l-histidine induces state-dependent memory deficit in mice mediated by H(1) receptor.

This study investigated the role of H(1) receptor in the state-dependent memory deficit induced by l-histidine (LH) in mice using Trial 1/2 protocol in the elevated plus-maze (EPM). The test was performed for two consecutive days: Trial 1 (T1) and Trial 2 (T2). Before both trials, mice received a combined injection i.p. of saline+saline (SAL/SAL), 500 mg/kg L-histidine+saline (LH/SAL), 500 mg/kg L-histidine+16 mg/kg chlorpheniramine (LH/CPA) or saline+16 mg/kg chlorpheniramine (SAL/CPA). The trials were performed in the EPM 10 min after the last injection. Each animal was placed in the center of the maze facing the open arm and had five minutes to explore it. On both days, test sessions were videotaped. The behavioral measures were scored from videotape. Data were analyzed based on Analysis of Variance (ANOVA) and the Fisher's LSD test. The data showed no effects on anxiety since there was no difference between the SAL/SAL and the other groups in Trial 1, respectively, open arm entries (OAE), open arm time (OAT) and their percentages (%OAE and %OAT). During Trial 2, OAE, OAT, %OAE and %OAT were reduced in mice treated with SAL/SAL, LH/CPA and SAL/CPA, while the group LH/SAL did not show any difference in these measures. No significant changes were observed in enclosed arm entries (EAE), an EPM index of general exploratory activity. Thus, it can be suggested that LH induces emotional memory deficit and the treatment with chlorpheniramine was able to revert this effect, suggesting this action of LH was mediated by the H(1) receptor.

Histidines 13 and 14 in the Abeta sequence are targets for inhibition of Alzheimer's disease Abeta ion channel and cytotoxicity.

The fact that Alzheimer's beta amyloid (Abeta) peptides forms cation channels in lipid bilayers was discovered during the course of our experiments in the laboratory of "Guayo" Rojas at NIH in Bethesda, Maryland (USA). Recently, we found that the Abeta ion channel could be blocked selectively with small peptides that copy the amino acid sequence of the predicted mouth region of the Abeta channel pore. We now have searched for the essential amino acid residues required for this blocking effect by mutations. We found that the ability of peptides to block Abeta channel activity could be lost by replacement of histidines 13 and 14 by alanine or lysine. The amino acid substitution also resulted in the loss of the capacity of the peptides to protect cells from Abeta cytotoxicity. These data thus contribute to the definition of the region of the Abeta sequence that participates in the formation of the channel pore. Additionally, these data support the hypothesis that the ion channel activity of Ab contributes significantly to the cytotoxic properties of Abeta. These data also emphasize the potential value in using inhibition of Abeta ion channel activity as an end point for Alzheimer's disease drug discovery.

Histidines 13 and 14 in the Aâ sequence are targets for inhibition of Alzheimer's disease Aâ ion channel and cytotoxicity

The fact that Alzheimer's beta amyloid (Aâ) peptides forms cation channels in lipid bilayers was discovered during the course of our experiments in the laboratory of "Guayo" Rojas at NIH in Bethesda, Maryland (USA). Recently, we found that the Aâ ion channel could be blocked selectively with small peptides that copy the amino acid sequence of the predicted mouth region of the Aâ channel pore. We now have searched for the essential amino acid residues required for this blocking effect by mutations. We found that the ability of peptides to block Aâ channel activity could be lost by replacement of histidines 13 and 14 by alanine or lysine. The amino acid substitution also resulted in the loss of the capacity of the peptides to protect cells from Aâ cytotoxicity. These data thus contribute to the definition of the region of the Aâ sequence that participates in the formation of the channel pore. Additionally, these data support the hypothesis that the ion channel activity of Ab contributes significantly to the cytotoxic properties of Aâ. These data also emphasize the potential value in using inhibition of Aâ ion channel activity as an end point for Alzheimer's disease drug discovery.