Absence of Carboxypeptidase E/Neurotrophic Factor-Α1 in Knock-Out Mice Leads to Dysfunction of BDNF-TRKB Signaling in Hippocampus.

Carboxypeptidase E (CPE), first discovered as a prohormone processing enzyme, has also now been shown to be a secreted neurotrophic factor (neurotrophic factor-α1, NF-α1) that acts extracellularly as a signaling molecule to mediate neuroprotection, cortical stem cell differentiation, and antidepressive-like behavior in mice. Since brain-derived neurotrophic factor (BDNF) has very similar trophic functions, and its processing from pro-BDNF involves intracellular sorting of pro-BDNF to the regulated secretory pathway by CPE acting as a sorting receptor, we investigated whether the lack of CPE/NF-α1 would affect BDNF-TrkB signaling in mice. Previous studies have shown that CPE/NF-α1 knock-out (KO) mice exhibited severe neurodegeneration of the hippocampal CA3 region which raises the question of why other neurotrophic factors such as BDNF could not compensate for the deficiency of CPE. Here, we show that the expressions of pro-BDNF mRNA and protein in hippocampus of CPE-KO mice were similar to WT mice, but mature BDNF was ∼40% less in the CPE-KO mice, suggesting decreased intracellular processing of pro-BDNF. Furthermore, TrkB receptor levels were similar in both genotypes, but there was significantly decreased phosphorylation of TrkB receptor in the CPE-KO mice. Electrophysiological studies showed lack of formation of long-term potentiation in hippocampal slices of CPE-KO mice compared to WT mice, which was not rescued by application of BDNF, indicating dysfunction of the BDNF-TrkB signaling system. The CPE-KO mice showed normal postsynaptic AMPA response to kainate application in hippocampal slices and dissociated neurons. Our findings indicate that CPE/NF-α1 is essential for normal BDNF-TrkB signaling function in mouse hippocampus.

Carbamazepine Prevents Hippocampal Neurodegeneration in Mice Lacking the Neuroprotective Protein, Carboxypetidase E.

Carboxypeptidase E (CPE) has recently been described as a neuroprotective protein, and in mice devoid of CPE, a complete loss of the hippocampal CA3 neurons is observed. The pattern of loss is characteristic of that caused by status epilepticus. We therefore set out to determine when this loss occurred, what might induce it and if it could be prevented. We found that the hippocampus was intact in 4 week old CPE knock out (KO) mice that had not undergone weaning. However, weaning of 2 or 3 week old CPE KO mice, which involves maternal separation (emotional stress) and ear tagging and tail snipping for genotyping (physical stress), resulted in degeneration of the CA3 neurons by 3 and 4 weeks of age, respectively, while the wild-type mice were unaffected. Moreover, the physical stress caused a more severe neurodegeneration phenotype than the emotional stress of the maternal separation alone. Daily treatment with carbamazepine, an antiepileptic agent, in 2 week old CPE KO mice for 2 weeks prevented the neurodegeneration, despite the weaning process at 3 weeks. No further neurodegeneration was observed 3 weeks post weaning in carbamazepine treated mice. These results showed that degeneration of the CA3 neurons in the hippocampus, previously observed in 6 week old CPE KO mice, is not due to a developmental defect, but caused by physical and emotional stress during the weaning process. This degeneration was prevented by carbamazepine suggesting that the stress associated with weaning caused epileptic-like events in the CPE KO mice.

The processing of beta-endorphin and alpha-melanotrophin in the pars intermedia of Xenopus laevis is influenced by background adaptation.

beta-Endorphin- and alpha-melanotrophin (alpha-MSH)-related peptides were extracted from the pars intermedia of Xenopus laevis maintained for 2, 4 or 6 weeks on a white background and for the same periods on a black background. The peptides were resolved under dissociating conditions by gel exclusion chromatography on Sephadex G-50 and they were detected by radioimmunoassay with antibodies to beta-endorphin, alpha,N-acetyl beta-endorphin and alpha-MSH. The beta-endorphin-related peptides separated into two fractions of different molecular size. Further purification of the peptides in each fraction was by ion exchange chromatography on SP-Sephadex C-25 and by high-pressure liquid chromatography. The alpha-MSH-related peptides were resolved by gel exclusion and ion exchange chromatography. The purified beta-endorphin- and alpha-MSH-immunoreactive peptides were identified by comparison of their chromatographic properties with the corresponding peptides from porcine pituitary or by comparison with synthetic peptides. The major form of beta-endorphin in the pars intermedia of the frog adapted to a white background was identified as alpha,N-acetyl beta-endorphin (1-8); it was accompanied by a small quantity of acetylated peptides with molecular size similar to beta-endorphin. In contrast, the pars intermedia of the frogs adapted to a black background contained approximately equal amounts of alpha,N-acetyl beta-endorphin (1-8) and the larger forms of beta-endorphin. The higher molecular weight forms were identified as the alpha,N-acetyl derivatives of beta-endorphin (1-26), (1-27) and (1-31); however after 6 weeks of white adaptation the sole remaining peptide in this group was the 26-residue peptide. An additional beta-endorphin immunoreactive peptide, provisionally identified as beta-endorphin (10-26), was present in both black- and white-adapted animals; the amounts of this peptide increased during white adaptation. Major differences in the processing of alpha-MSH were also observed. In the frogs adapted to a black background des-acetyl alpha-MSH greatly predominated over the acetyl form whereas after 6- weeks adaptation to a white background the acetylated peptide proved to be the principal component. The results demonstrate that the proteolytic processing of beta-endorphin and the acetylation of alpha-MSH in Xenopus laevis are influenced by background adaptation. The formation of beta-endorphin (1-8) appears to reflect the action of an endopeptidase that acts at the single arginine residue present at position 9.(ABSTRACT TRUNCATED AT 400 WORDS)

Developmental expression of G proteins that differentially modulate adenylyl cyclase activity in mouse brain.

Changes in the relative abundance of the G protein alpha subunits were observed during early mouse development Gs alpha was almost exclusively present as a large form (Gs-1) in prenatal brain. Postnatally with a substantial increase in Gpp[NH]p stimulated adenylyl cyclase activity, the small form (Gs.s) increased in amount while Gs-1 decreased. These results suggest that the Gs-s may be the more effective cyclase activator and that changes in alternative splicing are developmentally regulated. Gi1 and Go appeared before birth whereas Gi2 developed postnatally. Opiate stimulation of GTPase and inhibition of adenylyl cyclase were fully expressed prenatally.