Demography of Genotypes: Failure of the Limited Life-Span Paradigm in
            <i>Drosophila melanogaster</i>

Curtsinger, James W.; Fukui, Hidenori H.; Townsend, D. P.; Vaupel, James W.

doi:10.1126/science.1411541

Cited by 397 publications

(238 citation statements)

References 11 publications

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“…Brooks et al (1994) demonstrated that mortality rate in an isogenic population of the nematode Caenorhabditis elegans showed a less-distinct plateau than in a genetically heterogeneous population, but Vaupel et al (1994) were quick to point out that the isogenic line was grown at a higher temperature and in higher food concentration than the heterogeneous line, greatly complicating the interpretation of the mortality patterns. In addition, isogenic versus heterogenous populations of Drosophila melanogaster do not consistently show these same patterns (Curtsinger et al, 1992;Fukui et al, 1996). Furthermore, although the relevance of individual environmental heterogeneity to late-life mortality rates is extremely difficult to test effectively (Curtsinger et al, 1992;Fukui et al, 1993;Vaupel and Carey, 1993), an intricate experiment by Khazaeli et al (1998) found no evidence to support the hypothesis that environmental heterogeneity among individual flies is a primary factor in determining late-life mortality rates.…”

Section: Introductionmentioning

confidence: 80%

“…In addition, isogenic versus heterogenous populations of Drosophila melanogaster do not consistently show these same patterns (Curtsinger et al, 1992;Fukui et al, 1996). Furthermore, although the relevance of individual environmental heterogeneity to late-life mortality rates is extremely difficult to test effectively (Curtsinger et al, 1992;Fukui et al, 1993;Vaupel and Carey, 1993), an intricate experiment by Khazaeli et al (1998) found no evidence to support the hypothesis that environmental heterogeneity among individual flies is a primary factor in determining late-life mortality rates. In another experiment, Khazaeli et al (1995b) seemingly demonstrated environmental heterogeneity for stress resistance by subjecting genetically homogenous populations to a 24-hr heat stress and comparing their poststress mortality patterns to control lines; however, this paper was later retracted after new research revealed that the experimental method was flawed Khazaeli et al, 1997;Tatar et al, 1997).…”

Section: Introductionmentioning

confidence: 80%

“…Because late-life plateaus in cohort mortality rates indicate that there is no "wall of death" past which no organism can survive, some individuals can theoretically live indefinitely. Understandably, researchers have been intrigued by this phenomenon since its first experimental demonstration (Carey et al, 1992;Curtsinger et al, 1992). Indeed, late-life mortality plateaus seem to challenge current definitions and theories of aging (see Finch, 1990;Rose, 1991).…”

Section: Introductionmentioning

confidence: 99%

“…The required heterogeneity may be genetic or environmental (cf. Curtsinger et al, 1992;Fukui et al, 1993).…”

Section: Introductionmentioning

confidence: 99%

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Testing the heterogeneity theory of late-life mortality plateaus by using cohorts of Drosophila melanogaster

Drapeau

Gass

Simison

et al. 2000

Experimental Gerontology

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Variation among individuals in robustness has been posed as a general explanation for the lack of increase in late-life mortality rates. Here, we test corollaries of this heterogeneity theory. One is that populations that have undergone strong laboratory selection for differentiated stress resistance should show significant differences in their late-life mortality schedules. To test this corollary, we employed 40 410 flies from three groups of Drosophila melanogaster populations that differ substantially in their resistance to starvation. No significant differences between these groups were found for late-life mortality. Another corollary of the heterogeneity theory is that there should be late-life plateaus in stress resistance that coincide with the plateau stage of the mortality curve. In 20 994 flies from six replicate outbred laboratory populations, we measured mortality rates every other day and starvation and desiccation resistance every 7 days. Both male and female starvation and desiccation resistance clearly decreased with time overall. There was no late-life plateau in male desiccation resistance. A late-life plateau in male starvation resistance may exist, however. Together, these two experiments generally constitute evidence against heterogeneity as a major contributor to the phenomenon of late-life mortality plateaus.

show abstract

Section: Introductionmentioning

confidence: 80%

Section: Introductionmentioning

confidence: 80%

Section: Introductionmentioning

confidence: 99%

“…The required heterogeneity may be genetic or environmental (cf. Curtsinger et al, 1992;Fukui et al, 1993).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Testing the heterogeneity theory of late-life mortality plateaus by using cohorts of Drosophila melanogaster

Drapeau

Gass

Simison

et al. 2000

Experimental Gerontology

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show abstract

“…In some other organisms, such as Pacific salmon and the marsupial Antechinus , there is a spectacular period of aging which proceeds so rapidly that no individuals survive after the aging phase. But in many animals, we now know, there is a period after aging during which mortality and fecundity plateau (Carey et al ., 1992;Curtsinger et al ., 1992;Vaupel et al ., 1998;Rauser et al ., 2003). That is, aging stops, and a new phase of life begins Rauser et al ., 2006).…”

Section: Introductionmentioning

confidence: 99%

Rules for the use of model organisms in antiaging pharmacology

Jafari

Rose

2006

Aging Cell

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SummaryThe use of animal models for initially screening antiaging drugs is a promising approach for drug discovery. However, there a number of potential artifacts, confounds and errors that can arise in such research programs. The following rules are intended to minimize such problems: (1) since aging occupies an increasing proportion of human adulthood, data that conflate aging and late life should not be extrapolated to human aging; (2) the response to candidate medications should show a normal dose-response pattern, although not necessarily a linear response; (3) medicated animal models should not be hypometabolic; (4) medicated animal models should not show pronounced reductions in fertility; (5) medicated animal models should not exhibit general nervous system depression; (6) the effect of the medication should not be highly sensitive to the culture environment; (7) the effect of the medication should not be highly dependent on the genetic ancestry of the stock employed, leaving aside inbreeding, which should be avoided because humans are not generally inbred. While these rules do not guarantee successful extrapolation of successful drug results from the animal model to humans in a clinical setting, the failure to adhere to these rules should raise doubts about such extrapolation.

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Evolution of human lifespan: Past, future, and present

Rose

Mueller

1998

Am. J. Hum. Biol.

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Demography of Genotypes: Failure of the Limited Life-Span Paradigm in Drosophila melanogaster

Cited by 397 publications

References 11 publications

Testing the heterogeneity theory of late-life mortality plateaus by using cohorts of Drosophila melanogaster

Testing the heterogeneity theory of late-life mortality plateaus by using cohorts of Drosophila melanogaster

Rules for the use of model organisms in antiaging pharmacology

Evolution of human lifespan: Past, future, and present

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