Myelin-associated glycoprotein alters the neuronal secretome and stimulates the release of TGFß and proteins that affect neural plasticity.

Myelin-associated glycoprotein (MAG) and Nogo inhibit neurite outgrowth by binding to receptors such as NgR1, PirB and LRP1, and they have also been shown to induce phosphorylation of Smad2, a key intermediate in the transforming growth factor ß (TGFß) signalling pathway. In this study, we determined that MAG and Nogo do not transactivate the TGFß receptor through their canonical receptors or discoidin domain receptor 1, which we identified as a novel receptor for MAG and Nogo. Instead, MAG and Nogo promoted Smad2 phosphorylation by stimulating secretion of TGFß. Proteomic analysis of the neuronal secretome revealed that MAG also regulated the secretion of proteins that affect central nervous system plasticity-inducing the secretion of S100A6, septin-7 and neurofascin 186, while inhibiting the secretion of frataxin, MAP6, syntenin-1 and GAP-43. This represents a novel function for MAG that has broad implications for the treatment for spinal cord injury.

Cultural diversity and inclusion in UK medical schools.

BACKGROUND: Racially minoritised groups across the globe continue to experience differential outcomes in both health and education. Medical schools can play an instrumental role in addressing both these disparities, by creating inclusive student communities and ensuring that tomorrow's doctors can care for our increasingly diverse populations. OBJECTIVES: This collaborative, qualitative study led by three United Kingdom (UK) institutions aimed to explore the perspectives of Heads of Primary Care Teaching (HOTs) on cultural diversity and inclusion across UK medical schools. METHODS: In December 2020, five focus groups were conducted remotely with 23 HOTs, or a nominated deputy. We explored participants' opinions regarding opportunities and barriers to cultural diversity and inclusion in medical education, ways to overcome these challenges and shared examples of best practice. Data were transcribed verbatim and thematically analysed by three researchers. RESULTS: Investigators identified six themes from the data: lack of faculty diversity, tokenistic faculty training, institutional mindset, diversifying the formal and hidden curricula, intersectionality and student voice. CONCLUSION: Medical schools worldwide face similar challenges, uncertainties and opportunities when integrating diversity and inclusion throughout the learning environment. Although the importance of the topic is increasingly acknowledged, current efforts are viewed as being passive and tokenistic, hindered by challenges at multiple levels. Partnership with students and collaboration within and between institutions nationally and internationally will enable us to move forwards with both local and global positive, sustainable change.

Inhibition of Autophagy Flux Promotes Secretion of Chondroitin Sulfate Proteoglycans in Primary Rat Astrocytes.

Following spinal cord injury (SCI), reactive astrocytes in the glial scar produce high levels of chondroitin sulfate proteoglycans (CSPGs), which are known to inhibit axonal regeneration. Transforming growth factor beta (TGFß) is a well-known factor that induces the production of CSPGs, and in this study, we report a novel mechanism underlying TGFß's effects on CSPG secretion in primary rat astrocytes. We observed increased TGFß-induced secretion of the CSPGs neurocan and brevican, and this occurred simultaneously with inhibition of autophagy flux. In addition, we show that neurocan and brevican levels are further increased when TGFß is administered in the presence of an autophagy inhibitor, Bafilomycin-A1, while they are reduced when cells are treated with a concentration of rapamycin that is not sufficient to induce autophagy. These findings suggest that TGFß mediates its effects on CSPG secretion through autophagy pathways. They also represent a potential new approach to reduce CSPG secretion in vivo by targeting autophagy pathways, which could improve axonal regeneration after SCI.

The effect of mark enhancement techniques on the presumptive and confirmatory tests for blood.

An investigation into the effects of physical and chemical enhancement on subsequent presumptive and confirmatory tests for human blood is presented. Human blood was deposited onto porous (white 80 gsm paper and brown envelope) and non-porous (tile and linoleum) substrates in a depletion series (30 depletions on non-porous and 20 on porous) and subjected to three ageing periods; 1, 7 and 28 days. A number of enhancement techniques were tested [fluorescence, black magnetic powder (BMP), iron-oxide black powder suspension (PS), cyanoacrylate (CA) fuming, acid violet 17 (AV17), acid yellow 7 (AY7), ninhydrin, DFO and Bluestar Forensic Magnum (BFM) luminol] to evaluate their potential effects on subsequent presumptive and confirmatory tests. AV17 and Bluestar provided the best enhancement and fully enhanced all depletions in the series. The sensitivity of the Kastle-Meyer (KM) (presumptive), Takayama and RSID-Blood tests (confirmatory) was initially investigated to determine the range of detectable depletions. The KM test detected all depletions, whereas the Takayama test detected up to depletion 6 and RSID-Blood detected up to depletion 20 (paper), 10 (envelope), 15 (tile) and 9 (lino). The abilities of these tests to detect blood after enhancement were then observed. A number of techniques resulted in little to no effect on any of the blood tests, whereas adverse effects were observed for others. Ninhydrin and CA fuming caused weak but instantaneous positive KM results whereas methanol-based AV17 and AY7 delayed the reaction by as much as 1 min. The Takayama test was not very sensitive, therefore, its performance was easily affected by enhancement and negative results were often observed. RSID-Blood tests were largely unaffected by chemical enhancement although a drop in positive results was observed for some of the techniques when compared to positive controls. Using a standard procedure for DNA extraction, all the tested blood samples (before and after enhancement) gave a detectable quantity of DNA and were successfully profiled. Out of the 45 samples processed for DNA profiling, 41 gave full profiles, while the remaining showed allele drop out in one or two loci.

The Evolution of Polymorphic Hybrid Incompatibilities in House Mice.

Resolving the mechanistic and genetic bases of reproductive barriers between species is essential to understanding the evolutionary forces that shape speciation. Intrinsic hybrid incompatibilities are often treated as fixed between species, yet there can be considerable variation in the strength of reproductive isolation between populations. The extent and causes of this variation remain poorly understood in most systems. We investigated the genetic basis of variable hybrid male sterility (HMS) between two recently diverged subspecies of house mice, Mus musculus domesticus and Mus musculus musculus We found that polymorphic HMS has a surprisingly complex genetic basis, with contributions from at least five autosomal loci segregating between two closely related wild-derived strains of M. m. musculus One of the HMS-linked regions on chromosome 4 also showed extensive introgression among inbred laboratory strains and transmission ratio distortion (TRD) in hybrid crosses. Using additional crosses and whole genome sequencing of sperm pools, we showed that TRD was limited to hybrid crosses and was not due to differences in sperm motility between M. m. musculus strains. Based on these results, we argue that TRD likely reflects additional incompatibilities that reduce hybrid embryonic viability. In some common inbred strains of mice, selection against deleterious interactions appears to have unexpectedly driven introgression at loci involved in epistatic hybrid incompatibilities. The highly variable genetic basis to F1 hybrid incompatibilities between closely related mouse lineages argues that a thorough dissection of reproductive isolation will require much more extensive sampling of natural variation than has been commonly utilized in mice and other model systems.