TY - JOUR
T1 - Dendritic spine pathologies in hippocampal pyramidal neurons from Rett syndrome brain and after expression of Rett-associated MECP2 mutations
AU - Chapleau, Christopher A.
AU - Calfa, Gaston D.
AU - Lane, Meredith C.
AU - Albertson, Asher J.
AU - Larimore, Jennifer L.
AU - Kudo, Shinichi
AU - Armstrong, Dawna L.
AU - Percy, Alan K.
AU - Pozzo-Miller, Lucas
N1 - Funding Information:
Supported by NIH grants NS40593 and NS057780, IRSF and the Civitan International Foundation (LP-M). We also thank the assistance of the UAB Intellectual and Developmental Disabilities Research Center (IDDRC; P30-HD38985) and the UAB Neuroscience Cores (P30-NS47466, P30-NS57098). Human tissue was obtained from the NICHD Brain and Tissue Bank for Developmental Disorders at the University of Maryland, Baltimore, MD, and the Harvard Brain Bank. We thank Dr. Carolyn Schanen (Nemours Biomedical Research, Alfred I. duPont Hospital for Children, Wilmington, DE, USA), and Mr. J. Matthew Rutherford for discussions and comments on the manuscript. We also thank Dr. Mark Beasley for statistical analyses (IDDRC Biometry Core A; UAB School of Public Health, Biostatistics).
PY - 2009/8
Y1 - 2009/8
N2 - Rett syndrome (RTT) is an X chromosome-linked neurodevelopmental disorder associated with the characteristic neuropathology of dendritic spines common in diseases presenting with mental retardation (MR). Here, we present the first quantitative analyses of dendritic spine density in postmortem brain tissue from female RTT individuals, which revealed that hippocampal CA1 pyramidal neurons have lower spine density than age-matched non-MR female control individuals. The majority of RTT individuals carry mutations in MECP2, the gene coding for a methylated DNA-binding transcriptional regulator. While altered synaptic transmission and plasticity has been demonstrated in Mecp2-deficient mouse models of RTT, observations regarding dendritic spine density and morphology have produced varied results. We investigated the consequences of MeCP2 dysfunction on dendritic spine structure by overexpressing (∼ twofold) MeCP2-GFP constructs encoding either the wildtype (WT) protein, or missense mutations commonly found in RTT individuals. Pyramidal neurons within hippocampal slice cultures transfected with either WT or mutant MECP2 (either R106W or T158M) showed a significant reduction in total spine density after 48 h of expression. Interestingly, spine density in neurons expressing WT MECP2 for 96 h was comparable to that in control neurons, while neurons expressing mutant MECP2 continued to have lower spine density than controls after 96 h of expression. Knockdown of endogenous Mecp2 with a specific small hairpin interference RNA (shRNA) also reduced dendritic spine density, but only after 96 h of expression. On the other hand, the consequences of manipulating MeCP2 levels for dendritic complexity in CA3 pyramidal neurons were only minor. Together, these results demonstrate reduced dendritic spine density in hippocampal pyramidal neurons from RTT patients, a distinct dendritic phenotype also found in neurons expressing RTT-associated MECP2 mutations or after shRNA-mediated endogenous Mecp2 knockdown, suggesting that this phenotype represent a cell-autonomous consequence of MeCP2 dysfunction.
AB - Rett syndrome (RTT) is an X chromosome-linked neurodevelopmental disorder associated with the characteristic neuropathology of dendritic spines common in diseases presenting with mental retardation (MR). Here, we present the first quantitative analyses of dendritic spine density in postmortem brain tissue from female RTT individuals, which revealed that hippocampal CA1 pyramidal neurons have lower spine density than age-matched non-MR female control individuals. The majority of RTT individuals carry mutations in MECP2, the gene coding for a methylated DNA-binding transcriptional regulator. While altered synaptic transmission and plasticity has been demonstrated in Mecp2-deficient mouse models of RTT, observations regarding dendritic spine density and morphology have produced varied results. We investigated the consequences of MeCP2 dysfunction on dendritic spine structure by overexpressing (∼ twofold) MeCP2-GFP constructs encoding either the wildtype (WT) protein, or missense mutations commonly found in RTT individuals. Pyramidal neurons within hippocampal slice cultures transfected with either WT or mutant MECP2 (either R106W or T158M) showed a significant reduction in total spine density after 48 h of expression. Interestingly, spine density in neurons expressing WT MECP2 for 96 h was comparable to that in control neurons, while neurons expressing mutant MECP2 continued to have lower spine density than controls after 96 h of expression. Knockdown of endogenous Mecp2 with a specific small hairpin interference RNA (shRNA) also reduced dendritic spine density, but only after 96 h of expression. On the other hand, the consequences of manipulating MeCP2 levels for dendritic complexity in CA3 pyramidal neurons were only minor. Together, these results demonstrate reduced dendritic spine density in hippocampal pyramidal neurons from RTT patients, a distinct dendritic phenotype also found in neurons expressing RTT-associated MECP2 mutations or after shRNA-mediated endogenous Mecp2 knockdown, suggesting that this phenotype represent a cell-autonomous consequence of MeCP2 dysfunction.
KW - Dendrite
KW - Dendritic spine
KW - DiOlistics
KW - Hippocampus
KW - Human postmortem brain
KW - MeCP2
KW - Pyramidal neuron
KW - Rett syndrome
UR - http://www.scopus.com/inward/record.url?scp=67649487935&partnerID=8YFLogxK
U2 - 10.1016/j.nbd.2009.05.001
DO - 10.1016/j.nbd.2009.05.001
M3 - Article
C2 - 19442733
AN - SCOPUS:67649487935
SN - 0969-9961
VL - 35
SP - 219
EP - 233
JO - Neurobiology of Disease
JF - Neurobiology of Disease
IS - 2
ER -