Aberrant White Matter Microstructure in Children with 16p11.2 Deletions

Owen, Julia P.; Chang, Yi Shin; Pojman, Nicholas J.; Bukshpun, Polina; Wakahiro, Mari; Marco, Elysa J.; Berman, Jeffrey; Spiro, John E.; Chung, Wendy K.; Buckner, Randy L.; Roberts, Timothy P.L.; Nagarajan, Srikantan S.; Sherr, Elliott H.; Mukherjee, Pratik

doi:10.1523/jneurosci.4495-13.2014

Cited by 73 publications

(71 citation statements)

References 32 publications

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“…Diffusion tension imaging analyses revealed white matter abnormalities in 16p11.2 deletion carriers, especially in the anterior corpus callosum, and bilateral internal and external capsules (Owen et al 2014). More research is needed to delineate the relationship between neuroanatomical changes and intellectual disabilities in people with 16p11.2 deletion syndrome.…”

Section: Discussionmentioning

confidence: 96%

16p11.2 Deletion mice display cognitive deficits in touchscreen learning and novelty recognition tasks

et al. 2015

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Chromosomal 16p11.2 deletion syndrome frequently presents with intellectual disabilities, speech delays, and autism. Here we investigated the Dolmetsch line of 16p11.2 heterozygous (+/2) mice on a range of cognitive tasks with different neuroanatomical substrates. Robust novel object recognition deficits were replicated in two cohorts of 16p11.2+/2 mice, confirming previous findings. A similarly robust deficit in object location memory was discovered in +/2, indicating impaired spatial novelty recognition. Generalizability of novelty recognition deficits in +/2 mice extended to preference for social novelty. Robust learning deficits and cognitive inflexibility were detected using Bussey-Saksida touchscreen operant chambers. During acquisition of pairwise visual discrimination, +/2 mice required significantly more training trials to reach criterion than wild-type littermates (+/+), and made more errors and correction errors than +/+. In the reversal phase, all +/+ reached criterion, whereas most +/2 failed to reach criterion by the 30-d cutoff. Contextual and cued fear conditioning were normal in +/2. These cognitive phenotypes may be relevant to some aspects of cognitive impairments in humans with 16p11.2 deletion, and support the use of 16p11.2+/2 mice as a model system for discovering treatments for cognitive impairments in 16p11.2 deletion syndrome.Recurrent heterozygous deletions of a 600-kb segment on human chromosome 16 is found in 0.4% of individuals with intellectual disability (Bijlsma et al. 2009;Hanson et al. 2015) and 0.6% of individuals with autism (Marshall et al. 2008;Weiss et al. 2008;Walsh and Bracken 2011). 16p11.2 deletion syndrome presents with a range of mild-to-severe cognitive impairments, with IQ scores averaging 2 SDs lower than controls, and a confirmed diagnosis of autism in 15% of affected individuals (Hanson et al.

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Section: Discussionmentioning

confidence: 96%

16p11.2 Deletion mice display cognitive deficits in touchscreen learning and novelty recognition tasks

et al. 2015

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“…A deeper understanding of the origin and significance of these phenomena is greatly complicated by our very limited understanding of the neurobiological foundations of macro-scale neuroimaging readouts commonly employed in ASD research, such as white matter microstructural parameters (e.g., fractional anisotropy, Owen et al, 2014) or the elusive functional couplings underlying rsfMRI-based functional connectivity. This has left us with a major explanatory gap between mechanistic models of brain function at the cellular and microcircuit level, and the emergence of macroscale functional activity in health and pathological states such as those that are observed in autism.…”

Section: The Connectivity Theory Of Autism: Open Questions and Contromentioning

confidence: 99%

“…Similarly, studies of additional genetic etiologies associated with ASDs, covering heterogeneous pathophysiological pathways, are crucial to achieve a deeper understanding of whether the connectional signatures are mutation specific or can be regarded as a generalizable phenomenon. When coupled to analogous clinical efforts aimed at identification of connectional aberrancies in genetically homogeneous populations [e.g., 16p11.2 deletion (Simons Vip Consortium, 2012; Owen et al, 2014)], the method can also be used to investigate the cellular and physiological basis of clinically relevant neuroimaging readouts and, via a comparison between human and mouse imaging findings, to obtain an assessment of the translational and construct validity of mouse models of ASD. The developmental trajectory of these alterations could in principle also be investigated in mouse models, although critical limitations in the accuracy of physiological control in young mice and pups exist.…”

Section: Limitations and Future Perspectivesmentioning

confidence: 99%

Can Mouse Imaging Studies Bring Order to Autism Connectivity Chaos?

Liska

Gozzi

2016

Front. Neurosci.

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Functional Magnetic Resonance Imaging (fMRI) has consistently highlighted impaired or aberrant functional connectivity across brain regions of autism spectrum disorder (ASD) patients. However, the manifestation and neural substrates of these alterations are highly heterogeneous and often conflicting. Moreover, their neurobiological underpinnings and etiopathological significance remain largely unknown. A deeper understanding of the complex pathophysiological cascade leading to aberrant connectivity in ASD can greatly benefit from the use of model organisms where individual pathophysiological or phenotypic components of ASD can be recreated and investigated via approaches that are either off limits or confounded by clinical heterogeneity. Despite some obvious limitations in reliably modeling the full phenotypic spectrum of a complex developmental disorder like ASD, mouse models have played a central role in advancing our basic mechanistic and molecular understanding of this syndrome. Recent progress in mouse brain connectivity mapping via resting-state fMRI (rsfMRI) offers the opportunity to generate and test mechanistic hypotheses about the elusive origin and significance of connectional aberrations observed in autism. Here we discuss recent progress toward this goal, and illustrate initial examples of how the approach can be employed to establish causal links between ASD-related mutations, developmental processes, and brain connectional architecture. As the spectrum of genetic and pathophysiological components of ASD modeled in the mouse is rapidly expanding, the use of rsfMRI can advance our mechanistic understanding of the origin and significance of the connectional alterations associated with autism, and their heterogeneous expression across patient cohorts.

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“…In contrast, ASD, regardless of whether it is idiopathic or associated with TSC, is characterized by decreased long-range connectivity, a proportional increase in short-range connectivity, and evidence of decreased functional specialization and excessive degeneracy within the network [57]. Neuroimaging studies of individuals with different types of 16p11.2 copy number variations with and without autism are underway [60,61]. …”

Section: Autism Spectrum Disorders Associated With Specific Genetic Dmentioning

confidence: 99%

Brain imaging research in autism spectrum disorders

Lainhart

2015

Current Opinion in Psychiatry

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Purpose of review Advances in brain imaging research in autism spectrum disorders (ASD) are rapidly occurring, and the amount of neuroimaging research has dramatically increased over the past 5 years. In this review, advances during the past 12 months and longitudinal studies are highlighted. Recent findings Cross-sectional neuroimaging research provides evidence that the neural underpinnings of the behavioral signs of ASD involve not only dysfunctional integration of information across distributed brain networks but also basic dysfunction in primary cortices. Longitudinal studies of ASD show abnormally enlarged brain volumes and increased rates of brain growth during early childhood in only a small minority of ASD children. There is evidence of disordered development of white matter microstructure and amygdala growth, and at 2 years of age, network inefficiencies in posterior cerebral regions. From older childhood into adulthood, atypical age-variant and age-invariant changes in the trajectories of total and regional brain volumes and cortical thickness are apparent at the group level. Summary There is evidence of abnormalities in posterior lobes and posterior brain networks during the first 2 years of life in ASD and, even in older children and adults, dysfunction in primary cortical areas.

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Aberrant White Matter Microstructure in Children with 16p11.2 Deletions

Cited by 73 publications

References 32 publications

16p11.2 Deletion mice display cognitive deficits in touchscreen learning and novelty recognition tasks

16p11.2 Deletion mice display cognitive deficits in touchscreen learning and novelty recognition tasks

Can Mouse Imaging Studies Bring Order to Autism Connectivity Chaos?

Brain imaging research in autism spectrum disorders

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