Larval regulation of adult longevity in a genetically-selected long-lived strain of Drosophila (original) (raw)
References
Ashburner, M. 1979. The induction of gene activity in Drosophila by heat shock. Cell, 17, 241–254. ArticleCAS Google Scholar
Ashburner, R. 1987a. Successful selection for increased longevity in Drosophila: analysis of the survival data and presentation of a hypothesis on the genetic regulation of longevity. Exp Gerontol, 22, 199–220. Article Google Scholar
Arking, R. 1987b. Letter to the editor. Exp Gerontol, 22, 223–226. Article Google Scholar
Arking, R, Buck, S, Berrios, A, Dwyer, S, and Baker, G T, III. 1991. Elevated paraquat resistance can be used as a bioassay for longevity in a genetically based long-lived strain of Drosophila. Devel Genetics, 12, 362–370. ArticleCAS Google Scholar
Arking, R, Buck, S, Wells, R A, and Pretzlaff, R. 1988. Metabolic rates in genetically based long lived strains of Drosophila. Exp Gerontol, 23, 59–76. ArticleCAS Google Scholar
Arking, R, and Wells, R A. 1990. Genetic alteration of normal aging processes is responsible for extended longevity in Drosophila. Devel Genetics, 11, 141–148. ArticleCAS Google Scholar
Austad, S N. 1989. Life extension by dietary restriction in the bowl and doily spider, Frontilnela pyramitela. Exp Gerontol, 24, 83–92. ArticleCAS Google Scholar
Barker, K. 1961. An analysis of factors which determine success in competition for food among larvae of Drosophila melanogaster. Arch Neerland Zool, 14, 200–281. Google Scholar
Becker, J, Mezger, V, Courgeon, A-M, and Best-Belpomme, M. 1990. Hydrogen peroxide activities immediate binding of a Drosophila factor to DNA heat-shock regulatory element in vivo and in vitro. Eur J Biochem, 189, 553–558. ArticleCAS Google Scholar
Boetella, L M, Moya, A, Gonzalez, M C, and Mensua, J L. 1985. Larval stop, delayed development and survival in overcrowded cultures of Drosophila melanogaster: effect of urea and uric acid. J Insect Physiol, 31, 179–185. Article Google Scholar
Bryant, P J. 1987. Experimental and genetic analysis of growth and cell proliferation in Drosophila imaginal discs. In: Loomis, W. F. (ed.) Genetic Regulation of Development Alan R. Liss, New York, pp. 339–372. Google Scholar
Buck, S, Wells, R A, Dudas, S P, Baker, G T, III, and Arking, R. 1993. Chromosomal localization and regulation of the longevity determinant genes in a selected strain of Drosophila melanogaster. Heredity71, 11–22. Google Scholar
Church, R, and Robertson, F. 1969. A biochemical study of the growth of Drosophila. J Exp Zool, 162, 337–352. Article Google Scholar
Clare, M, and Luckinbill, L. 1985. The effects of gene-environment interaction on the expression of longevity. Heredity, 55, 19–29. Article Google Scholar
Crowl, T A, and Covich, A P. 1990. Predator-induced life-history shifts in a freshwater snail. Science, 247, 949–951. ArticleCAS Google Scholar
Curtsinger, J. 1990. “Genetic and environmental components in variance of longevity in Drosophila males”. Talk presented at 43rd annual meeting of Gerontology Society of America, 18 November.
David, J, Van Herrewege, J, and Fouiller, R. 1971. Quantitative underfeeding of Drosophila: effects on adult longevity and fecundity. Exp Gerontol, 6, 249. ArticleCAS Google Scholar
Dudas, S P, and Arking, R. 1990. Genetic expression in long-lived strains of Drosophila. Gerontologist, 30, 115A. (abstract). Google Scholar
Dunnett, C W. 1955. A multiple comparison procedure for comparing several treatments with a control. Am Stat Assoc J, 50, 1096–1121. Article Google Scholar
Dunnett, C W. 1964. New tables for multiple comparisons with a control. Biometrics, 20, 482–491. Article Google Scholar
Economos, A C, and Lints, F A. 1984a. Growth rate and life span in Drosophila. i Methods and mechanisms of growth rate. Mech Ageing Devel, 27, 1–13. ArticleCAS Google Scholar
Economos, A C, and Lints, F A. 1984b. Growth rate and life span in Drosophila. iii Effect of body size and developmental temperature on the biphasic relationship between growth rate and life span. Mech Ageing Devel, 27, 153–160. ArticleCAS Google Scholar
Economos, A C, and Lints, F A. 1985. Growth rate and life span in Drosophila. iv Role of cell z = size and cell number in the biphasic relationship between life span and growth rate. Mech Ageing Devel, 32, 193–204. ArticleCAS Google Scholar
Hillesheim, E, and Stearns, S C. 1992. Correlated responses in life-history traits to artificial selection for body weights in Drosophila melanogaster. Evolution, 46, 745–752. Article Google Scholar
Hoffman, A A, and Parsons, P A. 1993. Selection for adult dessication resistance in Drosophila melanogaster Fitness components, larvae resistance and stress correlations. Biol J Linn Soc, in press.
Ingram, D, Baker, G T, III, and N, Shock. 1991. Potential for Nutritional Modulation of Aging Processes Food and Nutrition Press, Westport, CT. Google Scholar
Lints, F A, and Lints, C V. 1971. Influence of preimaginal environment on fecundity and ageing in Drosophila melanogaster hybrids, ii. Developmental speed and life span. Exp Gerontol, 6, 427–445. ArticleCAS Google Scholar
Miller, R S, and Thomas, J L. 1958. The effects of larval crowding and body size on the longevity of adult Drosophila melanogaster. Ecology, 39, 118–125. Article Google Scholar
Mode, C J, Ashleigh, R D, Zawodniak, A, and Baker, G T, III. 1984. On statistical tests of significance in studies of survivorship in laboratory animals. J Gerontology, 39, 36–42. ArticleCAS Google Scholar
Nothiger, R. 1972. The larval development of imaginal discs. In Ursprung, H. and Nothiger, R. (eds) The Biology of Imaginal Discs: Results and Problems in Cell Differentiation, vol. 5. Springer-Verlag, New York, Chap. 1. Google Scholar
Pritsos, C, Ahmad, S, Elliott, A, and Pardini, R. 1990. Antioxidant enzyme level response to prooxidant allelochemicals in larvae of the Southern armyworm moth, Spopdeptera eridania. Free Rad Res Commun, 9, 127–133. ArticleCAS Google Scholar
Richardson, A, Roberts, M S, and Rutherford, M S. 1985. Aging and gene expression. Rev Biol Res Aging, 2, 395–419. CAS Google Scholar
Rose, M R, Vu, L N, Park, S U, and Graves, J L, Jr. 1992. Selection on stress resistance increases longevity in Drosophila melanogaster. Exp Gerontol, 27, 241–250. ArticleCAS Google Scholar
Sacher, G A. 1977. Life table modification and life prolongation. In Finch, C. E. and Hayflick, L. (eds) Handbook of the Biology of Aging Van Nostrand Reinhold, New York. Google Scholar
Storz, G, Tartaglia, S, Farr, S, and Ames, B. 1990. Bacterial defenses against oxidative stress. Trends Genetics, 6, 363–368. ArticleCAS Google Scholar
Suzuki, D T. 1970. Temperature-sensitive mutations in Drosophila melanogaster. Science, 170, 695–706. ArticleCAS Google Scholar
Wells, R A, Buck, S, Ali, R, Marzouq, O, and Arking, R. 1987. Localization of the longevity genes in D. melanogaster. Gerontologist, 27, 149A (abstract). Google Scholar
Yonemura, I, Motoyama, T, Hasekura, H, and Boettcher, B. 1991. Relationship between genotypes of longevity genes and developmental speed in Drosophila melanogaster. Heredity, 66, 143–149. Article Google Scholar
Zar, J H. 1984. Biostatistical Analysis, 2nd edn. Prentice-Hall, Englewood Cliffs, New Jersey. Google Scholar
Zwaan, B, Bijlsma, R, and Hoekstra, R. 1991a. On the developmental theory of ageing. i Starvation resistance and longevity in Drosophila melanogaster in relation to pre-adult breeding conditions. Heredity, 66, 29–39. Article Google Scholar
Zwaan, B, Bijlsma, R, and Hoekstra, R. 1992. On the developmental theory of ageing. ii the effect of developmental temperature on longevity in relation to adult body size in D. melanogster. Heredity, 68, 123–130. ArticleCAS Google Scholar