Large-scale topology and the default mode network in the mouse connectome

Significance Noninvasive brain imaging holds great promise for expanding our capabilities of treating human neurologic and psychiatric disorders. However, key limitations exist in human-only studies, and the ability to use animal models would greatly advance our understanding of human brain function. Mice offer sophisticated genetic and molecular methodology, but correlating these data to functional brain imaging in the mouse brain has remained a major hurdle. This study is the first, to our knowledge, to use whole-brain functional imaging to show large-scale functional architecture with structural correlates in the mouse. Perhaps more important is the finding of conservation in brain topology and default network among rodents and primates, thereby clearing the way for a bridge measurement between human and mouse models. Noninvasive functional imaging holds great promise for serving as a translational bridge between human and animal models of various neurological and psychiatric disorders. However, despite a depth of knowledge of the cellular and molecular underpinnings of atypical processes in mouse models, little is known about the large-scale functional architecture measured by functional brain imaging, limiting translation to human conditions. Here, we provide a robust processing pipeline to generate high-resolution, whole-brain resting-state functional connectivity MRI (rs-fcMRI) images in the mouse. Using a mesoscale structural connectome (i.e., an anterograde tracer mapping of axonal projections across the mouse CNS), we show that rs-fcMRI in the mouse has strong structural underpinnings, validating our procedures. We next directly show that large-scale network properties previously identified in primates are present in rodents, although they differ in several ways. Last, we examine the existence of the so-called default mode network (DMN)—a distributed functional brain system identified in primates as being highly important for social cognition and overall brain function and atypically functionally connected across a multitude of disorders. We show the presence of a potential DMN in the mouse brain both structurally and functionally. Together, these studies confirm the presence of basic network properties and functional networks of high translational importance in structural and functional systems in the mouse brain. This work clears the way for an important bridge measurement between human and rodent models, enabling us to make stronger conclusions about how regionally specific cellular and molecular manipulations in mice relate back to humans.

[1]  J. Gore,et al.  The Relationship of Anatomical and Functional Connectivity to Resting-State Connectivity in Primate Somatosensory Cortex , 2013, Neuron.

[2]  A. Toga,et al.  The Rhesus Monkey Brain in Stereotaxic Coordinates , 1999 .

[3]  O. Sporns,et al.  Network hubs in the human brain , 2013, Trends in Cognitive Sciences.

[4]  B. Hermann,et al.  Children with new-onset epilepsy exhibit diffusion abnormalities in cerebral white matter in the absence of volumetric differences , 2010, Epilepsy Research.

[5]  Marleen Verhoye,et al.  Resting State fMRI Reveals Diminished Functional Connectivity in a Mouse Model of Amyloidosis , 2013, PloS one.

[6]  M. Viergever,et al.  Recovery of Sensorimotor Function after Experimental Stroke Correlates with Restoration of Resting-State Interhemispheric Functional Connectivity , 2010, The Journal of Neuroscience.

[7]  D. V. Essen,et al.  Surface-Based and Probabilistic Atlases of Primate Cerebral Cortex , 2007, Neuron.

[8]  Abraham Z. Snyder,et al.  Maturing Thalamocortical Functional Connectivity Across Development , 2010, Front. Syst. Neurosci..

[9]  D. Amaral,et al.  Macaque monkey retrosplenial cortex: II. Cortical afferents , 2003, The Journal of comparative neurology.

[10]  M Petrides,et al.  Architecture and connections of retrosplenial area 30 in the rhesus monkey (macaca mulatta). , 1999, The European journal of neuroscience.

[11]  R. Buckner,et al.  Evidence for the Default Network's Role in Spontaneous Cognition , 2010 .

[12]  S. Petersen,et al.  The maturing architecture of the brain's default network , 2008, Proceedings of the National Academy of Sciences.

[13]  E. Fombonne,et al.  Structural and functional connectivity of the human brain in autism spectrum disorders and attention‐deficit/hyperactivity disorder: A rich club‐organization study , 2014, Human brain mapping.

[14]  Justin L. Vincent,et al.  Intrinsic functional architecture in the anaesthetized monkey brain , 2007, Nature.

[15]  Brian D. Mills,et al.  Bridging the Gap between the Human and Macaque Connectome: A Quantitative Comparison of Global Interspecies Structure-Function Relationships and Network Topology , 2014, The Journal of Neuroscience.

[16]  D. Fair,et al.  Dietary Omega-3 Fatty Acids Modulate Large-Scale Systems Organization in the Rhesus Macaque Brain , 2014, The Journal of Neuroscience.

[17]  John W. Harwell,et al.  Cortical parcellations of the macaque monkey analyzed on surface-based atlases. , 2012, Cerebral cortex.

[18]  G L Shulman,et al.  INAUGURAL ARTICLE by a Recently Elected Academy Member:A default mode of brain function , 2001 .

[19]  Klaas E. Stephan,et al.  The history of CoCoMac , 2013, NeuroImage.

[20]  Brent A. Vogt,et al.  Cytoarchitecture of mouse and rat cingulate cortex with human homologies , 2012, Brain Structure and Function.

[21]  Timothy Edward John Behrens,et al.  Anatomically related grey and white matter abnormalities in adolescent-onset schizophrenia. , 2007, Brain : a journal of neurology.

[22]  Tom Schoenemann From Monkey Brain to Human Brain: A Fyssen Foundation Symposium , 2006 .

[23]  B. Miller,et al.  Neurodegenerative Diseases Target Large-Scale Human Brain Networks , 2009, Neuron.

[24]  O Sporns,et al.  Predicting human resting-state functional connectivity from structural connectivity , 2009, Proceedings of the National Academy of Sciences.

[25]  B. Biswal,et al.  Functional connectivity in the motor cortex of resting human brain using echo‐planar mri , 1995, Magnetic resonance in medicine.

[26]  Christopher P. Pawela,et al.  Modeling of region-specific fMRI BOLD neurovascular response functions in rat brain reveals residual differences that correlate with the differences in regional evoked potentials , 2008, NeuroImage.

[27]  James Loudin,et al.  A Multivariate Method for Comparing N-dimensional Distributions , 2003 .

[28]  Jack L. Lancaster,et al.  A modality‐independent approach to spatial normalization of tomographic images of the human brain , 1995 .

[29]  Jaeseung Jeong,et al.  Frequency distribution of causal connectivity in rat sensorimotor network: resting-state fMRI analyses. , 2013, Journal of neurophysiology.

[30]  S. Debener,et al.  Default-mode brain dysfunction in mental disorders: A systematic review , 2009, Neuroscience & Biobehavioral Reviews.

[31]  D. Little,et al.  A preliminary study targeting neuronal pathways activated following environmental enrichment by resting state functional magnetic resonance imaging. , 2012, Journal of Alzheimer's disease : JAD.

[32]  Bharat B. Biswal,et al.  A protocol for use of medetomidine anesthesia in rats for extended studies using task-induced BOLD contrast and resting-state functional connectivity , 2009, NeuroImage.

[33]  Olaf Sporns,et al.  Network structure of cerebral cortex shapes functional connectivity on multiple time scales , 2007, Proceedings of the National Academy of Sciences.

[34]  S. Petersen,et al.  Development of distinct control networks through segregation and integration , 2007, Proceedings of the National Academy of Sciences.

[35]  O. Sporns,et al.  Rich-Club Organization of the Human Connectome , 2011, The Journal of Neuroscience.

[36]  Alessandro Vespignani,et al.  Detecting rich-club ordering in complex networks , 2006, physics/0602134.

[37]  Deepti R. Bathula,et al.  Atypical Default Network Connectivity in Youth with Attention-Deficit/Hyperactivity Disorder , 2010, Biological Psychiatry.

[38]  Kai-Hsiang Chuang,et al.  Detection of functional connectivity in the resting mouse brain , 2014, NeuroImage.

[39]  M. P. van den Heuvel,et al.  Microstructural Organization of the Cingulum Tract and the Level of Default Mode Functional Connectivity , 2008, The Journal of Neuroscience.

[40]  M. Schölvinck,et al.  Neural basis of global resting-state fMRI activity , 2010, Proceedings of the National Academy of Sciences.

[41]  M. Raichle,et al.  Rat brains also have a default mode network , 2012, Proceedings of the National Academy of Sciences.

[42]  B. Vogt,et al.  Cytology of human caudomedial cingulate, retrosplenial, and caudal parahippocampal cortices , 2001, The Journal of comparative neurology.

[43]  Joaquín Goñi,et al.  Abnormal rich club organization and functional brain dynamics in schizophrenia. , 2013, JAMA psychiatry.

[44]  M. Greicius,et al.  Resting-state functional connectivity reflects structural connectivity in the default mode network. , 2009, Cerebral cortex.

[45]  Allan R. Jones,et al.  A mesoscale connectome of the mouse brain , 2014, Nature.

[46]  David C. Van Essen,et al.  Application of Information Technology: An Integrated Software Suite for Surface-based Analyses of Cerebral Cortex , 2001, J. Am. Medical Informatics Assoc..

[47]  M. Verhoye,et al.  Functional Connectivity fMRI of the Rodent Brain: Comparison of Functional Connectivity Networks in Rat and Mouse , 2011, PloS one.

[48]  Nikos K. Logothetis,et al.  Intracortical recordings and fMRI: An attempt to study operational modules and networks simultaneously , 2012, NeuroImage.

[49]  Samuel D. Carpenter,et al.  Structural and Functional Rich Club Organization of the Brain in Children and Adults , 2014, PloS one.

[50]  R. Kahn,et al.  Functionally linked resting‐state networks reflect the underlying structural connectivity architecture of the human brain , 2009, Human brain mapping.

[51]  O. Sporns,et al.  White matter maturation reshapes structural connectivity in the late developing human brain , 2010, Proceedings of the National Academy of Sciences.

[52]  Emma K. Towlson,et al.  The Rich Club of the C. elegans Neuronal Connectome , 2013, The Journal of Neuroscience.

[53]  R. Buckner,et al.  Functional-Anatomic Fractionation of the Brain's Default Network , 2010, Neuron.

[54]  M. Corbetta,et al.  Common Blood Flow Changes across Visual Tasks: II. Decreases in Cerebral Cortex , 1997, Journal of Cognitive Neuroscience.

[55]  H. Lu,et al.  Resting-State Functional Connectivity in Rat Brain , 2005 .

[56]  Randy L. Buckner,et al.  The evolution of distributed association networks in the human brain , 2013, Trends in Cognitive Sciences.

[57]  Brent A. Vogt,et al.  CHAPTER 22 – Cingulate Cortex and Disease Models , 2004 .

[58]  G. Paxinos,et al.  Comprar The Mouse Brain in Stereotaxic Coordinates, The coronal plates and diagrams Compact, 3rd Edition | Keith Franklin | 9780123742445 | Academic Press , 2008 .

[59]  Adam G. Thomas,et al.  The Organization of Dorsal Frontal Cortex in Humans and Macaques , 2013, The Journal of Neuroscience.

[60]  Younglim Lee,et al.  Default-Mode-Like Network Activation in Awake Rodents , 2011, PloS one.

[61]  David G. Norris,et al.  An Investigation of Functional and Anatomical Connectivity Using Magnetic Resonance Imaging , 2002, NeuroImage.

[62]  O. Sporns,et al.  Mapping the Structural Core of Human Cerebral Cortex , 2008, PLoS biology.

[63]  Shi Zhou,et al.  The rich-club phenomenon in the Internet topology , 2003, IEEE Communications Letters.

[64]  Abraham Z. Snyder,et al.  Imaging of Functional Connectivity in the Mouse Brain , 2011, PloS one.

[65]  Jürgen Hennig,et al.  Fine-grained mapping of mouse brain functional connectivity with resting-state fMRI , 2014, NeuroImage.

[66]  M. Greicius,et al.  Default-mode network activity distinguishes Alzheimer's disease from healthy aging: Evidence from functional MRI , 2004, Proc. Natl. Acad. Sci. USA.