Professor Michael Piper
Professor

Michael Piper

Email: 
Phone: 
+61 7 334 69873

Background

I graduated from The University of Tasmania, and received my PhD in Developmental Biology from The University of Queensland in 2003. My PhD, performed at the Institute for Molecular Bioscience with Prof. Melissa Little, centred on understanding the cellular and molecular mechanisms underlying embryonic kidney development. My first postdoc was performed with Prof. Christine Holt at The University of Cambridge, UK, where I studied the mechanisms by which axonal growth cones navigate to their targets in the brain, using the frog Xenopus laevis as a model system. In my second postdoctoral position, with Prof. Linda Richards at the Queensland Brain Institute at The University of Queensland, my work focussed on understanding the molecular mechanisms of neural progenitor cell specification in the developing cerebral cortex. In late 2010, I took up a joint position with the Queensland Brain Institute and The School of Biomedical Sciences (SBMS) to continue my research into the mechanisms underlying neural stem cell differentiation. I have held numerous fellowships during my career, including an NHMRC Howard Florey Fellowship, an NHMRC CDF and an ARC Future Fellowship. I currently hold a continuing Teaching and Research position within SBMS, and am currently the Director for Higher Degree Research Training at SBMS.

Availability

Professor Michael Piper is:
Available for supervision

Fields of research

Biological Sciences Biomedical and Clinical Sciences Cell and nuclear division Cellular nervous system Epigenetics (incl. genome methylation and epigenomics) Genetics Neurosciences

Qualifications

  • Bachelor (Honours) of Science (Advanced), University of Tasmania
  • Doctor of Philosophy, The University of Queensland

Research interests

  • Understanding the drivers of neural stem cell differentiation

    What are the mechanisms that control neural stem cell (NSC) differentiation during embryogenesis, and that enable the generation of the diverse suite of neurons and glia that comprise the brain? This is a key question in developmental neuroscience. My contribution to this field to date has been to reveal central transcriptional regulators that mediate NSC biology within the brain. Using rodent model systems, I demonstrated that transcription factors of the Nuclear Factor One (NFI) family mediate NSC proliferation and differentiation in the embryonic, postnatal and adult nervous system. This work has received international recognition, as evidenced by numerous invited international presentations and high-impact reviews (e.g. Trends in Cell Biology), and forms the framework around which the hypotheses of this program will be addressed. I am interested in defining how NSC proliferation and differentiation is regulated at a transcriptional and epigenomic level within the developing nervous system. Using the developing mouse brain as a model system, we are using a suite of molecular and cellular techniques to understand how diverse regions of the nervous system are generated, including the cerebral cortex, the cerebellum, the spinal cord and the hypothalamus. For example, within the cerebral cortex, we are investigating how the NFI family of transcription factors mediate NSC differentiation, and how mutations to the NFI family culminate in macrocephaly, and disorders such as Malan syndrome. Moreover, we are using mice lacking the gene Nsd1 (a histone modifying protein) to investigate the development of a human syndrome known as Sotos syndrome, which is also characterised by macrocephaly. In collaboration with Mikael Boden (SCMB), we are also investigating how changes to chromatin landscapes mediate NSC differentiation, and developing bioinformatic tools to enhance the analysis of RNA-seq and ChIP-seq datasets. Collectively, this work will provide fundamental insights into neural development, as well as insights into human neurodevelopmental disorders that arise as a result of abnormal neural stem cell biology in utero.

Research impacts

The human brain is an incredibly complex organ, consisting of over 100 billion neurons, and even more glial cells. Further adding to this complexity is the fact that there are a wide variety of distinct neuronal subpopulations within the brain, each with different morphological characteristics, neurochemical properties and patterns of connectivity. Amazingly, nearly all of the cells within the brain are derived from a relatively small population of neural stem cells (NSCs) that proliferate, then differentiate, during embryogenesis. Understanding how NSC biology is coordinated, both spatially and temporally, to generate the mature brain remains one of the great challenges in biology. My vision is to reveal the mechanisms that control NSC differentiation within the developing brain, and to apply this knowledge to understand diseases caused by abnormal NSC differentiation, such as autism and hydrocephalus.

I have made a number of significant contributions to understanding how NSC differentiation is coordinated during neural development since starting my own group in late 2010. This work, which was supported by competitive fellowship (NHMRC Career Development Fellowship 2009-2012; ARC Future Fellowship 2013-2017) and grant funding (three NHMRC project grants as CIA; two ARC Discovery Projects as sole CI), has helped to elucidate the fundamental mechanisms underpinning neurogenesis within the neocortex, hippocampus and cerebellum. I have also defined critical molecular controllers of NSC quiescence, a cellular state that ensures the longevity of adult NSCs, as well as describing the behavioural consequences of aberrant adult neurogenesis. Finally, I have provided new insights into how abnormal stem cell biology can contribute to a range of neurodevelopmental disorders, as well as cancers of the brain and skin. The significance of my findings has been recognised by multiple awards for research excellence, from both national (e.g. 2018 Emerging Leader Award, Australian and New Zealand Society for Cell and Developmental Biology; 2010 AW Campbell Award, Australasian Neuroscience Society) and international agencies (2015 Innovator Award, Hydrocephalus Association; 2010 CJ Herrick Award, American Association for Anatomists). I now am in an ideal position to address aspects of two key questions in the field, namely, what are the transcriptomic and epigenomic factors that control the differentiation of NSCs during brain development, and how do deficits in this process contribute to disease?

I have published 111 manuscripts, over 70% of which have been as first or last author. These include manuscripts in leading jourals such as Nature, Nature Neuroscience, Neuron, The Journal of Neuroscience and Cerebral Cortex. For my full publication record, please visit my Orcid site

Search Professor Michael Piper’s works on UQ eSpace

130 works between 2000 and 2025
All (130) Journal Article (116) Book Chapter (5) Conference Publication (8) Other Outputs (1)

41 - 60 of 130 works

2020

Journal Article

Abnormal behavior and cortical connectivity deficits in mice lacking Usp9x

Kasherman, Maria A., Currey, Laura, Kurniawan, Nyoman D., Zalucki, Oressia, Vega, Michelle Sanchez, Jolly, Lachlan A., Burne, Thomas H. J., Wood, Stephen A. and Piper, Michael (2020). Abnormal behavior and cortical connectivity deficits in mice lacking Usp9x. Cerebral Cortex, 31 (3), 1763-1775. doi: 10.1093/cercor/bhaa324

Abnormal behavior and cortical connectivity deficits in mice lacking Usp9x

2020

Journal Article

Alterations in gene expression in the spinal cord of mice lacking Nfix

Matuzelski, Elise, Essebier, Alexandra, Harris, Lachlan, Gronostajski, Richard M., Harvey, Tracey J. and Piper, Michael (2020). Alterations in gene expression in the spinal cord of mice lacking Nfix. BMC Research Notes, 13 (1) 437, 437. doi: 10.1186/s13104-020-05278-w

Alterations in gene expression in the spinal cord of mice lacking Nfix

2020

Journal Article

The spindle-associated microcephaly protein, WDR62, is required for neurogenesis and development of the hippocampus

Shohayeb, Belal, Ho, Uda Y., Hassan, Halah, Piper, Michael and Ng, Dominic C. H. (2020). The spindle-associated microcephaly protein, WDR62, is required for neurogenesis and development of the hippocampus. Frontiers in Cell and Developmental Biology, 8 549353, 549353. doi: 10.3389/fcell.2020.549353

The spindle-associated microcephaly protein, WDR62, is required for neurogenesis and development of the hippocampus

2020

Journal Article

Adult neurogenesis in the olfactory system: improving performance for difficult discrimination tasks?

Kouremenou, Ioanna, Piper, Michael and Zalucki, Oressia (2020). Adult neurogenesis in the olfactory system: improving performance for difficult discrimination tasks?. BioEssays, 42 (10) 2000065, 2000065. doi: 10.1002/bies.202000065

Adult neurogenesis in the olfactory system: improving performance for difficult discrimination tasks?

2020

Journal Article

The role of lipids in ependymal development and the modulation of adult neural stem cell function during aging and disease

Harkins, Danyon, Cooper, Helen M. and Piper, Michael (2020). The role of lipids in ependymal development and the modulation of adult neural stem cell function during aging and disease. Seminars in Cell and Developmental Biology, 112, 61-68. doi: 10.1016/j.semcdb.2020.07.018

The role of lipids in ependymal development and the modulation of adult neural stem cell function during aging and disease

2020

Journal Article

Cell-extrinsic requirement for sulfate in regulating hippocampal neurogenesis

Zhang, Zhe, Jhaveri, Dhanisha, Sharmin, Sazia, Harvey, Tracey J., Dawson, Paul A., Piper, Michael and Simmons, David G. (2020). Cell-extrinsic requirement for sulfate in regulating hippocampal neurogenesis. Biology Open, 9 (7) bio053132, 1-7. doi: 10.1242/bio.053132

Cell-extrinsic requirement for sulfate in regulating hippocampal neurogenesis

2020

Journal Article

Investigating cortical features of Sotos syndrome using mice heterozygous for Nsd1

Oishi, Sabrina, Zalucki, Oressia, Sanchez Vega, Michelle, Harkins, Danyon, Harvey, Tracey J., Kasherman, Maria, Davila, Raul A., Hale, Lauren, White, Melissa, Piltz, Sandra, Thomas, Paul, Burne, Thomas H.J., Harris, Lachlan and Piper, Michael (2020). Investigating cortical features of Sotos syndrome using mice heterozygous for Nsd1. Genes, Brain and Behavior, 19 (4) e12637, e12637. doi: 10.1111/gbb.12637

Investigating cortical features of Sotos syndrome using mice heterozygous for Nsd1

2020

Journal Article

The ubiquitin system: a regulatory hub for intellectual disability and autism spectrum disorder

Kasherman, Maria A., Premarathne, Susitha, Burne, Thomas H. J., Wood, Stephen A. and Piper, Michael (2020). The ubiquitin system: a regulatory hub for intellectual disability and autism spectrum disorder. Molecular Neurobiology, 57 (5), 2179-2193. doi: 10.1007/s12035-020-01881-x

The ubiquitin system: a regulatory hub for intellectual disability and autism spectrum disorder

2020

Journal Article

Partial loss of USP9X function leads to a male neurodevelopmental and behavioural disorder converging on TGFβ signalling

Johnson, Brett V., Kumar, Raman, Oishi, Sabrina, Alexander, Suzy, Kasherman, Maria, Vega, Michelle Sanchez, Ivancevic, Atma, Gardner, Alison, Domingo, Deepti, Corbett, Mark, Parnell, Euan, Yoon, Sehyoun, Oh, Tracey, Lines, Matthew, Lefroy, Henrietta, Kini, Usha, Van Allen, Margot, Grønborg, Sabine, Mercier, Sandra, Küry, Sébastien, Bézieau, Stéphane, Pasquier, Laurent, Raynaud, Martine, Afenjar, Alexandra, Billette de Villemeur, Thierry, Keren, Boris, Désir, Julie, Van Maldergem, Lionel, Marangoni, Martina ... Undiagnosed Diseases Network (2020). Partial loss of USP9X function leads to a male neurodevelopmental and behavioural disorder converging on TGFβ signalling. Biological Psychiatry, 87 (2), 100-112. doi: 10.1016/j.biopsych.2019.05.028

Partial loss of USP9X function leads to a male neurodevelopmental and behavioural disorder converging on TGFβ signalling

2020

Journal Article

The association of microcephaly protein WDR62 with CPAP/IFT88 is required for cilia formation and neocortical development

Shohayeb, Belal, Ho, Uda, Yeap, Yvonne Y., Parton, Robert G., Millard, Sean S., Xu, Zhiheng, Piper, Michael and Ng, Dominic C. H. (2020). The association of microcephaly protein WDR62 with CPAP/IFT88 is required for cilia formation and neocortical development. Human Molecular Genetics, 29 (2), 248-263. doi: 10.1093/hmg/ddz281

The association of microcephaly protein WDR62 with CPAP/IFT88 is required for cilia formation and neocortical development

2020

Journal Article

Expression of NFIA and NFIB within the murine spinal cord

Matuzelski, Elise, Harvey, Tracey J., Harkins, Danyon, Nguyen, Thuan, Ruitenberg, Marc J. and Piper, Michael (2020). Expression of NFIA and NFIB within the murine spinal cord. Gene Expression Patterns, 35 119098, 119098. doi: 10.1016/j.gep.2020.119098

Expression of NFIA and NFIB within the murine spinal cord

2019

Journal Article

Common Regulatory Targets of NFIA, NFIX and NFIB during Postnatal Cerebellar Development

Fraser, James, Essebier, Alexandra, Brown, Alexander S., Davila, Raul Ayala, Harkins, Danyon, Zalucki, Oressia, Shapiro, Lauren P., Penzes, Peter, Wainwright, Brandon J., Scott, Matthew P., Gronostajski, Richard M., Bodén, Mikael, Piper, Michael and Harvey, Tracey J. (2019). Common Regulatory Targets of NFIA, NFIX and NFIB during Postnatal Cerebellar Development. Cerebellum, 19 (1), 89-101. doi: 10.1007/s12311-019-01089-3

Common Regulatory Targets of NFIA, NFIX and NFIB during Postnatal Cerebellar Development

2019

Journal Article

A simple, web-based repository for the management, access and analysis of micrographic images

Davila, Raul Ayala, Harkins, Danyon, Currey, Laura, Fraser, James, Bowles, Josephine and Piper, Michael (2019). A simple, web-based repository for the management, access and analysis of micrographic images. Journal of Molecular Histology, 50 (6), 573-580. doi: 10.1007/s10735-019-09850-y

A simple, web-based repository for the management, access and analysis of micrographic images

2019

Journal Article

Usp9X Controls Ankyrin-Repeat Domain Protein Homeostasis during Dendritic Spine Development

Yoon, Sehyoun, Parnell, Euan, Kasherman, Maria, Forrest, Marc P., Myczek, Kristoffer, Premarathne, Susitha, Sanchez Vega, Michelle C., Piper, Michael, Burne, Thomas H. J., Jolly, Lachlan A., Wood, Stephen A. and Penzes, Peter (2019). Usp9X Controls Ankyrin-Repeat Domain Protein Homeostasis during Dendritic Spine Development. Neuron, 105 (3), 506-521.e7. doi: 10.1016/j.neuron.2019.11.003

Usp9X Controls Ankyrin-Repeat Domain Protein Homeostasis during Dendritic Spine Development

2019

Journal Article

Variants in nuclear factor I genes influence growth and development

Zenker, Martin, Bunt, Jens, Schanze, Ina, Schanze, Denny, Piper, Michael, Priolo, Manuela, Gerkes, Erica H., Gronostajski, Richard M., Richards, Linda J., Vogt, Julie, Wessels, Marja W. and Hennekam, Raoul C. (2019). Variants in nuclear factor I genes influence growth and development. American Journal of Medical Genetics Part C: Seminars in Medical Genetics, 181 (4) ajmg.c.31747, 611-626. doi: 10.1002/ajmg.c.31747

Variants in nuclear factor I genes influence growth and development

2019

Journal Article

The p75 neurotrophin receptor is required for the survival of neuronal progenitors and normal formation of the basal forebrain, striatum, thalamus and neocortex

Meier, Sonja, Alfonsi, Fabienne, Kurniawan, Nyoman D., Milne, Michael R., Kasherman, Maria A., Delogu, Alessio, Piper, Michael and Coulson, Elizabeth J. (2019). The p75 neurotrophin receptor is required for the survival of neuronal progenitors and normal formation of the basal forebrain, striatum, thalamus and neocortex. Development, 146 (18) dev181933, dev.181933. doi: 10.1242/dev.181933

The p75 neurotrophin receptor is required for the survival of neuronal progenitors and normal formation of the basal forebrain, striatum, thalamus and neocortex

2019

Conference Publication

Common regulatory targets of NFIA and NFIX mediate postnatal cerebellar development

Harvey, Tracey, Fraser, James, Essebier, Alexandra, Brown, Alexander, Davila, Raul, Boden, Mikael, Gronostajski, Richard and Piper, Michael (2019). Common regulatory targets of NFIA and NFIX mediate postnatal cerebellar development. 10th IBRO World Congress of Neuroscience, Daegu, South Korea, 21-25 September 2019. Amsterdam, Netherlands: Elsevier. doi: 10.1016/j.ibror.2019.07.1042

Common regulatory targets of NFIA and NFIX mediate postnatal cerebellar development

2019

Journal Article

NFIX-mediated inhibition of neuroblast branching regulates migration within the adult mouse ventricular–subventricular zone

Zalucki, Oressia, Harris, Lachlan, Harvey, Tracey J., Harkins, Danyon, Widagdo, Jocelyn, Oishi, Sabrina, Matuzelski, Elise, Yong, Xuan Ling Hilary, Schmidt, Hannes, Anggono, Victor, Burne, Thomas H. J., Gronostajski, Richard M. and Piper, Michael (2019). NFIX-mediated inhibition of neuroblast branching regulates migration within the adult mouse ventricular–subventricular zone. Cerebral Cortex, 29 (8), 3590-3604. doi: 10.1093/cercor/bhy233

NFIX-mediated inhibition of neuroblast branching regulates migration within the adult mouse ventricular–subventricular zone

2019

Journal Article

Postnatal N-acetylcysteine administration rescues impaired social behaviors and neurogenesis in Slc13a4 haploinsufficient mice

Zhang, Zhe, Dawson, Paul Anthony, Piper, Michael and Simmons, David Gordon (2019). Postnatal N-acetylcysteine administration rescues impaired social behaviors and neurogenesis in Slc13a4 haploinsufficient mice. EBioMedicine, 43, 435-446. doi: 10.1016/j.ebiom.2019.03.081

Postnatal N-acetylcysteine administration rescues impaired social behaviors and neurogenesis in Slc13a4 haploinsufficient mice

2019

Journal Article

Nuclear Factor One X in development and disease

Piper, Michael, Gronostajski, Richard and Messina, Graziella (2019). Nuclear Factor One X in development and disease. Trends in Cell Biology, 29 (1), 20-30. doi: 10.1016/j.tcb.2018.09.003

Nuclear Factor One X in development and disease

Current funding

  • 2023 - 2026
    What drives the Anterior Expansion of the Central Nervous System?
    ARC Discovery Projects
    Open grant
  • 2023 - 2025
    What is the common factor driving brain overgrowth in ASD? Investigating the relationship between epigenetic marks neural stem cell proliferation.
    Simons Foundation Autism Research Initiative - Pilot Award
    Open grant

Past funding

  • 2023 - 2024
    Generation and characterisation of humanised mouse model of Malan Syndrome
    The University of Queensland in America, Inc
    Open grant
  • 2023 - 2024
    The Brain-Ovary connection: identification of a novel regulator of female reproductive function
    Repro Grants
    Open grant
  • 2022 - 2025
    Understanding the generation of hypothalamic sleep neurons
    ARC Discovery Projects
    Open grant
  • 2021 - 2023
    Can inhalational general anaesthetic exposure during pregnancy affect non-genetic heritable elements in fetal germs cells in such a way as to engender pathology in offspring,
    Silicon Valley Community Foundation
    Open grant
  • 2019
    Advanced Brightfield and Fluorescent High Speed and Throughput Slide Scanner for biological, medical, materials science, and agricultural applications
    UQ Major Equipment and Infrastructure
    Open grant
  • 2018
    Trailblazer Grant Piper ISDN Meeting 2018
    Brisbane Marketing
    Open grant
  • 2018 - 2021
    Transcriptional regulation of brain size during development
    ARC Discovery Projects
    Open grant
  • 2018 - 2020
    Aberrant ependymal development and the formation of hydrocephalus
    NHMRC Project Grant
    Open grant
  • 2017 - 2019
    USP9X: A master gene for neural development and autism
    Simons Foundation Autism Research Initiative
    Open grant
  • 2016 - 2019
    Molecular control of adult neural stem cell quiescence
    ARC Discovery Projects
    Open grant
  • 2016 - 2017
    Regulation of stem cell differentiation during cerebellar development and medulloblastoma
    Cancer Council Queensland
    Open grant
  • 2015 - 2016
    Analysis of the role of NFIX in the development of hydrocephalus
    Hydrocephalus Association Innovator Award Research Grant
    Open grant
  • 2015
    Computerised stereotaxic stages and rapid tissue processor for enhanced fixation and immunolabelling
    NHMRC Equipment Grant
    Open grant
  • 2015
    Spectral Applied Research spinning disc confocal microscope for high speed 3D imaging of tissue and live organisms
    UQ Major Equipment and Infrastructure
    Open grant
  • 2014
    Mitochondrial analysis suite
    UQ Major Equipment and Infrastructure
    Open grant
  • 2014 - 2016
    Regulation of neural progenitor cell self-renewal by the RNA-binding protein ZFP36L1 during development and disease
    NHMRC Project Grant
    Open grant
  • 2014
    Touchscreen-automated cognitive testing for mice
    NHMRC Equipment Grant
    Open grant
  • 2013 - 2017
    Transcriptional control of neural stem cell differentiation during development and disease
    ARC Future Fellowships
    Open grant
  • 2013
    Establishment of an Integrated Facility for Single Cell Analysis
    UQ Major Equipment and Infrastructure
    Open grant
  • 2012 - 2014
    Nfib regulates glial differentiation during development and disease via repression of the key epigenetic protein, Ezh2
    NHMRC Project Grant
    Open grant
  • 2011 - 2013
    Investigation of the role of Nfix in adult neurogenesis
    NHMRC Project Grant
    Open grant
  • 2011 - 2013
    ResTeach 2011 0.1 FTE School of Biomedical Sciences
    UQ ResTeach
    Open grant
  • 2011 - 2012
    Suppression of high-grade glioma by Nfib overexpression
    Cancer Council Queensland
    Open grant
  • 2010 - 2012
    Regulation of the Polycomb Genes Eed and Ezh2 by Nfib during Neural Progenitor Cell Differentiation
    UQ Foundation Research Excellence Awards - DVC(R) Funding
    Open grant
  • 2010
    The role of Nfix in stem cell differentiation within the subventricular zone of the adult brain
    UQ Early Career Researcher
    Open grant
  • 2009 - 2013
    NHMRC Career Development Award (Biomedical Level 1): Nfi genes regulate the switch between neurogenesis and gliogenesis during cortical development
    NHMRC Career Development Award
    Open grant
  • 2007 - 2008
    Analysis of gene expression changes within the cortex of Nfi- and Emx1-deficient mice
    UQ New Staff Research Start-Up Fund
    Open grant
  • 2007 - 2008
    The role of Nfi genes in development of the corpus callosum
    Ramaciotti Foundation
    Open grant

Availability

Professor Michael Piper is:
Available for supervision

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Available projects

  • Understanding the drivers of neural stem cell differentiation

    What are the mechanisms that control neural stem cell (NSC) differentiation during embryogenesis, and that enable the generation of the diverse suite of neurons and glia that comprise the brain? This is a key question in developmental neuroscience. My contribution to this field to date has been to reveal central transcriptional regulators that mediate NSC biology within the brain. Using rodent model systems, I demonstrated that transcription factors of the Nuclear Factor One (NFI) family mediate NSC proliferation and differentiation in the embryonic, postnatal and adult nervous system. This work has received international recognition, as evidenced by numerous invited international presentations and high-impact reviews (e.g. Trends in Cell Biology), and forms the framework around which the hypotheses of this program will be addressed.

    I am interested in defining how NSC proliferation and differentiation is regulated at a transcriptional and epigenomic level within the developing nervous system. Using the developing mouse brain as a model system, we are using a suite of molecular and cellular techniques to understand how diverse regions of the nervous system are generated, including the cerebral cortex, the cerebellum, the spinal cord and the hypothalamus. For example, within the cerebral cortex, we are investigating how the NFI family of transcription factors mediate NSC differentiation, and how mutations to the NFI family culminate in macrocephaly, and disorders such as Malan syndrome. Moreover, we are using mice lacking the gene Nsd1(a histone modifying protein) to investigate the development of a human syndrome known as Sotos syndrome, which is also characterised by macrocephaly. In collaboration with Mikael Boden (SCMB), we are also investigating how changes to chromatin landscapes mediate NSC differentiation, and developing bioinformatic tools to enhance the analysis of RNA-seq and ChIP-seq datasets. Collectively, this work will provide fundamental insights into neural development, as well as insights into human neurodevelopmental disorders that arise as a result of abnormal neural stem cell biology in utero.

  • Adult neurogenesis

    The birth of new neurons within the mature cerebral cortex, a process termed neurogenesis, plays a critical role in learning, memory and spatial navigation. We are investigating various aspects of adult neurogenesis in rodent models, such as neural stem cell quiescence . We are also interrogating the consequences of abnormal neurogenesis using behavioural tests for learning and memory.

    We employ a range of transgenic mice to investigate adult neurogenesis, coupled with techniques ranging from immunocytochemistry, behavioural testing, analysis of axonal connectivity and genome-wide sequencing platforms. Given the critical roles that learning and memory play in our everyday lives, and the fact that neurogenesis within the adult brain diminishes with age, this research will provide fundamental insights into how this vital process is co-ordinated at a cellular and molecular level.

  • Identifying how abnormal neural stem cell biology contributes to disease

    The importance of NSC biology to brain development is underscored by disorders associated with abnormal NSC differentiation, including autism, hydrocephalus and macrocephaly. Despite the role of aberrant NSC development to these disorders, our understanding of the cellular and molecular deficits that contribute to disease onset and progression remains limited. Recently, my work has begun to focus on these disorders. Moreover, as the transcriptional landscape of many cancers resembles that of stem cells during development, I am also applying my expertise to understand how abnormal transcriptional activity contributes to cancer progression. This approach has gained significant traction, as evidenced by international awards (2015 Innovator Award, Hydrocephalus Association) and grants (Simons Foundation Autism Research Initiative, 2018-2019; Cancer Council Queensland, 2016-2017) I have received.

  • Understanding the drivers of neural stem cell differentiation

    What are the mechanisms that control neural stem cell (NSC) differentiation during embryogenesis, and that enable the generation of the diverse suite of neurons and glia that comprise the brain? This is a key question in developmental neuroscience. My contribution to this field to date has been to reveal central transcriptional regulators that mediate NSC biology within the brain. Using rodent model systems, I demonstrated that transcription factors of the Nuclear Factor One (NFI) family mediate NSC proliferation and differentiation in the embryonic, postnatal and adult nervous system. This work has received international recognition, as evidenced by numerous invited international presentations and high-impact reviews (e.g. Trends in Cell Biology), and forms the framework around which the hypotheses of this program will be addressed.

    I am interested in defining how NSC proliferation and differentiation is regulated at a transcriptional and epigenomic level within the developing nervous system. Using the developing mouse brain as a model system, we are using a suite of molecular and cellular techniques to understand how diverse regions of the nervous system are generated, including the cerebral cortex, the cerebellum, the spinal cord and the hypothalamus. For example, within the cerebral cortex, we are investigating how the NFI family of transcription factors mediate NSC differentiation, and how mutations to the NFI family culminate in macrocephaly, and disorders such as Malan syndrome. Moreover, we are using mice lacking the gene Nsd1(a histone modifying protein) to investigate the development of a human syndrome known as Sotos syndrome, which is also characterised by macrocephaly. In collaboration with Mikael Boden (SCMB), we are also investigating how changes to chromatin landscapes mediate NSC differentiation, and developing bioinformatic tools to enhance the analysis of RNA-seq and ChIP-seq datasets. Collectively, this work will provide fundamental insights into neural development, as well as insights into human neurodevelopmental disorders that arise as a result of abnormal neural stem cell biology in utero.

  • Adult neurogenesis

    The birth of new neurons within the mature cerebral cortex, a process termed neurogenesis, plays a critical role in learning, memory and spatial navigation. We are investigating various aspects of adult neurogenesis in rodent models, such as neural stem cell quiescence . We are also interrogating the consequences of abnormal neurogenesis using behavioural tests for learning and memory.

    We employ a range of transgenic mice to investigate adult neurogenesis, coupled with techniques ranging from immunocytochemistry, behavioural testing, analysis of axonal connectivity and genome-wide sequencing platforms. Given the critical roles that learning and memory play in our everyday lives, and the fact that neurogenesis within the adult brain diminishes with age, this research will provide fundamental insights into how this vital process is co-ordinated at a cellular and molecular level.

  • Identifying how abnormal neural stem cell biology contributes to disease

    The importance of NSC biology to brain development is underscored by disorders associated with abnormal NSC differentiation, including autism, hydrocephalus and macrocephaly. Despite the role of aberrant NSC development to these disorders, our understanding of the cellular and molecular deficits that contribute to disease onset and progression remains limited. Recently, my work has begun to focus on these disorders. Moreover, as the transcriptional landscape of many cancers resembles that of stem cells during development, I am also applying my expertise to understand how abnormal transcriptional activity contributes to cancer progression. This approach has gained significant traction, as evidenced by international awards (2015 Innovator Award, Hydrocephalus Association) and grants (Simons Foundation Autism Research Initiative, 2018-2019; Cancer Council Queensland, 2016-2017) I have received.

Supervision history

Current supervision

Completed supervision

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