The utilization of sterols by insects

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The utilization of sterols by insects

R. B. Clayton

Department of Psychiatry, Stanford University School of Medicine, Palo Alto, California

The experimental data discussed in this review are fragmentaryand frequently fail, in a most tantalizing fashion, to allowof precise interpretation. For reasons that are indicated, ashadow of uncertainty hangs over several of the nutritionaldata discussed. The problems inherent in working with the smallamounts of material available from insects' tissues have alsocontributed to the difficulties of interpretation, and evenwhen an unambiguous experimental result is obtained, it maywell be hazardous to generalize from one or two species to allmembers of the class, which, after all, is the largest in theanimal kingdom.

Nevertheless, it is becoming clear that thesterols play a role in insect physiology that seems remarkablysimilar to that of cholesterol in the mammal. It is evidentthat both "structural" and metabolic functions are fulfilled,and there is evidence for the existence of mechanisms for theexcretion of sterols and their metabolites. If the latter areexcretory forms of physiologically active substances, it seemsclear that some metabolites other than ecdysone must be involved,since polar derivatives of cholesterol have been detected inthe tissues of adult insects in which, presumably, the prothoracicglands have degenerated and ecdysone is no longer secreted.

Studiesof the distribution and dynamic state of the tissue sterolsof insects show that the sterols per se have diverse roles withinthe tissues, which for convenience may be described as "structural."Many species of insects can modify the sterols of their dietand presumably such modifications serve to provide a structurethat is more appropriate to one or all of the insect's requirements.It is not entirely clear whether phytosterols must always beconverted to some extent to cholesterol, but one must concludefrom the data available that species differ widely in the extentto which they carry out such conversions. This suggests thatwhile there is probably a basic unity among all species withrespect to the types of multimolecular structures into whichthe sterols are incorporated, there are species differencesin the detailed structure of the immediate environment of thesterol molecule. A rewarding aspect of future research in thisfield may well be the analysis of the relationship between sterolsof different structures and the other lipid molecules with whichthey are associated in the cells of different species. Suchstudies may shed new light on the manner in which sterols contributeto the stability of subcellular structures.

It is almost certainthat with the structure of ecdysone finally established as thatof a steroid and its biogenesis from cholesterol demonstrated,there will be increasing interest in the functions of sterolsand steroids in insects. It is hoped that this review showsthat there is an emergent body of coherent biochemical and physiologicalinformation to serve as a basis for future work.

Submitted on June 26, 1963

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				J. West, R. Hernandez, D. Ferreira, and D. T. Brown Mutations in the Endodomain of Sindbis Virus Glycoprotein E2 Define Sequences Critical for Virus Assembly J. Virol., May 1, 2006; 80(9): 4458 - 4468. [Abstract] [Full Text] [PDF]

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				R. Hernandez, C. Sinodis, M. Horton, D. Ferreira, C. Yang, and D. T. Brown Deletions in the Transmembrane Domain of a Sindbis Virus Glycoprotein Alter Virus Infectivity, Stability, and Host Range J. Virol., December 1, 2003; 77(23): 12710 - 12719. [Abstract] [Full Text] [PDF]

				D. H. Dyer, S. Lovell, J. B. Thoden, H. M. Holden, I. Rayment, and Q. Lan The Structural Determination of an Insect Sterol Carrier Protein-2 with a Ligand-bound C16 Fatty Acid at 1.35-A Resolution J. Biol. Chem., October 3, 2003; 278(40): 39085 - 39091. [Abstract] [Full Text] [PDF]

				X. Lu, Y. Xiong, and J. Silver Asymmetric Requirement for Cholesterol in Receptor-Bearing but Not Envelope-Bearing Membranes for Fusion Mediated by Ecotropic Murine Leukemia Virus J. Virol., June 5, 2002; 76(13): 6701 - 6709. [Abstract] [Full Text] [PDF]

				R. Hernandez, H. Lee, C. Nelson, and D. T. Brown A Single Deletion in the Membrane-Proximal Region of the Sindbis Virus Glycoprotein E2 Endodomain Blocks Virus Assembly J. Virol., May 1, 2000; 74(9): 4220 - 4228. [Abstract] [Full Text]

				T. Reichstein, J. von Euw, J. A. Parsons, and M. Rothschild Heart Poisons in the Monarch Butterfly Science, August 30, 1968; 161(3844): 861 - 866. [PDF]

				T. Eisner and J. Meinwald Defensive Secretions of Arthropods Science, September 16, 1966; 153(3742): 1341 - 1350. [PDF]

				J. Meinwald, G. M. Happ, J. Labows, and T. Eisner Cyclopentanoid Terpene Biosynthesis in a Phasmid Insect and in Catmint Science, January 7, 1966; 151(3706): 79 - 80. [Abstract] [PDF]

				W. B. Heed and H. W. Kircher Unique Sterol in the Ecology and Nutrition of Drosophila pachea Science, August 13, 1965; 149(3685): 758 - 761. [Abstract] [PDF]