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Genetic, Ontogenetic, and Tissue-specific Variation of Dipeptidases in Drosophila Melanogaster

Overview
Journal Biochem Genet
Specialty Molecular Biology
Date 1982 Jun 1
PMID 6810870
Citations 9
Authors
C C Laurie-Ahlberg
Affiliations
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Abstract

Three dipeptidases in Drosophila melanogaster are under independent genetic control and their structural genes have been localized, Dip-A to 2R and Dip-B and Dip-C to 3R (Voelker and Langley, 1978; Ohnishi and Voelker, 1981). These enzymes were characterized with respect to their substrate specificities, genetic variability (electrophoretic mobility and quantitative activity level), ontogeny (activity and isozyme pattern), and tissue localization. The dipeptide substrate specificities of DIP-A and DIP-B overlap each other considerably, but do not overlap with DIP-C. In natural populations, DIP-B and DIP-C are essentially monomorphic electrophoretically whereas DIP-A is polymorphic for three allozymes. Both DIP-A and DIP-B show quantitative genetic variation of activity level within an allozyme class. All three enzymes are expressed at all stages in the life cycle, but DIP-A and DIP-B activities vary considerably according to developmental stage and sex of adult. The tissue localizations of DIP-A and DIP-B activities show similar patterns and a nearly ubiquitous occurrence of both enzymes, but with particularly high values in larval and adult midguts and in the adult female reproductive system. These results suggest a general metabolic role for the enzymes, such as regulation of the concentrated pools of amino acids and oligopeptides found in Drosophila tissues.

Citing Articles

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Reliability of transferrin and leucine aminopeptidase phenotyping in wild meadow voles (Microtus pennsylvanicus).

Mihok S, EWING D Biochem Genet. 1983; 21(9-10):969-83.

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Genetic variability of flight metabolism in Drosophila melanogaster. II. Relationship between power output and enzyme activity levels.

Laurie-Ahlberg C, Barnes P, Curtsinger J, Emigh T, Karlin B, Morris R Genetics. 1985; 111(4):845-68.

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Genetic characterization of dipeptidase activity modifiers in Drosophila melanogaster from natural populations.

Hiraizumi K, Laurie C Biochem Genet. 1988; 26(11-12):783-803.

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Peptidases in Drosophila melanogaster. I. Characterization of dipeptidase and leucine aminopeptidase activities.

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