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1. Fetal cannabidiol (CBD) exposure alters thermal pain sensitivity, problem-solving, and prefrontal cortex excitability

   https://doi.org/10.1038/s41380-023-02130-y  

   Swenson, Karli S; Gomez_Wulschner, Luis E; Hoelscher, Victoria M; Folts, Lillian; Korth, Kamryn M; Oh, Won Chan; Bates, Emily Anne (August 2023, Molecular Psychiatry)

   Abstract Thousands of people suffer from nausea with pregnancy each year. Nausea can be alleviated with cannabidiol (CBD), a primary component of cannabis that is widely available. However, it is unknown how fetal CBD exposure affects embryonic development and postnatal outcomes. CBD binds and activates receptors that are expressed in the fetal brain and are important for brain development, including serotonin receptors (5HT_1A), voltage-gated potassium (Kv)7 receptors, and the transient potential vanilloid 1 receptor (TRPV1). Excessive activation of each of these receptors can disrupt neurodevelopment. Here, we test the hypothesis that fetal CBD exposure in mice alters offspring neurodevelopment and postnatal behavior. We administered 50 mg/kg CBD in sunflower oil or sunflower oil alone to pregnant mice from embryonic day 5 through birth. We show that fetal CBD exposure sensitizes adult male offspring to thermal pain through TRPV1. We show that fetal CBD exposure decreases problem-solving behaviors in female CBD-exposed offspring. We demonstrate that fetal CBD exposure increases the minimum current required to elicit action potentials and decreases the number of action potentials in female offspring layer 2/3 prefrontal cortex (PFC) pyramidal neurons. Fetal CBD exposure reduces the amplitude of glutamate uncaging-evoked excitatory post-synaptic currents, consistent with CBD-exposed female problem-solving behavior deficits. Combined, these data show that fetal CBD exposure disrupts neurodevelopment and postnatal behavior in a sex specific manner. 

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2. Netrin-1 stimulated axon growth requires the polyglutamylase TTLL1

   https://doi.org/10.3389/fnins.2024.1436312  

   Northington, Kyle R; Calderon, Jasmynn; Bates, Emily A (October 2024, Frontiers in Neuroscience)

   IntroductionIn the developing brain, neurons extend an axonal process through a complex and changing environment to form synaptic connections with the correct targets in response to extracellular cues. Microtubule and actin filaments provide mechanical support and drive axon growth in the correct direction. The axonal cytoskeleton responds to extracellular guidance cues. Netrin-1 is a multifunctional guidance cue that can induce alternate responses based on the bound receptor. The mechanism by which actin responds to Netrin-1 is well described. However, how Netrin-1 influences the microtubule cytoskeleton is less understood. Appropriate microtubule function is required for axon pathfinding, as mutations in tubulin phenocopy axon crossing defects of Netrin-1 and DCC mutants. Microtubule stabilization is required for attractive guidance cue response. The C-terminal tails of microtubules can be post-translationally modified. Post-translational modifications (PTMs) help control the microtubule cytoskeleton. MethodsWe measured polyglutamylation in cultured primary mouse cortical neurons before and after Netrin-1 stimulation. We used immunohistochemistry to measure how Netrin-1 stimulation alters microtubule-associated protein localization. Next, we manipulated TTLL1 to determine if Netrin-1-induced axon growth and MAP localization depend on polyglutamylation levels. ResultsIn this study, we investigated if Netrin-1 signaling alters microtubule PTMs in the axon. We found that microtubule polyglutamylation increases after Netrin-1 stimulation. This change in polyglutamylation is necessary for Netrin-1-induced axonal growth rate increases. We next determined that MAP1B and DCX localization changes in response to Netrin-1. These proteins can both stabilize the microtubule cytoskeleton and may be responsible for Netrin-1-induced growth response in neurons. The changes in DCX and MAP1B depend on TTLL1, a protein responsible for microtubule polyglutamylation. 

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3. Calcium dynamics tune developmental tempo to generate evolutionarily divergent axon tract lengths

   https://doi.org/10.1101/2024.12.28.630576  

   Lindhout, Feline W; Szafranska, Hanna M; Imaz-Rosshandler, Ivan; Guglielmi, Luca; Moarefian, Maryam; Voitiuk, Kateryna; Zernicka-Glover, Natalia K; Boulanger, Jerome; Schulze, Ulrike; Lloyd-Davies_Sánchez, Daniel J; et al (December 2024, bioRxiv)

   ABSTRACT The considerably slow pace of human brain development correlates with an evolutionary increase in brain size, cell numbers, and expansion of neuronal structures, with axon tracts undergoing an even greater evolutionary increase than other neuronal domains. However, whether tempo is responsible for these differences in magnitude, and how, remains to be determined. Here, we used brain organoids to investigate this and observed that human axon tracts spend more time growing and extend farther compared to those of mice, independent of their tissue environment. Single cell RNA sequencing analysis pointed to a subset of calcium-permeable ion channels expressed throughout neuron development, including during axon tract outgrowth. Calcium imaging during early neuron development consistently revealed a reduced calcium influx in human neurons compared to mouse neurons. Stimulating calcium influx and increasing cAMP levels resulted in premature halting of axon tract outgrowth and shorter axon tracts, mimicking the mouse phenotype, while abrogating calcium influx led to an even longer phase of axon tract outgrowth and longer axon tracts in humans. Thus, evolutionary differences in calcium regulation set the tempo of neuronal development, by extending the time window to foster the more elaborated human neuron morphology. 

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4. Investigating the impact of the phosphorylation status of tyrosine residues within the TACC domain of TACC3 on microtubule behavior during axon growth and guidance

   https://doi.org/10.1002/cm.21622  

   Erdogan, Burcu; St. Clair, Riley M.; Cammarata, Garrett M.; Zaccaro, Timothy; Ballif, Bryan A.; Lowery, Laura Anne (July 2020, Cytoskeleton)

   Abstract Axon guidance is a critical process in forming the connections between a neuron and its target. The growth cone steers the growing axon toward the appropriate direction by integrating extracellular guidance cues and initiating intracellular signal transduction pathways downstream of these cues. The growth cone generates these responses by remodeling its cytoskeletal components. Regulation of microtubule dynamics within the growth cone is important for making guidance decisions. TACC3, as a microtubule plus‐end binding (EB) protein, modulates microtubule dynamics during axon outgrowth and guidance. We have previously shown thatXenopus laevisembryos depleted of TACC3 displayed spinal cord axon guidance defects, while TACC3‐overexpressing spinal neurons showed increased resistance to Slit2‐induced growth cone collapse. Tyrosine kinases play an important role in relaying guidance signals to downstream targets during pathfinding events via inducing tyrosine phosphorylation. Here, in order to investigate the mechanism behind TACC3‐mediated axon guidance, we examined whether tyrosine residues that are present in TACC3 have any role in regulating TACC3's interaction with microtubules or during axon outgrowth and guidance behaviors. We find that the phosphorylatable tyrosines within the TACC domain are important for the microtubule plus‐end tracking behavior of TACC3. Moreover, TACC domain phosphorylation impacts axon outgrowth dynamics such as growth length and growth persistency. Together, our results suggest that tyrosine phosphorylation of TACC3 affects TACC3's microtubule plus‐end tracking behavior as well as its ability to mediate axon growth dynamics in cultured embryonic neural tube explants. 

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5. Cannabis sativa CBD Extract Exhibits Synergy with Broad-Spectrum Antibiotics against Salmonella enterica subsp. Enterica serovar typhimurium

   https://doi.org/10.3390/microorganisms10122360  

   Gildea, Logan; Ayariga, Joseph Atia; Xu, Junhuan; Villafane, Robert; Robertson, Boakai K.; Samuel-Foo, Michelle; Ajayi, Olufemi S. (December 2022, Microorganisms)

   New generation antibiotics are needed to combat the development of resistance to antimicrobials. One of the most promising new classes of antibiotics is cannabidiol (CBD). It is a non-toxic and low-resistance chemical that can be used to treat bacterial infections. The antibacterial activity of Cannabis sativa L. byproducts, specifically CBD, has been of growing interest in the field of novel therapeutics. As research continues to define and characterize the antibacterial activity that CBD possesses against a wide variety of bacterial species, it is important to examine potential interactions between CBD and common therapeutics such as broad-spectrum antibiotics. In this study it is demonstrated that CBD-antibiotic (combination of CBD and antibiotic) co-therapy can effectively fight Salmonella typhimurium (S. typhimurium) via membrane integrity disruption. This research serves to examine the potential synergy between CBD and three broad-spectrum antibiotics (ampicillin, kanamycin, and polymyxin B) for potential CBD-antibiotic co-therapy. In this study, it is revealed that S. typhimurium growth is inhibited at very low dosages of CBD-antibiotic. This interesting finding demonstrates that CBD and CBD-antibiotic co-therapies are viable novel alternatives to combating S. typhimurium. 

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