THE GENETIC ARCHITECTURE OF WING SIZE DIVERGENCE AT VARYING SPATIAL SCALES ALONG A BODY SIZE CLINE INDROSOPHILA MELANOGASTER

1. Mass selection for both high- and low-ratio of wing to thorax length has been carried out on a population of Drosophila melanogaster. The response to selection was immediate and sustained. When the experiment was stopped after ten generations, the wing area in the two selected lines differed by about 30%. The heritability estimate worked out at 0·56 ± 0·08.2. Thorax length remained comparatively unchanged during selection nor was there any change in wing shape. There was some evidence of assymetry of response since there was a relatively greater change in favour of smaller rather than larger size.3. The tibia length of all pairs of legs showed correlated changes so that the lines with larger or smaller wing sizes had also larger and smaller legs.4. The normal allometric relation between wing and thorax length, associated with variation in body-size, apparently also changed, so that for a given change in thorax length there was a greater or smaller proportional change in wing size in the high- or low-ratio lines.5. The changes in relative wing size are due to changes in cell number.6. It is suggested that the genetic changes due to selection act in the early pupal period when the imaginal discs are undergoing differentiation and proliferation to form imaginal hypoderm and appendages.7. Tests of genetic behaviour failed to show any departure from additivity in crosses which involved the unselected population and the high-ratio line. But highly significant departures existed in the cross to the low-ratio line. Relatively smaller wing size behaves as largely recessive. Stability of the normal wing/thorax ratio involves dominance and probably also epistasis. The genetic properties of the relative size of the appendage are apparently similar to those which characterize body-size as a whole.8. It is suggested that selection provides a valuable tool for studying the constancy or lability of the growth patterns which determine morphology.

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Genetic architecture supports mosaic brain evolution and independent brain–body size regulation

Nature Communications ◽

10.1038/ncomms2086 ◽

2012 ◽

Vol 3 (1) ◽

Cited By ~ 60

Author(s):

Reinmar Hager ◽

Lu Lu ◽

Glenn D. Rosen ◽

Robert W. Williams

Keyword(s):

Body Size ◽

Genetic Architecture ◽

Brain Evolution ◽

Size Regulation ◽

Mosaic Brain Evolution

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Integrating morphology and kinematics in the scaling of hummingbird hovering metabolic rate and efficiency

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2017.2011 ◽

2018 ◽

Vol 285 (1873) ◽

pp. 20172011 ◽

Cited By ~ 4

Author(s):

Derrick J. E. Groom ◽

M. Cecilia B. Toledo ◽

Donald R. Powers ◽

Bret W. Tobalske ◽

Kenneth C. Welch

Keyword(s):

Body Size ◽

Metabolic Rate ◽

Wing Size ◽

Wing Morphology ◽

Morphological Adaptation ◽

Wingbeat Frequency ◽

Cycle Frequency ◽

Scaling Relationship ◽

Metabolic Costs ◽

The Cost

Wing kinematics and morphology are influential upon the aerodynamics of flight. However, there is a lack of studies linking these variables to metabolic costs, particularly in the context of morphological adaptation to body size. Furthermore, the conversion efficiency from chemical energy into movement by the muscles (mechanochemical efficiency) scales with mass in terrestrial quadrupeds, but this scaling relationship has not been demonstrated within flying vertebrates. Positive scaling of efficiency with body size may reduce the metabolic costs of flight for relatively larger species. Here, we assembled a dataset of morphological, kinematic, and metabolic data on hovering hummingbirds to explore the influence of wing morphology, efficiency, and mass on hovering metabolic rate (HMR). We hypothesize that HMR would decline with increasing wing size, after accounting for mass. Furthermore, we hypothesize that efficiency will increase with mass, similarly to other forms of locomotion. We do not find a relationship between relative wing size and HMR, and instead find that the cost of each wingbeat increases hyperallometrically while wingbeat frequency declines with increasing mass. This suggests that increasing wing size is metabolically favourable over cycle frequency with increasing mass. Further benefits are offered to larger hummingbirds owing to the positive scaling of efficiency.

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THE CONTRASTING GENETIC ARCHITECTURE OF WING SIZE, VIABILITY, AND DEVELOPMENT TIME IN A RAINFOREST SPECIES AND ITS MORE WIDELY DISTRIBUTED RELATIVE

Evolution ◽

10.1554/05-266.1 ◽

2006 ◽

Vol 60 (1) ◽

pp. 106

Author(s):

Michele Schiffer ◽

A. Stuart Gilchrist ◽

Ary A. Hoffmann

Keyword(s):

Genetic Architecture ◽

Development Time ◽

Wing Size

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Platypus (Ornithorhynchus anatinus) body size, condition and population structure in Tasmanian river catchments: variability and potential mucormycosis impacts

Wildlife Research ◽

10.1071/wr10162 ◽

2011 ◽

Vol 38 (4) ◽

pp. 271 ◽

Cited By ~ 9

Author(s):

Nick Gust ◽

Josh Griffiths

Keyword(s):

Population Structure ◽

Body Size ◽

Spatial Scales ◽

Population Level ◽

Disease Status ◽

Volume Index ◽

Adult Males ◽

Ornithorhynchus Anatinus ◽

Size Condition ◽

River Catchments

Context Despite widespread interest in platypus (Ornithorhynchus anatinus) conservation, it is unclear how their fundamental morphometric and demographic characteristics differ over a range of scales. This hampers impact assessments and understanding of platypus ecology. Although the ulcerative fungal disease mucormycosis has infected platypuses in Tasmania for three decades, its population level impacts and conservation significance remain unknown. Aims This study examined morphometric and demographic patterns in Tasmanian platypuses to provide a basis for investigating impacts of mucormycosis or other anthropogenic disturbances. It also sought to identify important spatial scales of natural variability and the magnitude of seasonal variation in platypus body size, condition and population structure. The hypothesis of higher mucormycosis prevalence and mortality in adult males was also investigated. Methods Extensive live-trapping surveys were conducted from January 2008 to July 2009 in 75 streams and 18 river catchments across Tasmania including King Island. The sex, age, body size, tail volume index, health and moult condition of 195 individuals were assessed, and population age and sex structures characterised. Sampling focussed on assessing variability within and between river catchments and compared populations in river catchments with contrasting disease status. Key results Differences in platypus morphometrics within and between catchments and seasonal moulting patterns were detected. Adult males had higher fat stores than adult females, especially during winter. This study also provided the first evidence of population level consequences of disease in platypuses. The demographic group most commonly affected by mucormycosis was confirmed to be adult males. Differences in male age structure among catchments of varying disease status were consistent with the hypothesis of higher adult male mortality rates and turnover in currently affected catchments. Conclusions More than 25 years after mucormycosis was first detected in Tasmanian platypuses, the disease continues to play a low-level, ongoing role in affected populations. Implications The present study provides the first systematic multi-scale spatial investigation of platypus mucormycosis, which contributes to unravelling the epidemiology of the disease and detecting its impacts. By identifying the magnitude and important scales of morphometric and demographic differences in Tasmanian platypuses the study also assists researchers choose comparable demographic groups and spatial scales for meaningful comparisons in future impact studies.

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Genetic architecture of a wing size measure in Drosophila hibisci from two populations in eastern Australia

Heredity ◽

10.1046/j.1365-2540.2000.00763.x ◽

2000 ◽

Vol 85 (6) ◽

pp. 521-529 ◽

Cited By ~ 7

Author(s):

Larry L Wolf ◽

W T Starmer ◽

Michal Polak ◽

J S F Barker

Keyword(s):

Genetic Architecture ◽

Wing Size ◽

Eastern Australia ◽

Size Measure ◽

Two Populations

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Climate, species richness, and body size drive geographical variation in resource specialization of herbivorous butterflies

10.1101/2020.01.09.899922 ◽

2020 ◽

Author(s):

Ryosuke Nakadai ◽

Tommi Nyman ◽

Koya Hashimoto ◽

Takaya Iwasaki ◽

Anu Valtonen

Keyword(s):

Body Size ◽

Structural Equation ◽

Spatial Scales ◽

Equation Modeling ◽

Butterfly Species ◽

Host Use ◽

Resource Specialization ◽

The Japanese Archipelago ◽

Bayesian Structural Equation Modeling ◽

General Prediction

AbstractRevealing drivers of variation in resource specialization is a long-standing goal in ecological and evolutionary research. As a general prediction, the degree of resource specialization increases towards lower latitudes. Although herbivorous insects are one of the best-studied consumer groups, factors determining the degree of specialization on large spatial scales are poorly understood. Herein, we focused on the fundamental host breadth of 246 herbivorous butterfly species distributed across the Japanese archipelago. Using Bayesian Structural Equation Modeling based on information of pooled geographical occurrence and host use, we show that local butterfly communities tend to become more specialized towards higher latitudes, a pattern that is opposite to predictions from classical hypotheses. We also found that the pattern is mainly driven by factors related to climate, butterfly diversity, and body size in each community. Our results re-emphasize the importance of current climate as a regulating factor for butterfly host breadth and morphology.

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Eco-evolutionary dynamics in urbanized landscapes: evolution, species sorting and the change in zooplankton body size along urbanization gradients

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2016.0030 ◽

2017 ◽

Vol 372 (1712) ◽

pp. 20160030 ◽

Cited By ~ 33

Author(s):

Kristien I. Brans ◽

Lynn Govaert ◽

Jessie M. T. Engelen ◽

Andros T. Gianuca ◽

Caroline Souffreau ◽

...

Keyword(s):

Body Size ◽

Evolutionary Dynamics ◽

Spatial Scales ◽

Zooplankton Community ◽

Urban Heat Islands ◽

Integrated Analysis ◽

Large Species ◽

Species Sorting ◽

Cladoceran Species ◽

Urbanization Gradients

Urbanization causes both changes in community composition and evolutionary responses, but most studies focus on these responses in isolation. We performed an integrated analysis assessing the relative contribution of intra- and interspecific trait turnover to the observed change in zooplankton community body size in 83 cladoceran communities along urbanization gradients quantified at seven spatial scales (50–3200 m radii). We also performed a quantitative genetic analysis on 12 Daphnia magna populations along the same urbanization gradient. Body size in zooplankton communities generally declined with increasing urbanization, but the opposite was observed for communities dominated by large species. The contribution of intraspecific trait variation to community body size turnover with urbanization strongly varied with the spatial scale considered, and was highest for communities dominated by large cladoceran species and at intermediate spatial scales. Genotypic size at maturity was smaller for urban than for rural D. magna populations and for animals cultured at 24°C compared with 20°C. While local genetic adaptation likely contributed to the persistence of D. magna in the urban heat islands, buffering for the phenotypic shift to larger body sizes with increasing urbanization, community body size turnover was mainly driven by non-genetic intraspecific trait change. This article is part of the themed issue ‘Human influences on evolution, and the ecological and societal consequences’.

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