by: Amaral DG, Dawson G, Geschwind DH. 2011, New York: Oxford University Press, USA, 1239-1258.

26.

Bear MF, Huber KM, Warren ST: The mGluR theory of Fragile X mental retardation. Trends Neurosci. 2004, 27: 370-377. 10.1016/j.tins.2004.04.009.PubMed

27.

Grossman AW, Elisseou NM, McKinney BC, Greenough WT: Hippocampal pyramidal cells in adult Fmr1 knockout mice exhibit an immature-appearing profile of dendritic spines. Brain Res. 2006, 1084: 158-164. 10.1016/j.brainres.2006.02.044.PubMed

28.

Hutsler JJ, Zhang H: Increased dendritic spine densities on cortical projection neurons in autism spectrum disorders. Brain Res. 2010, 1309: 83-94.PubMed

29.

Irwin SA, Patel B, Idupulapati M, Harris JB, Crisostomo RA, Larsen BP, Kooy F, Willems PJ, Cras P, Kozlowski PB, Swain RA, Weiler IJ, Greenough WT: Abnormal dendritic spine characteristics in the temporal and visual cortices of patients with fragile-X syndrome: a quantitative examination. Am J Med Genet. 2001, 98: 161-171. 10.1002/1096-8628(20010115)98:2<161::AID-AJMG1025>3.0.CO;2-B.PubMed

30.

Fatemi SH, Folsom TD: Dysregulation of fragile X mental retardation protein and metabotropic glutamate receptor 5 in superior frontal cortex of subjects with autism: a postmortem brain study. Mol Autism. 2011, 2: 6-10.1186/2040-2392-2-6.PubMedCentralPubMed

31.

Fatemi SH, Folsom TD, Kneeland RE, Liesch SB: Metabotropic glutamate receptor 5 upregulation in children with autism is associated with underexpression of both Fragile X mental retardation protein and GABA_A receptor beta 3 in adults with autism. Anat Rec. 2011, 294: 1635-1645. 10.1002/ar.21299.

32.

Fatemi SH, Reutiman TJ, Folsom TD, Thuras PD: GABA(A) Receptor downregulation in brains of subjects with autism. J Autism Dev Disord. 2009, 39: 223-230. 10.1007/s10803-008-0646-7.PubMedCentralPubMed

33.

Fatemi SH, Folsom TD, Reutiman TJ, Thuras PD: Expression of GABA(B) receptors is altered in brains of subjects with autism. Cerebellum. 2009, 8: 64-69. 10.1007/s12311-008-0075-3.PubMedCentralPubMed

34.

Fatemi SH, Reutiman TJ, Folsom TD, Rooney RJ, Patel DH, Thuras PD: mRNA and Protein levels for GABA(A) alpha 4, alpha 5, beta 1, and GABA(B)R1 receptors are altered in brains from subjects with autism. J Autism Dev Disord. 2010, 40: 743-750. 10.1007/s10803-009-0924-z.PubMedCentralPubMed

35.

Cohen J: A power primer. Psychol Bull. 1992, 112: 155-159.PubMed

36.

Voineagu I, Wang X, Johnston P, Lowe JK, Tian Y, Horvath S, Mill J, Cantor RM, Blencowe BJ, Geschwind DH: Transcriptomic analysis of autistic brain reveals convergent molecular pathology. Nature. 2011, 474: 380-384. 10.1038/nature10110.PubMedCentralPubMed

37.

Bustelo XR, Sauzeau V, Berenjeno IM: GTP-binding proteins of the Rho/Rac family: regulation, effectors and functions in vivo. Bioessays. 2007, 29: 356-370. 10.1002/bies.20558.PubMedCentralPubMed

38.

Kaibuchi K, Kuroda S, Amano M: Regulation of the cytoskeleton and cell adhesion by the Rho family GTPases in mammalian cells. Annu Rev Biochem. 1999, 68: 459-486. 10.1146/annurev.biochem.68.1.459.PubMed

39.

Corbetta S, Gualdoni S, Ciceri G, Monari M, Zuccaro E, Tybulewicz VL, de Curtis I: Essential role of Rac1 and Rac3 GTPases in neuronal development. FASEB J. 2009, 23: 1347-1357. 10.1096/fj.08-121574.PubMed

40.

Negishi M, Katoh H: Rho family GTPases and dendrite plasticity. Neuroscientist. 2005, 11: 187-191. 10.1177/1073858404268768.PubMed

41.

Tashiro A, Yuste R: Regulation of dendritic spine motility and stability by Rac1 and Rho kinase: evidence for two forms of spine motility. Mol Cell Neurosci. 2004, 26: 429-440. 10.1016/j.mcn.2004.04.001.PubMed

42.

Wiens KM, Lin H, Liao D: Rac1 induces the clustering of AMPA receptors during spinogenesis. J Neurosci. 2005, 25: 10627-10636. 10.1523/JNEUROSCI.1947-05.2005.PubMed

43.

Yuste R: Dendritic Spines. 2010, Cambridge, MA: The MIT Press

44.

Billuart P, Bienvenu T, Ronce N, Des Portes V, Vinet MC, Zemni R, Roest Crollius H, Carrié A, Fauchereau F, Cherry M, Briault S, Hamel B, Fryns JP, Beldjord C, Kahn A, Moraine C, Chelly J: Oligophrenin-1 encodes a rhoGAP protein involved in X-linked mental retardation. Nature. 1998, 392: 923-926. 10.1038/31940.PubMed

45.

Arai Y, Ijuin T, Takenawa T, Becker LE, Takashima S: Excessive expression of synaptojanin in brains with Down syndrome. Brain Dev. 2002, 24: 67-72. 10.1016/S0387-7604(01)00405-3.PubMed

46.

Schenck A, Bardoni B, Moro A, Bagni C, Mandel JL: A highly conserved protein family interacting with the fragile X mental retardation protein (FMRP) and displaying selective interactions with FMRP-related proteins FXR1P and FXR2P. Proc Natl Acad Sci U S A. 2001, 98: 8844-8849. 10.1073/pnas.151231598.PubMedCentralPubMed

47.

Schenck A, Bardoni B, Langmann C, Harden N, Mandel JL, Giangrande A: CYFIP/Sra-1 controls neuronal connectivity in Drosophila and links the Rac1 GTPase pathway to the fragile X protein. Neuron. 2003, 38: 887-898. 10.1016/S0896-6273(03)00354-4.PubMed

48.

Castets M, Schaeffer C, Bechara E, Schenck A, Khandjian EW, Luche S, Moine H, Rabilloud T, Mandel JL, Bardoni B: FMRP interferes with the Rac1 pathway and controls actin cytoskeleton dynamics in murine fibroblasts. Hum MolGenet. 2005, 14: 835-844.

49.

Bongmba OY, Martinez LA, Elhardt ME, Butler K, Tejada-Simon MV: Modulation of dendritic spines and synaptic function by Rac1: A possible link to fragile X syndrome pathology. Brain Res. 2011, 1399: 79-95.PubMedCentralPubMed

50.

Luo L, Hensch TK, Ackerman L, Barbel S, Jan LY, Jan YN: Differential effects of the Rac GTPase on Purkinje cell axons and dendritic trunks and spines. Nature. 1996, 379: 837-840. 10.1038/379837a0.PubMed

51.

Nakayama AY, Harms MB, Luo L: Small GTPases Rac and Rho in the maintenance of dendritic spines and branches in hippocampal pyramidal neurons. J Neurosci. 2000, 20: 5329-5338.PubMed

52.

Racchetti G, D’Alessandro R, Meldolesi J: Astrocyte stellation, a process dependent on Rac1 is sustained by the regulated exocytosis of enlargeosomes. Glia. 2012, 60: 465-475. 10.1002/glia.22280.PubMedCentralPubMed

53.

Bourguignon LY, Gilad E, Peyrollier K, Brightman A, Swanson RA: Hyaluronan-CD44 interaction stimulates Rac1 signaling and PKN gamma kinase activation leading to cytoskeleton function and cell migration in astrocytes. J Neurochem. 2007, 101: 1002-1017. 10.1111/j.1471-4159.2007.04485.x.PubMed

54.

Laurence JA, Fatemi SH: Glial fibrillary acidic protein is elevated in superior frontal, parietal and cerebellar cortices of autistic subjects. Cerebellum. 2005, 4: 201-210.

55.

Sokol DK, Chen D, Farlow MR, Dunn DW, Maloney B, Zimmer JA, Lahiri DK: High levels of Alzheimer beta-amyloid precursor protein (APP) in children with severely autistic behavior and aggression. J Child Neurol. 2006, 21: 444-449.PubMed

56.

Bailey AR, Giunta BN, Obregon D, Nikolic WV, Tian J, Sanberg CD, Sutton DT, Tan J: Peripheral biomarkers in autism: Secreted amyloid precursor protein-alpha as a probable key player in early diagnosis. Int J Clin Exp Med. 2008, 1: 338-344.PubMedCentralPubMed

57.

Ray B, Long JM, Sokol DK, Lahiri DK: Increased secreted amyloid precursor protein-α (sAPPα) in severe autism: proposal of a specific, anabolic pathway and putative biomarker. PLoS One. 2011, 6: e20405-10.1371/journal.pone.0020405.PubMedCentralPubMed

58.

Sokol DK, Maloney B, Long JM, Ray B, Lahiri DK: Autism, Alzheimer disease, and fragile X: APP, FMRP, and mGluR5 are molecular links. Neurology. 2011, 76: 344-1352.

59.

Westmark CJ, Malter JS: FMRP mediates mGluR5-dependent translation of amyloid precursor protein. PLoS Biol. 2007, 5: e52-10.1371/journal.pbio.0050052.PubMedCentralPubMed

60.

Wang H, Xu H, Dyck LE, Li XM: Olanzapine and quetiapine protect PC12 cells from beta-amyloid peptide(25–35)-induced oxidative stress and the ensuing apoptosis. J Neurosci Res. 2005, 81: 572-580. 10.1002/jnr.20570.PubMed

61.

Chavant F, Deguil J, Pain S, Ingrand I, Milin S, Fauconneau B, Pérault-Pochat MC, Lafay- Chebassier C: Imipramine, in part through tumor necrosis factor alpha inhibition, prevents cognitive decline and beta-amyloid accumulation in a mouse model of Alzheimer’s disease. J Pharmacol Exp Ther. 2010, 332: 505-514. 10.1124/jpet.109.162164.PubMed

62.

Volknandt W, Karas M: Proteomic analysis of the presynaptic active zone. Exp Brain Res. 2012, 217: 449-461. 10.1007/s00221-012-3031-x.PubMed

63.

Innocent N, Cousins SL, Stephenson FA: NMDA receptor/amyloid precursor protein interactions: a comparison between wild-type and amyloid precursor protein mutations associated with familial Alzheimer’s disease. Neurosci Lett. 2012, 515: 131-136. 10.1016/j.neulet.2012.03.029.PubMed

64.

Cousins SL, Hoey SE, Stephenson FA, Perkinton MS: Amyloid precursor protein 695 associates with assembled NR2A- and NR2B-containing NMDA receptors to result in the enhancement of their cell surface delivery. J Neurochem. 2009, 111: 1501-1513. 10.1111/j.1471-4159.2009.06424.x.PubMed

65.

Hoe HS, Fu Z, Makarova A, Lee JY, Lu C, Feng L, Pajoohesh-Ganji A, Matsuoka Y, Hyman BT, Ehlers MD, Vicini S, Pak DT, Rebeck GW: The effects of amyloid precursor protein on postsynaptic composition and activity. J Biol Chem. 2009, 284: 8495-8506.PubMedCentralPubMed

66.

Westmark CJ, Westmark PR, O’Riordan KJ, Ray BC, Hervey CM, Salamat MS, Abozeid SH, Stein KM, Stodola LA, Tranfaglia M, Burger C, Berry-Kravis EM, Malter JS: Reversal of fragile X phenotypes by manipulation of AβPP/Aβ levels in Fmr1KO mice. PLoS One. 2011, 6: e26549-10.1371/journal.pone.0026549.PubMedCentralPubMed

67.

Matsui T, Ingelsson M, Fukumoto H, Ramasamy K, Kowa H, Frosch MP, Irizarry MC, Hyman BT: Expression of APP pathway mRNAs and proteins in Alzheimer’s disease. Brain Res. 2007, 1161: 116-123.PubMed

68.

Kim SH, Markham JA, Weiler IJ, Greenough WT: Aberrant early-phase ERK inactivation impedes neuronal function in fragile X syndrome. Proc Natl Acad Sci U S A. 2008, 105: 4429-4434. 10.1073/pnas.0800257105.PubMedCentralPubMed

69.

Canal F, Palygin O, Pankratov Y, Corrêa SA, Müller J: Compartmentalization of the MAPK scaffold protein KSR1 modulates synaptic plasticity in hippocampal neurons. FASEB. 2011, 25: 2362-2372. 10.1096/fj.10-173153.

70.

Zhang Y, Venkitaramani DV, Gladding CM, Zhang Y, Kurup P, Molnar E, Collingridge GL, Lombroso PJ: The tyrosine phosphatase STEP mediates AMPA receptor endocytosis after metabotropic glutamate receptor stimulation. J Neurosci. 2008, 28: 10561-10566. 10.1523/JNEUROSCI.2666-08.2008.PubMedCentralPubMed

71.

Sharma E, Zhao F, Bult A, Lambroso PJ: Identification of two alternatively spliced transcripts of STEP: a subfamily of brain-enriched protein tyrosine phosphatases. Brain Res Mol Brain Res. 1995, 32: 87-93. 10.1016/0169-328X(95)00066-2.PubMed

72.

Bult A, Zhao F, Dirkx R, Raghunathan A, Solimena M, Lombroso PJ: STEP: a family of brain-enriched PTPs. Alternative splicing produces transmembrane, cytosolic and truncated isoforms. Eur J Cell Biol. 1997, 72: 337-344.PubMed

73.

Goebel-Goody SM, Wilson-Wallis ED, Royston S, Tagliatela SM, Naegele JR, Lombroso PJ: Genetic manipulation of STEP reverses behavioral abnormalities in a fragile X syndrome mouse model. Genes Brain Behav. 2012, 11: 586-600. 10.1111/j.1601-183X.2012.00781.x.PubMedCentralPubMed

74.

Fitzpatrick CJ, Lombroso P: The Role of Striatal-Enriched Protein Tyrosine Phosphatase (STEP) in Cognition. Front Neuroanat. 2011, 5: 47-PubMedCentralPubMed

75.

Carty NC, Xu J, Kurup P, Brouillette J, Goebel-Goody SM, Austin DR, Yuan P, Chen G, Correa PR, Haroutunian V, Pittenger C, Lombroso PJ: The tyrosine phosphatase STEP: implications in schizophrenia and the molecular mechanism underlying antipsychotic medications. Transl Psychiatry. 2012, 2: e137-10.1038/tp.2012.63.PubMedCentralPubMed

76.

Kurup P, Zhang Y, Xu J, Venkitaramani DV, Haroutunian V, Greengard P, Nairn AC, Lombroso PJ: Abeta-mediated NMDA receptor endocytosis in Alzheimer’s disease involves ubiquitination of the tyrosine phosphatase STEP61. J Neurosci. 2010, 30: 5948-5957. 10.1523/JNEUROSCI.0157-10.2010.PubMedCentralPubMed

77.

Huber KM, Gallagher SM, Warren ST, Bear MF: Altered synaptic plasticity in a mouse model of fragile X mental retardation. Proc Acad Natl Sci U S A. 2002, 99: 7746-7750. 10.1073/pnas.122205699.

78.

Zhang Y, Kurup P, Xu J, Carty N, Fernandez SM, Nygaard HB, Pittenger C, Greengard P, Strittmatter SM, Nairn AC, Lombroso PJ: Genetic reduction of striatal-enriched tyrosine phosphatase (STEP) reverses cognitive and cellular deficits in an Alzheimer’s disease mouse model. Proc Natl Acad Sci U S A. 2010, 107: 19014-19019. 10.1073/pnas.1013543107.PubMedCentralPubMed

79.

Hasegawa S, Morioka M, Goto S, Korematsu K, Okamura A, Yano S, Kai Y, Hamada JI, Ushio Y: Expression of neuron specific phosphatase, striatal enriched phosphatase (STEP) in reactive astrocytes after transient forebrain ischemia. Glia. 2000, 29: 316-329. 10.1002/(SICI)1098-1136(20000215)29:4<316::AID-GLIA3>3.0.CO;2-O.PubMed

80.

Briggs SW, Walker J, Asik K, Lombroso P, Naegele J, Aaron G: STEP regulation of seizure thresholds in the hippocampus. Epilepsia. 2011, 52: 497-506. 10.1111/j.1528-1167.2010.02912.x.PubMedCentralPubMed

81.

Tu JC, Xiao B, Yuan JP, Lanahan AA, Leoffert K, Li M, Linden DJ, Worley PF: Homer binds a novel prolin-rich motif and links group 1 metabotropic glutamate receptors with IP3 receptors. Neuron. 1998, 21: 717-726. 10.1016/S0896-6273(00)80589-9.PubMed

82.

Tu JC, Xiao B, Naisbitt S, Yuan JP, Petralia RS, Brakeman P, Doan A, Aakalu VK, Lanahan AA, Sheng M, Worley PF: Coupling of mGluR/Homer and PSD-95 complexes by the Shank family of postsynaptic density protein. Neuron. 1999, 23: 583-592. 10.1016/S0896-6273(00)80810-7.PubMed

83.

Giuffrida R, Musumeci S, D’Antoni S, Bonaccorso CM, Giuffrida-Stella AM, Oostra BA, Catania MV: A reduced number of metabotropic glutamate subtype 5 receptors are associated with constitutive homer proteins in a mouse model of fragile X syndrome. J Neurosci. 2005, 25: 8908-8916. 10.1523/JNEUROSCI.0932-05.2005.PubMed

84.

Ango F, Robbe D, Muller T, Tu JC, Xiao B, Worley PF, Pin JP, Bockaert J, Fagni L: Homer-dependent cell surface expression of metabotropic glutamate receptor type 5 in neurons. Mol Cell Neurosci. 2002, 20: 323-329. 10.1006/mcne.2002.1100.PubMed

85.

Kammermeier PJ: Endogenous homer proteins regulate metabotropic glutamate receptor signaling in neurons. J Neurosci. 2008, 28: 8560-8567. 10.1523/JNEUROSCI.1830-08.2008.PubMed

86.

Sergé A, Fourgeaud L, Hémar A, Choquet D: Receptor activation and Homer differentially control the lateral mobility of metabotropic glutamate receptor 5 in the neuronal membrane. J Neurosci. 2002, 22: 3910-3920.PubMed

87.

Ronesi JA, Huber KM: Homer interactions are necessary for metabotropic glutamate receptor-induced long-term depression and translational activation. J Neurosci. 2008, 28: 543-547. 10.1523/JNEUROSCI.5019-07.2008.PubMed

88.

Kelleher RJ, Geigenmüller U, Hovhannisyan H, Trautman E, Pinard R, Rathmell B, Carpenter R, Margulies D: High-throughput sequencing of mGluR signaling pathway genes reveals enrichment of rare variants in autism. PLoS One. 2012, 7: e35003-10.1371/journal.pone.0035003.PubMed

89.

de Bartolomeis A, Tomasetti C, Cicale M, Yuan PX, Manji HK: Chronic treatment with lithium or valproate modulates the expression of Homer1b/c and its related genes Shank and Inositol 1,4,5-trisphosphate receptor. Eur Neuropsychopharmacol. 2012, 22: 527-535. 10.1016/j.euroneuro.2011.11.006.PubMedCentralPubMed

90.

El Idrissi A, Ding XH, Scalia J, Trenkner E, Brown WT, Dobkin C: Decreased GABA_A receptor expression in the seizure-prone fragile X mouse. Neurosci Lett. 2005, 377: 141-146. 10.1016/j.neulet.2004.11.087.PubMed

91.

D’Hulst C, De Geest N, Reeve SP, Van Dam D, De Deyn PP, Hassan BA, Kooy RF: Decreased expression of the GABA_A receptor in fragile X syndrome. Brain Res. 2006, 1121: 238-245. 10.1016/j.brainres.2006.08.115.PubMed

92.

Gantois I, Vandescompele J, Speleman F, Reyniers E, D’Hooge R, Severijnen LA, Willemsen R, Tassone F, Kooy RF: Expression profiling suggests underexpression of the GABAA receptor subunit delta in the fragile X knockout mouse model. Neurobiol Dis. 2006, 21: 346-357. 10.1016/j.nbd.2005.07.017.PubMed

93.

Hong A, Zhang A, Ke Y, El Idrissi A, Shen CH: Downregulation of GABA(A) β subunits is transcriptionally controlled by Fmr1p. J Mol Neurosci. 2012, 46: 272-275. 10.1007/s12031-011-9531-5.PubMed

94.

Fatemi SH, Stary JM, Halt AR, Realmuto GR: Dysregulation of Reelin and Bcl-2 proteins in autistic cerebellum. J Autism Dev Disord. 2001, 31: 529-535. 10.1023/A:1013234708757.PubMed

95.

Fatemi SH, Stary JM, Egan EA: Reduced blood levels of reelin as a vulnerability factor in pathophysiology of autistic disorder. Cell Mol Neurobiol. 2002, 22: 139-152. 10.1023/A:1019857620251.PubMed

96.

Fatemi SH, Snow AV, Stary JM, Araghi-Niknam M, Reutiman TJ, Lee S, Brooks AI, Pearce DA: Reelin signaling is impaired in autism. Biol Psychiatry. 2005, 57: 777-787. 10.1016/j.biopsych.2004.12.018.PubMed

97.

Fatemi SH, Folsom TD: The role of fragile X mental retardation protein in major mental disorders. Neuropharmacology. 2012, 60: 1221-1226.

98.

Darnell JC, Klann E: The translation of translational control by FMRP: therapeutic targets for FXS. Nat Neurosci. 2013, 10.1038/nn.3379.

99.

de Vrij FM, Levenga J, van der Linde HC, Koekkoek SK, De Zeeuw CI, Nelson DL, Oostra BA, Willemsen R: Rescue of behavioral phenotype and neuronal protrusion morphology in Fmr1 KO mice. Neurobiol Dis. 2008, 31: 127-132. 10.1016/j.nbd.2008.04.002.PubMedCentralPubMed

100.

Levenga J, Hayashi S, de Vrij FM, Koekkoek SK, van der Linde HC, Nieuwenhuizen I, Song C, Buijsen RA, Pop AS, Gomezmancilla B, Nelson DL, Willemsen R, Gasparini F, Oostra BA: AFQ506, a new mGluR5 antagonist for treatment of fragile X syndrome. Trends Mol Med. 2011, 16: 516-527.

101.

Michalon A, Sidorov M, Ballard TM, Ozmen L, Spooren W, Wettstein JG, Jaeschke G, Bear MF, Lindemann L: Chronic pharmacological mGlu5 inhibition corrects fragile X in adult mice. Neuron. 2012, 74: 49-56. 10.1016/j.neuron.2012.03.009.PubMed

102.

Familian A, Boshuizen RS, Eikelenboom P, Veerhuis R: Inhibitory effect of minocycline on amyloid beta fibril formation and human microglial activation. Glia. 2006, 53: 233-240. 10.1002/glia.20268.PubMed

103.

Ryu JK, Franciosi S, Sattayaprasert P, Kim SU, McLarnon JG: Minocycline inhibits neuronal death and glial activation induced by beta-amyloid peptide in rat hippocampus. Glia. 2004, 48: 85-90. 10.1002/glia.20051.PubMed

104.

Bilousova TV, Dansie L, Ngo M, Aye J, Charles JR, Ethell DW, Ethell IM: Minocycline promotes dendritic spine maturation and improves behavioural performance in the fragile X mouse model. J Med Genet. 2009, 46: 94-102.PubMed

Titel: Impairment of fragile X mental retardation protein-metabotropic glutamate receptor 5 signaling and its downstream cognates ras-related C3 botulinum toxin substrate 1, amyloid beta A4 precursor protein, striatal-enriched protein tyrosine phosphatase, and homer 1, in autism: a postmortem study in cerebellar vermis and superior frontal cortex
verfasst von: SHossein Fatemi
Timothy D Folsom
Rachel E Kneeland
Mahtab K Yousefi
Stephanie B Liesch
Paul D Thuras
Publikationsdatum: 01.12.2013
Verlag: BioMed Central
Erschienen in: Molecular Autism / Ausgabe 1/2013
Elektronische ISSN: 2040-2392
DOI: https://doi.org/10.1186/2040-2392-4-21

Neu in den Fachgebieten Neurologie und Psychiatrie

Akuter Schwindel: Wann lohnt sich eine MRT?

28.04.2024 Schwindel Nachrichten

Akuter Schwindel stellt oft eine diagnostische Herausforderung dar. Wie nützlich dabei eine MRT ist, hat eine Studie aus Finnland untersucht. Immerhin einer von sechs Patienten wurde mit akutem ischämischem Schlaganfall diagnostiziert.

Niedriger diastolischer Blutdruck erhöht Risiko für schwere kardiovaskuläre Komplikationen

25.04.2024 Hypotonie Nachrichten

Wenn unter einer medikamentösen Hochdrucktherapie der diastolische Blutdruck in den Keller geht, steigt das Risiko für schwere kardiovaskuläre Ereignisse: Darauf deutet eine Sekundäranalyse der SPRINT-Studie hin.

Frühe Alzheimertherapie lohnt sich

25.04.2024 AAN-Jahrestagung 2024 Nachrichten

Ist die Tau-Last noch gering, scheint der Vorteil von Lecanemab besonders groß zu sein. Und beginnen Erkrankte verzögert mit der Behandlung, erreichen sie nicht mehr die kognitive Leistung wie bei einem früheren Start. Darauf deuten neue Analysen der Phase-3-Studie Clarity AD.

Viel Bewegung in der Parkinsonforschung

25.04.2024 Parkinson-Krankheit Nachrichten

Neue arznei- und zellbasierte Ansätze, Frühdiagnose mit Bewegungssensoren, Rückenmarkstimulation gegen Gehblockaden – in der Parkinsonforschung tut sich einiges. Auf dem Deutschen Parkinsonkongress ging es auch viel um technische Innovationen.

Springer Medizin

Abstract

Background

Methods

Results

Conclusions

Electronic supplementary material

Competing interests

Authors’ contributions

Background

Methods

Tissue preparation

Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and western blot analysis

Statistical analysis

Results

Discussion

Conclusions

Acknowledgments

Competing interests

Authors’ contributions

Electronic supplementary material

Authors’ original submitted files for images

Weitere Artikel der Ausgabe 1/2013

Do girls with anorexia nervosa have elevated autistic traits?

Capping four years of growth of Molecular Autism: impact factor coming in 2014

Does epilepsy in multiplex autism pedigrees define a different subgroup in terms of clinical characteristics and genetic risk?

Test-retest reliability of the ‘Reading the Mind in the Eyes’ test: a one-year follow-up study

Rare coding variants of the adenosine A3 receptor are increased in autism: on the trail of the serotonin transporter regulome

Decitabine alters the expression of Mecp2 isoforms via dynamic DNA methylation at the Mecp2 regulatory elements in neural stem cells

Neu in den Fachgebieten Neurologie und Psychiatrie

Akuter Schwindel: Wann lohnt sich eine MRT?

Niedriger diastolischer Blutdruck erhöht Risiko für schwere kardiovaskuläre Komplikationen

Frühe Alzheimertherapie lohnt sich

Viel Bewegung in der Parkinsonforschung