324 Milk Fat Globule Membrane from Bovine Milk on Brain Development of Early Life

The milk fat globule membrane (MFGM) is instrumental for the fat delivery system into human and bovine milk, but is typically removed during the manufacture of infant formula. MFGM contains components that may impact neurodevelopment, including sialic acid, gangliosides, sphingomyelin, choline, glycerophospholipids, proteins, and cholesterol. This presentation will review the clinical trial evidence linking MFGM supplementation to beneficial outcomes in infants and will describe potential mechanistic evidence linking MFGM with neurocognitive outcomes arising from preclinical studies in piglets. Infants fed formula supplemented with a MFGM (4% total protein) from 2 to 6 months of age had improved neurocognitive development at 1 year of age compared to infants fed standard formula. Infants fed formula with MFGM (5.0 g/L) and lactoferrin (0.6 g/L) for 1 year had an accelerated neurodevelopmental profile at 1 year and improved language subcategories at 18 months compared to infants fed a standard formula. To investigate potential mechanisms, piglets were fed a CONT formula or a TEST formula with MFGM and lactoferrin at the same concentrations from 2 to 31 days of age. Piglets underwent spatial T-maze testing to assess learning and memory, and magnetic resonance imaging to measure brain micro- and macrostructure. TEST piglets had lower radial and mean diffusivities in the internal capsule, suggesting greater myelination. The internal capsule contains motor and sensory projections from the cortex to corticospinal tract. Piglets on the CONT diet displayed shorter latency to choice in the T-maze compared to TEST piglets, potentially indicating anxiety-like behaviors or greater impulsivity. Aspects of the microbiome-gut-brain-axis (MGBA) were investigated to uncover potential mechanisms. TEST piglets had higher protein abundance of tyrosine hydroxylase and vasoactive intestinal peptide, longer villi and greater disaccharidase activity in the small intestine and differences in microbial abundances in the ascending colon and feces, suggesting potential modulation of the MGBA by MFGM.

Actin crosslinker competition and sorting drive emergent GUV size-dependent actin network architecture

Robust spatiotemporal organization of cytoskeletal networks is crucial, enabling cellular processes such as cell migration and division. α-Actinin and fascin are two actin crosslinking proteins localized to distinct regions of eukaryotes to form actin bundles with optimized spacing for cell contractile machinery and sensory projections, respectively. In vitro reconstitution assays and coarse-grained simulations have shown that these actin bundling proteins segregate into distinct domains with a bundler size-dependent competition-based mechanism, driven by the minimization of F-actin bending energy. However, it is not known how physical confinement imposed by the cell membrane contributes to sorting of actin bundling proteins and the concomitant reorganization of actin networks in intracellular environment. Here, by encapsulating actin, α-actinin, and fascin in giant unilamellar vesicles (GUVs), we show that the size of such a spherical boundary determines equilibrated structure of actin networks among three typical structures: single rings, astral structures, and star-like structures. We show that α-actinin bundling activity and its tendency for clustering actin is central to the formation of these structures. By analyzing physical features of crosslinked actin networks, we show that spontaneous sorting and domain formation of α-actinin and fascin are intimately linked to the resulting structures. We propose that the observed boundary-imposed effect on sorting and structure formation is a general mechanism by which cells can select between different structural dynamical steady states.

Cas Adaptor Proteins Coordinate Sensory Axon Fasciculation

Development of complex neural circuits like the peripheral somatosensory system requires intricate mechanisms to ensure axons make proper connections. While much is known about ligand-receptor pairs required for dorsal root ganglion (DRG) axon guidance, very little is known about the cytoplasmic effectors that mediate cellular responses triggered by these guidance cues. Here we show that members of the Cas family of cytoplasmic signaling adaptors are highly phosphorylated in central projections of the DRG as they enter the spinal cord. Furthermore, we provide genetic evidence that Cas proteins act DRG-autonomously to promote fasciculation of sensory projections. These data establish an evolutionarily conserved requirement for Cas adaptor proteins during peripheral nervous system axon pathfinding. They also provide insight into the interplay between axonal fasciculation and adhesion to the substrate.

BrainstemPart Two

Chapter 10 also discusses the brainstem, and covers major sensory projections, major motor projections, midbrain syndromes, pontine syndromes, and medullary syndromes.