Mossy fiber sprouting and the genesis of ectopic granule cells contribute to reverberating excitation in the dentate gyrus of epileptic brain. This study determined whether the extent of sprouting after status epilepticus in rats correlates with the seizure-induced degeneration of GluR2-immunoreactive (GluR2+) hilar neurons (presumptive mossy cells) and also quantitated granule cell-like GluR2-immunoreactive hilar neurons. Stereological cell counting indicated that GluR2+ neurons account for 57% of the total hilar neuron population. Prolonged pilocarpine-induced status epilepticus killed 95% of these cells. A smaller percentage of GluR2+ neurons (74%) was killed when status epilepticus was interrupted after 1-3.5 h with a single injection of phenobarbital, and the number of residual GluR2+ neurons varied among animals by a factor of 6.2. GluR2+ neurons were not necessarily more vulnerable than other hilar neurons. In rats administered phenobarbital, the extent of recurrent mossy fiber growth varied inversely and linearly with the number of GluR2+ hilar neurons that remained intact (P = 0.0001). Thus the loss of each GluR2+ neuron was associated with roughly the same amount of sprouting. These findings support the hypothesis that mossy fiber sprouting is driven largely by the degeneration of and/or loss of innervation from mossy cells. Granule cell-like GluR2-immunoreactive neurons were rarely encountered in the hilus of control rats, but increased 6-to 140-fold after status epilepticus. Their number did not correlate with the extent of hilar cell death or mossy fiber sprouting in the same animal. The morphology, number, and distribution of these neurons suggested that they were hilar ectopic granule cells.
Dendritic Epidermal T Cells (DETCs) are generated exclusively in the fetal thymus and maintained in the skin epithelium throughout postnatal life of the mouse. DETCs have restricted antigenic specificity due to their exclusive usage of a canonical TCR. Although the importance of the TCR in DETC development has been well established, the exact role of TCR signaling in DETC homeostasis and function remains incompletely defined. Here, we investigated TCR signaling in fully matured DETCs by lineage-restricted deletion of the Lat gene, an essential signaling molecule downstream of the TCR. We found that Lat deletion impaired TCR-dependent cytokine gene activation and the ability of DETC undergoing proliferative expansion. However, LAT-deficient DETCs were able to maintain long-term population homeostasis even though with reduced proliferation rate. Mice with Lat deletion in DETCs exhibited delayed wound healing accompanied by impaired clonal expansion within the wound area. Our study revealed differential requirements of TCR signaling in homeostatic maintenance of DETCs and in their effector function during wound healing.
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