Odile E. Said-Nejad scite author profile

Odile E. Said-Nejad

5Publications

67Citation Statements Received

17Citation Statements Given

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124

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University of California, San Diego

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Enkephalin analogues containing β‐naphthylalanine at the fourth position

et al. 1990

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To examine the importance of the aromatic side chains of enkephalin on opiate activity, we report the synthesis and conformational analysis of a series of analogues related to enkephalin with beta-naphthylalanine in place of phenylalanine at the fourth position. Three linear analogues (Tyr-D-Ala-Gly-(L and D)-beta Nal(1)-Leu-NH2 and Tyr-D-Ala-Gly-beta Nal(2)-Leu-NH2) were initially synthesized to examine the effect of the substitution on biological activity. The increased activity of these peptides at the mu-opiate receptor, compared to native Leu-enkephalin, prompted us to examine the more conformational constrained analogues, Tyr-c[D-A2bu-Gly-(L and D)-beta Nal(1)-Leu], incorporating a alpha, gamma-diaminobutyric acid at the second position and cyclization to the carboxylic end of the leucine. These two cyclic analogues provide insight into the necessity for the L chirality of the aromatic residue at position 4. The Tyr-c[D-A2bu-Gly-L-beta Nal(1)-Leu] analogue is highly potent and displays a slight preference for the mu receptor. The conformational analysis indicates that despite the high flexibility of the tyrosine side chain, the aromatic rings of the tyrosine and naphthylalanine are relatively distant from each other. The presence of two intramolecular hydrogen bonds help maintain the conformation of the 14-membered backbone ring that keeps the side chains directed away from each other. These findings are in agreement with our model of an extended structure required for mu selectivity and a folded form with close aromatic ring placement for delta selectivity.

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Conformational studies of stereoisomeric 14‐membered cyclic enkephalin analogues containing 1‐naphthyialanine at the fourth position: Chirality effect of leucine at the fifth position on biological activity and receptor selectivity

et al. 1991

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In order to study structure-activity relationships of enkephalin-related analogues, we report the biological activity and conformational analysis of four 14-membered cyclic enkephalin analogues with beta-(1-naphthyl) alanine in place of phenylalanine at the fourth position, Tyr-c[D-A2bu-Gly-(L and D)-beta Nal(1)-(L and D)-Leu]. The L-beta Nal(1)-containing analogues display higher activity at both the mu and delta receptors than the corresponding analogues with the L-Phe residue. In contrast to the linear enkephalins, the cyclic analogues with the D-beta Nal(1) residue are also active at the mu receptor since the relative spatial arrangement of functional groups required for biological activity is achieved by the constrained nature of the cyclic molecules. A comparison of the findings from the conformational analysis and biological assays establishes that relatively extended structures, in which the two aromatic side chains are oriented in opposite directions with a approximately 14 A separation, is required for activity at the mu receptor. On the other hand, folded conformations with nearly parallel orientations and a close proximity (less than 10A) of the aromatic rings of the Tyr and beta Nal(1) residues are required for activity at the delta receptor. It should be noted that the overall structures and thus the biological profiles of the 14-membered cyclic enkephalin analogues are strongly dependent on the conformation of the second residue. The folded conformations with parallel orientation of the two aromatic side chains of Tyr-c[D-A2bu-Gly-L-beta Nal(1)-D-Leu] is stabilized by an interaction between the Tyr phenolic OH proton and beta Nal(1) C*O groups. This analogue, which shows the highest activity at both the mu and delta receptors among the four stereoisomers studied, displays an increase of the fraction of the side-chain chi 1 = t conformer for the beta Nal(1) residue. It is concluded that the incorporation of the D-Leu residue at the fifth position increases the relative fraction of the folded conformations with parallel orientation of the aromatic side chains, and hence enhances activity at the delta receptor as compared to the corresponding L-Leu containing analogue.

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Cis/trans isomers in cyclic peptides without N-substituted amides

Mierke¹,

Yamazaki²,

Said-Nejad³

et al. 1989

J. Am. Chem. Soc.

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The first mechanism-based inactivators for angiotensin-converting enzyme

Ghosh¹,

Said-Nejad²,

Roestamadji³

et al. 1992

J. Med. Chem.

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The first example of mechanism-based inactivation of angiotensin-converting enzyme (ACE) is described for N-[N-(cyanoacetyl)-L-phenylalanyl]-L-phenylalanine (compound 1). It is proposed that an ACE-mediated deprotonation of 1 unmasks a ketenimine intermediate, which traps an active-site nucleophile, and hence irreversibly modifies the enzyme. In competition with the inactivation reaction, ACE also hydrolyzes 1 with a partition ratio of 8300 (i.e., kcat/kinact). Since the corresponding keto analogue, N-[(R)-2-benzyl-5-cyano-4-oxopentanyl]-L-phenylalanine (compound 4), does not inactivate the enzyme, it is suggested that the NH in compound 1 is critical for the proper active-site anchoring of the inhibitor for the inactivation process to take place.

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14‐Membered cyclic opioids related to dermorphin and their partially retro‐inverso modified analogues

Said-Nejad¹,

Felder²,

Mierke³

et al. 1992

International Journal of Peptide and Protein Research

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As a continuation of our program to study structure‐activity relationships of opiate peptides, we report the syntheses and biological activities of a series of 14‐membered cyclic dermorphin analogues closely related to enkephalin analogue Tyr‐c[d‐A2bu‐Gly‐Phe‐Leu] incorporating a phenylalanine at the third position in place of glycine. In addition to two parent dermorphin analogues Tyr‐c[d‐A2bu‐Phe‐Phe‐(l and D)‐Leu], four stereoisomeric retro‐inverso modified analogues Tyr‐c[D‐A2bu‐Phe‐gPhe‐(S and R)‐mLeu] with a reversed amide bond between residues four and five, and Tyr‐c[d‐Glu‐Phe‐gPhe‐(L and D)‐rLeu] with two reversed amide bonds between residues four and five, and between residue five and the side chain of residue two have been synthesized. The results from the guinea pig ileum (GPI) and mouse vas deferens (MVD) assays show that all analogues are superactive at either one or both opiate receptors and in general display higher activities as compared to the corresponding enkephalin analogues with a glycine at the third position. Results from the in vitro biological assays and conformational analysis using 1H‐NMR spectroscopy (adjoining paper) will provide useful information to understand the role of the Phe3 aromatic side chain in dermorphin, and that of the Phe4 aromatic side chain in enkephalin, on opiate activity since these cyclic dermorphin analogues contain two Phe residues at both the third and fourth positions.

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