Local intraspinal or intramuscular administration of brain-derived or glial cell line-derived neurotrophic factors (BDNF, GDNF) is known to protect neural tissue after traumatic spinal cord injury (SC Show more
Local intraspinal or intramuscular administration of brain-derived or glial cell line-derived neurotrophic factors (BDNF, GDNF) is known to protect neural tissue after traumatic spinal cord injury (SCI). In this study, we investigated whether oral supplementation with antioxidant carnosine, a natural dipeptide, could stimulate endogenous production of these neuroprotective molecules within the neural and muscle microenvironment 6 weeks after SCI. We assessed the effects of 6-week carnosine treatment in female Zucker rats, administered either before (CB-I) or after injury (CA-I). The impact of thoracic SCI and carnosine treatment was evaluated in in/active microenvironments of fore limb and hind limb muscles, along with their corresponding innervation regions. To better understand how carnosine treatment affects the neural microenvironment, we analysed mRNA expression levels of neurotrophic factors and their receptors. We also examined molecules that may indicate which cell types are involved in producing or responding to BDNF or GDNF in the spinal cord. Six weeks after thoracic SCI, we observed better locomotor recovery in CA-I compared to CB-I treated rats. In the hind limb, posttraumatic carnosine treatment prevented SCI-induced reductions in BDNF and GDNF protein levels. Additionally, this treatment blocked the SCI-induced reduction of GDNF protein levels and the oligodendrocyte-specific gene Olig2 in the lumbar and cervical spinal cord segments. Interestingly, the postinjury treatment elevated the gene expression in BDNF receptor- and astrocyte-specific genes in the cervical segments. The finding that carnosine may prevent BDNF and GDNF declines in denervated hind limb muscles positions this dipeptide as a promising candidate for inclusion in future combination therapies. Show less
Obesity-related health issues, including cognitive decline linked to hippocampal neurogenesis and neuroplasticity, are gaining more attention as obesity rates rise worldwide. Physical activity is reco Show more
Obesity-related health issues, including cognitive decline linked to hippocampal neurogenesis and neuroplasticity, are gaining more attention as obesity rates rise worldwide. Physical activity is recognized as a potent stimulator of neurotrophic factors. This study examined the impact of six weeks of treadmill training on hippocampal molecular pathways in adult female Zucker diabetic fatty (obese) and Zucker lean rats. Animals were assigned to either treadmill exercise (n = 10) or sedentary control (n = 10) groups. Endurance training (ET) markedly upregulated mRNA expression of brain-derived neurotrophic factor and its receptor. The PI3K/Akt pathway was upregulated only in the trained lean rats and downregulated in the trained obese group compared with sedentary controls. ET elicited divergent effects on neurotrophin-associated PLCγ/PKC/CAMKII signalling between lean and obese groups. Sedentary obese rats primarily utilized the PLCγ/PKC axis, while both trained groups (lean and obese) showed increased CAMKII expression, associated with enhanced synaptic plasticity and memory. Enhanced synaptophysin mRNA indicated improved synaptogenesis and plasticity following ET. Trained obese rats also exhibited reduced expression of the microglial pro-inflammatory marker Iba1, alongside increased markers of oligodendrocyte regeneration and neurofilament expression. Behavioral assessment via the passive avoidance test demonstrated improved learning and memory in trained obese animals. Collectively, these findings suggest that ET may mitigate obesity-induced hippocampal damage, exert neuroprotection, and enhance hippocampal function. Show less