User:Kileytimmons/sandbox

ASPM article addition:

Animal studies
One mouse study looking at medulloblastoma growth in mice to study the Aspm gene, an ortholog to human ASPM, suggests that Aspm expression may drive postnatal cerebellar neurogenesis. This process occurs late in embryogenesis and immediately after birth over a time span of about 2 weeks in mice and 12 months in humans, and is regulated by the expression of the Shh gene. In proliferating cerebellar granule neuron progenitors (CGNPs), Shh expression in mouse models showed four times the amount of Aspm expression than those deprived of Shh expression in-vivo. This induction of Aspm and up-regulation during cerebellar neurogenesis was also seen in real-time PCR, where its expression was relatively high at the peak of neurogenesis and much lower at the end of neurogenesis. Additionally, the study indicates that Aspm is necessary for cerebellar neurogenesis. In the presence of Aspm KO mutations and deletions, experimental mice models show decreased cerebellar volume under MRI, compared to the controls. In addition to mutated Aspm’s effects on neurogenesis, these mutations may also play a role in neural differentiation. When looking at adult brains in Aspm KO mice, there was a trend in overall size reduction, and variations in cortical thickness between mutant and wild type models. In the somatosensory cortex, KO mice had a significantly thicker layer I cortex, thinner layer VI cortex, and an overall decrease in cortical thickness in the cortical plate. Certain transcription factors expressions were also abnormal in the KO mice. For example, Tbr1 and Satb2 had an increased presence in the cortical sub-plate, the first of which is important for differentiation and neuronal migration, and the second of which is a regulator of transcription and chromosomal remodeling.

While mouse studies have established the role of Aspm mutations in microcephaly, several have linked this mutation to other significant defects. One study showed nerve fiber impairments in which the shape and form of cortex and white matter tissue was altered. This was shown postnatally comparing KO mice and controls, where both cell number and cortical thickness was decreased in KO mice. Using a cell staining methodology for histological analysis, the study also showed shorter distances between adjacent neurons in KO mice, indicating abnormalities in cell alignment in the absence of normal Aspm.

Another significant impact of mutated Aspm is seen in germline abnormalities within mouse models. Mutations in Aspm were shown to reduce fertility in both female and male mice, indicated by a decrease in the rate of pregnancy and consequently the number of offspring, as well as a decrease in female ovarian size, as well as male sperm count and testicular size. The focus on severe germline mutations (as opposed to only mild microcephaly) in these mouse models raises the question as to whether or not human ASPM selection may be more significantly linked to reproduction than brain size.

In addition to mouse models, a study using ferrets reveals more about ASPM and its role in determining cortical size and thickness. The researchers from this study chose ferrets over mouse models due to incongruencies between Aspm effects in mice versus ASPM effects in humans - humans with microcephaly due to this gene mutation tend to have significantly reduced brain sizes (about 50% reduction), whereas the analogous mutation in mice only results in mild brain size reduction. Ferrets also show more similarities to humans in terms of brain structure; ferrets' brains have gyrification in high amounts similar to humans, different from the relatively smooth brains of mice. As a result, there is less cortical surface area in mice compared to that of ferrets and humans. In this 2018 study, researchers targeted Aspm exon 15, where a mutation in humans is linked to severe cases of microcephaly. With a loss of function in Aspm, ferrets with Aspm mutations saw a 40% decrease in overall brain size coupled with no reduction in body size, similar to the effects of loss of ASPM in humans. The study also looked at the neurodevelopmental pathways and mechanisms leading to neurogenesis in the KO ferrets compared to the WT controls, specifically studying three different neuron progenitor cell (NPC) types, all of which express the mitotic marker Ki-67 and undergo radial glial migration to the cortical plate. They found that outer subventricular zone (OSVZ) NPCs were largely displaced, especially frontally and dorsally which mirrors the effects seen in cortical volume reductions due to ASPM KO.