Neuropeptide Amidation in Drosophila: Separate Genes Encode the Two Enzymes Catalyzing Amidation

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Volume 17, Number 4, Issue of February 15, 1997 pp. 1363-1376
Copyright ©1997 Society for Neuroscience

Neuropeptide Amidation in Drosophila: Separate Genes Encode the Two Enzymes Catalyzing Amidation

Received Aug. 15, 1996; revised Nov. 5, 1996; accepted Dec. 2, 1996.
Aparna S. Kolhekar¹, Marie S. Roberts², Ning Jiang², Richard C. Johnson¹, Richard E. Mains¹, Betty A. Eipper¹, and Paul H. Taghert²
¹ Departments of Neuroscience and Physiology, The Johns Hopkins University School of Medicine, Baltimore, Maryland 21205, and ² Department of Anatomy and Neurobiology, Washington University Medical School, St. Louis, Missouri 63110
In vertebrates, the two-step peptide $alpha$ -amidation reaction is catalyzed sequentially by two enzymatic activities containedwithin one bifunctional enzyme called PAM (peptidylglycine $alpha$ -amidatingmono-oxygenase). Drosophila head extracts contained both of thesePAM-related enzyme activities: a mono-oxygenase (PHM) and a lyase(PAL). However, no bifunctional PAM protein was detected. We identifiedcDNAs encoding an active mono-oxygenase that is highly homologousto mammalian PHM. PHM-like immunoreactivity was found within diverselarval tissues, including the CNS, endocrine glands, and gut epithelium.Northern and Western blot analyses demonstrate RNA and proteinspecies corresponding to the cloned PHM, but not to a bifunctionalPAM, leading us to predict the existence of separate PHM and PALgenes in Drosophila. The Drosophila PHM gene displays an organizationof exons that is highly similar to the PHM-encoding portion ofthe rat PAM gene. Genetic analysis was consistent with the predictionof separate PHM and PAL gene functions in Drosophila: a P elementinsertion line containing a transposon within the PHM transcriptionunit displayed strikingly lower PHM enzyme levels, whereas PALlevels were increased slightly. The lethal phenotype displayedby the dPHM P element insertion indicates a widespread essentialfunction. Reversion analysis indicated that the lethality associatedwith the insertion chromosome likely is attributable to the Pelement insertion. These combined data indicate a fundamentalevolutionary divergence in the genes coding for critical neurotransmitterbiosynthetic enzymes: in Drosophila, the two enzyme activitiesof PAM are encoded by separate genes.

Key words: neuropeptide biosynthesis; Drosophila; $alpha$ -amidation; PAM; PHM; genetics; P element

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