Sex differences in neuronal differentiation of human stem cells

Sexual dimorphism has been long noted in human neurobiology, apparent most notably in sex-biased distribution of multiple neurological disorders or diseases, from autism spectrum disorder to Parkinson's disease. With the advances in molecular biology, genetics and epigenetics have come into focus as key players in sexually dimorphic neural development; and yet, many studies in the field of neuroscience overlook the importance of sex for the human brain. For this project, human embryonic and neural stem cells were chosen for three main reasons. Firstly, they provide an easily obtainable, scalable and physiologically native model for the early stages of development. Secondly, neural stem cells populations are retained within the adult human brain, and are implicated to play a role in cognition and mental illness, and as such are of interest in themselves. Thirdly, stem cell lines are widely used in research, including clinical trials of transplantation treatments, and for this reason should be meticulously examined and characterized. Here, the morphology, behaviour, and expression of selected genes in four stem cell lines, two of female and two of male origin, was examined in side-by-side comparisons prior to and during neuronal differentiation using a variety of methods including light microscopy, time-lapse two-photon microscopy, quantitative real-time PCR and immunocytochemistry. The obtained results have shown previously uncharacterised differences between those cell lines, such as a higher rate of proliferation but a slower rate of neuronal differentiation in male cell cultures compared to female cells cultivated in the same conditions, and a sex-biased expression of several markers of neuronal maturation at late stages of differentiation, as well as diverse patterns of expression of X- and Y-linked genes involved in stem cell proliferation and neural development

Sex differences in neuronal differentiation of human stem cells

Sexual dimorphism has been long noted in human neurobiology, apparent most notably in sex-biased distribution of multiple neurological disorders or diseases, from autism spectrum disorder to Parkinson's disease. With the advances in molecular biology, genetics and epigenetics have come into focus as key players in sexually dimorphic neural development; and yet, many studies in the field of neuroscience overlook the importance of sex for the human brain. For this project, human embryonic and neural stem cells were chosen for three main reasons. Firstly, they provide an easily obtainable, scalable and physiologically native model for the early stages of development. Secondly, neural stem cells populations are retained within the adult human brain, and are implicated to play a role in cognition and mental illness, and as such are of interest in themselves. Thirdly, stem cell lines are widely used in research, including clinical trials of transplantation treatments, and for this reason should be meticulously examined and characterized. Here, the morphology, behaviour, and expression of selected genes in four stem cell lines, two of female and two of male origin, was examined in side-by-side comparisons prior to and during neuronal differentiation using a variety of methods including light microscopy, time-lapse two-photon microscopy, quantitative real-time PCR and immunocytochemistry. The obtained results have shown previously uncharacterised differences between those cell lines, such as a higher rate of proliferation but a slower rate of neuronal differentiation in male cell cultures compared to female cells cultivated in the same conditions, and a sex-biased expression of several markers of neuronal maturation at late stages of differentiation, as well as diverse patterns of expression of X- and Y-linked genes involved in stem cell proliferation and neural development

Hyperactive mTORC1 disrupts habenula function and light preference in zebrafish model of Tuberous sclerosis complex

Summary: Mechanistic target of rapamycin complex 1 (mTORC1) is an integration hub for extracellular and intracellular signals necessary for brain development. Hyperactive mTORC1 is found in autism spectrum disorder (ASD) characterized by atypical reactivity to sensory stimuli, among other symptoms. In Tuberous sclerosis complex (TSC) inactivating mutations in the TSC1 or TSC2 genes result in hyperactivation of the mTORC1 pathway and ASD. Here, we show that lack of light preference of the TSC zebrafish model, tsc2vu242/vu242 is caused by aberrant processing of light stimuli in the left dorsal habenula and tsc2vu242/vu242 fish have impaired function of the left dorsal habenula, in which neurons exhibited higher activity and lacked habituation to the light stimuli. These characteristics were rescued by rapamycin. We thus discovered that hyperactive mTorC1 caused aberrant habenula function resulting in lack of light preference. Our results suggest that mTORC1 hyperactivity contributes to atypical reactivity to sensory stimuli in ASD