The Australian Drosophila Ecology and Evolution Resource (ADEER) collates Australian datasets on drosophilid flies, which are aimed at investigating questions around climate adaptation, species distribution limits and population genetics. Australian drosophilid species are diverse in climatic tolerance, geographic distribution and behaviour. Many species are restricted to the tropics, a few are temperate specialists, and some have broad distributions across climatic regions. Whereas some species show adaptability to climate changes through genetic and plastic changes, other species have limited adaptive capacity. This knowledge has been used to identify traits and genetic polymorphisms involved in climate change adaptation and build predictive models of responses to climate change. ADEER brings together 103 datasets from 39 studies published between 1982–2013 in a single online resource. All datasets can be downloaded freely in full, along with maps and other visualisations. These historical datasets are preserved for future studies, which will be especially useful for assessing climate-related changes over time.
01 Azevedo et al. 1996, Egg size and ovariole number
This data file contains means and 95% confidence limits of egg size (mm3) and mean ovariole number of 20 Drosophila melanogaster locations collected at 13 latitudes in 1993 (extracted from Fig 1&2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Azevedo, Ricardo B. R., French, Vernon & Partridge, Linda (1996). Thermal evolution of egg size in Drosophila melanogaster. Evolution 50: 2338-2345
1_Azevedo_et_al._1996_Egg_size_&_ovariole_number.csv
02 Azevedo et al. 1998, Wing traits
This data file contains means and 95% confidence limits of wing:thorax size ratio and mean wing-aspect ratio for 18 Drosophila melanogaster locations collected at 12 latitudes in 1993. The wing traits were measured in females and males of field collected flies and in their descendants reared under standard laboratory conditions (extracted from Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication: Azevedo, Ricardo B. R., James, Avis C., McCabe, Jennie & Partridge, Linda (1998). Latitudinal variation of wing: thorax size ratio and wing-aspect ratio in Drosophila melanogaster. Evolution 52: 1353-1362
2_Azevedo_et_al_1998_Wing_traits.csv
03 Gockel et al. 2001, Microsatellite markers
This data set contains raw genotypes of 19 microsatellite markers for 29 Drosophila melanogaster locations collected at 11 latitudes in 2000. When using this data, please cite the original publication:
Gockel, Julia, Kennington, W. Jason, Hoffmann, Ary, Goldstein, David B., and Partridge, Linda (2001). Nonclinality of Molecular Variation Implicates Selection in Maintaining a Morphological Cline of Drosophila melanogaster. Genetics 158: 319-323
3_Gockel_et_al._2001_Microsatellite_markers.csv
04 Gockel et al. 2001, Wing area
This data set contains means and standard deviations (SD) of wing area (mm2) for females and males of 19 Drosophila melanogaster locations collected at 11 latitudes in 2000 (extracted from Fig.1).When using this data, please cite the original publication:
Gockel, Julia, Kennington, W. Jason, Hoffmann, Ary, Goldstein, David B., and Partridge, Linda (2001). Nonclinality of Molecular Variation Implicates Selection in Maintaining a Morphological Cline of Drosophila melanogaster. Genetics 158: 319-323
4_Gockel_et_al_2001_Wing_area.csv
05 Griffiths et al. 2005, Development time
This data file contains means and standard errors of development times (days) of female and male Drosophila birchii originating from 11 populations collected in 2002 (Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Griffiths, J. A., Schiffer, M., and Hoffmann, A. A. (2005). Clinal variation and laboratory adaptation in the rainforest species Drosophila birchii for stress resistance, wing size, wing shape and development time. Journal of Evolutionary Biology 18: 213-222
5_Griffiths_et_al_2005_Development_time.csv
08 Hoffmann & Shirriffs 2002, Wing traits
This data file contains x and y coordinates of nine landmarks for wings and different traits related to wing shape for 19 Drosophila serrata populations collected in 2001. Measurements were taken for up to 10 isofemale lines per population. Wing_aspect was defined as wing length (the linear distance between landmarks 3 and 6) divided by the square root of wing area (here taken to be centroid size). Angle (outer-wing aspect) was defined as the angle between the vectors from landmarks 2 and 8 and the vector between landmarks 4 and 8. Wing proportion (outer_wing aspect) was defined as the linear distance between landmarks 2 and 4 divided by wing length (Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, Ary A. and Shirriffs, Jennifer (2002). Geographic variation for wing shape in Drosophila serrata. Evolution 56: 1068-1073
8_Hoffmann_&_Shirriffs_2002_Wing_traits.csv
09 Hoffmann et al. 2001, Desiccation resistance
This data file contains desiccation resistance (hours to death) of female and male Drosophila melanogaster of two types of lines (isofemale lines and F1s of a cross between two isofemale lines from the same population) and originating from 18 populations collected in 2000 (Fig. 4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Hallas, R., Sinclair, C., and Mitrovski, P. (2001). Levels of variation in stress resistance in Drosophila among strains, local populations, and geographic regions: Patterns for desiccation, starvation, cold resistance, and associated traits. Evolution 55: 1621-1630
9_Hoffmann_et_al_2001_Desiccation_resistance.csv
11_Hoffmann_et_al_2001_Line_means
This data file contains line mean starvation resistance (LT50 in hours), desiccation resistance (LT50 in hours), cold resistance (mortality out of 10), lipid content (proportion of body weight) and thorax length (mm) for four Queensland and three Tasmanian Drosophila melanogaster populations collected in 1997 (Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Hallas, R., Sinclair, C., and Mitrovski, P. (2001). Levels of variation in stress resistance in Drosophila among strains, local populations, and geographic regions: Patterns for desiccation, starvation, cold resistance, and associated traits. Evolution 55: 1621-1630
14_Hoffmann_et_al_2002_Heat_knockdown_time
This data contains raw heat knockdown time (minutes) for female Drosophila melanogaster from 176 isofemale lines and originating from 24 populations collected in 1999-2000 (Fig. 1a). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, Ary A., Anderson, Alisha and Hallas, Rebecca (2002). Opposing clines for high and low temperature resistance in Drosophila melanogaster. Ecology Letters 5: 614-618
15_Hoffmann_et_al_2003_Overwinter_fecundity
This data set contains means, standard deviation (SD) and standard error (SE) of fecundity rate (daily per female egg output), midpoint of egg output (time to produce half the eggs in a cage over the time interval tested) and mortality (number of flies alive out of 34 at the end of the experiment) for seven D. melanogaster populations. Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Scott, M., Partridge, L. and Hallas, R. (2003). Overwintering in Drosophila melanogaster: outdoor field cage experiments on clinal and laboratory selected populations help to elucidate traits under selection. Journal of Evolutionary Biology 16: 614-623
16_Hoffmann_et_al_2012_Frost_locusA
This data file contains Frost 6P and 10P allele frequencies (%) of 17 Drosophila melanogaster populations collected in 2005 and genotyped by acrylamide gel electrophoresis (Fig. 3A). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Blacket, M. J., McKechnie, S. W., Rako, L., Schiffer, M., Rane, R. V., Good, R. T., Robin, C., and Lee, S. F. (2012). A proline repeat polymorphism of the Frost gene of Drosophila melanogaster showing clinal variation but not associated with cold resistance. Insect Molecular Biology 21: 437-445
17_Hoffmann_et_al_2012_Frost_locusB
This data file contains Frost 6P allele frequencies (%) of 20 Drosophila melanogaster populations
collected independently in 2005-2006 and genotyped by Roche/454-amplicon sequencing (Fig. 3B). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Blacket, M. J., McKechnie, S. W., Rako, L., Schiffer, M., Rane, R. V., Good, R. T., Robin, C., and Lee, S. F. (2012). A proline repeat polymorphism of the Frost gene of Drosophila melanogaster showing clinal variation but not associated with cold resistance. Insect Molecular Biology 21: 437-445
18_James_&_Partridge_1995_Development_time
This data file contains means and 95% confidence limits of pupal period (days) and egg to eclosion development time (days) of females and males of two experiments and from 20 Drosophila melanogaster locations collected at 10 latitudes in 1993 (extracted from Fig. 4 & 5). Note longitudes in data are approximate. When using this data, please cite the original publication:
James, Avis C. & Partridge, Linda (1995). Thermal evolution of rate of larval development in Drosophila melanogaster in laboratory and field populations. Journal of Evolutionary Biology 8: 315-330
19_James_&_Partridge_1995_Time_to_pupation
This data file contains means and 95% confidence limits of time to pupation (days) of two expeirments and for 20 Drosophila melanogaster locations collected at 10 latitudes in 1993 (extracted from Fig. 4 & 5). Note longitudes in data are approximate. When using this data, please cite the original publication:
James, Avis C. & Partridge, Linda (1995). Thermal evolution of rate of larval development in Drosophila melanogaster in laboratory and field populations. Journal of Evolutionary Biology 8: 315-330
20_James_et_al_1995_Thorax_length_&_wing_traits
This data file contains means and 95% confidence intervals of thorax length (mm), wing area (mm2), wing cell area (µm2) and wing cell number (thousand trichomes) for 20 Drosophila melanogaster locations collected at 13 latitudes in 1993. These traits were measured for females and males and for two experiments (extracted from Fig. 2&3). Note longitudes in data are approximate. When using this data, please cite the original publication:
James, Avis C., Azevedo, Ricardo B. R. & Partridge, Linda (1995). Cellular Basis and Developmental Timing in a Size Cline of Drosophila melanogaster. Genetics 140: 659-666
22_Kennington_et_al_2006_Molecular_markers_&_In(3R)Payne_inversion
This data file contains genotypes of 24 molecular markers located within and near the In(3R)Payne inversion for 32 Drosophila melanogaster locations collected at 16 latitudes in 2000 (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Kennington, W.J., Partridge, L., and Hoffmann, A. A. (2006). Patterns of diversity and linkage disequilibrium within the cosmopolitan inversion In(3R)Payne in Drosophila melanogaster are indicative of coadaptation. Genetics 172: 1655-1663
27_Mitrovski_&_Hoffmann_2001_Overwinter_temperature_egg_laying_and_mortality_rates
This data file contains cage means for mortality rates (MR) and egg laying rates (ELR) per female and day for field cages held at temperate winter conditions for seven Drosophila melanogaster populations collected in 2000. In addition, average, minimum and maximum temperature (°C) records and time since the cages were established (days) are shown (Fig. 1a). Note longitudes in data are approximate. When using this data, please cite the original publication:
Mitrovski, Paul and Hoffmann, Ary A. (2001). Postponed reproduction as an adaptation to winter conditions in Drosophila melanogaster: evidence for clinal variation under semi-natural conditions. Proceedings of the Royal Society of Biological Sciences 268: 2163-2168
28_Mitrovski_&_Hoffmann_2001_Overwinter_raw_egg_counts
This data file contains egg counts at different time points in field cages held at temperate winter conditions until all adults have died more than five months later. Eggs were counted for seven Drosophila melanogaster populations collected in 2000. Note longitudes in data are approximate. When using this data, please cite the original publication:
Mitrovski, Paul and Hoffmann, Ary A. (2001). Postponed reproduction as an adaptation to winter conditions in Drosophila melanogaster: evidence for clinal variation under semi-natural conditions. Proceedings of the Royal Society of Biological Sciences 268: 2163-2168
29_Mitrovski_&_Hoffmann_2001_Overwinter_raw_mortality
This data file contains numbers of dead females and males scored at different time points in field cages held at temperate winter conditions until all adults have died more than five months later. Survival was monitored for seven Drosophila melanogaster populations collected in 2000. When using this data, please cite the original publication:
Mitrovski, Paul and Hoffmann, Ary A. (2001). Postponed reproduction as an adaptation to winter conditions in Drosophila melanogaster: evidence for clinal variation under semi-natural conditions. Proceedings of the Royal Society of Biological Sciences 268: 2163-2168
30_Oakeshott_et_al_1982_Adh_&_Gpdh_loci
This data file contains frequencies of the F and S allele for the Adh and Gpdh locus for 33 Drosophila melanogaster locations collected in 1978-1979 (extracted from Table 1). When using this data, please cite the original publication:
Oakeshott, J. G., Gibson, J. B., Anderson, P. R., Knibb, W. R. Anderson, D. G. & Chambers, G. K. (1982). Alcohol Dehydrogenase and Glycerol-3-Phosphate Dehydrogenase Clines in Drosophila melanogaster on Different Continents. Evolution 36: 86-96
31_Oakeshott_et_al_1983_G6pd_locus
This data file contains frequencies of the G6pdF allele for 47 Drosophila melanogaster locations collected in 1978-1979 (extracted from Fig. 1). When using this data, please cite the original publication:
Oakeshott, J. G., Chambers, G. K., Gibson, J. B., Eanes, W. F. & Willcocks, D. A. (1983). Geographic variation in G6pd and Pgd allele frequencies in Drosophila melanogaster. Heredity 50: 67-72
32_Oakeshott_et_al_1983_Pgd_locus
This data file contains frequencies of the Pgd FF allele for 48 Drosophila melanogaster locations collected in 1978-1979 (extracted from Fig. 2). When using this data, please cite the original publication:
Oakeshott, J. G., Chambers, G. K., Gibson, J. B., Eanes, W. F. & Willcocks, D. A. (1983). Geographic variation in G6pd and Pgd allele frequencies in Drosophila melanogaster. Heredity 50: 67-72
33_Rako_et_al_2009_Post_winter_male_fertility_2006
This data file contains post winter male fertility data of the 2006 experiment with three Drosophila melanogaster populations collected in 2005. Each male was crossed to 1-5 virgin females and the total number of offspring, number of offspring per female and maximum number of offspring per female was scored for each male (Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Rako, L., Poulsen, N. A., Shirriffs, J., and Hoffmann, A. A. (2009). Clinal variation in post-winter male fertility retention; an adaptive overwintering strategy in Drosophila melanogaster. Journal of Evolutionary Biology 22: 2438-2444
34_Rako_et_al_2009_Post_winter_male_fertility_2008
This data file contains post winter male fertility data of the 2008 experiment with 17 Drosophila melanogaster populations collected in 2008. Each male was crossed to 2-5 virgin females and the total number of offspring was scored for each male (Fig. 4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Rako, L., Poulsen, N. A., Shirriffs, J., and Hoffmann, A. A. (2009). Clinal variation in post-winter male fertility retention; an adaptive overwintering strategy in Drosophila melanogaster. Journal of Evolutionary Biology 22: 2438-2444
35_Rako_et_al_2009_Post_winter_male_size_2006
This data file contains wing centroid size (mm) of overwintering males from the 2006 experiment with three Drosophila melanogaster populations collected in 2005. The 48 overwintering males with the highest and lowest productivity were measured for size (Fig. 3). Note longitudes in data are approximate. When using this data, please cite the original publication:
Rako, L., Poulsen, N. A., Shirriffs, J., and Hoffmann, A. A. (2009). Clinal variation in post-winter male fertility retention; an adaptive overwintering strategy in Drosophila melanogaster. Journal of Evolutionary Biology 22: 2438-2444
36_Rako_et_al_2009_Male_size_2008
This data file contains thorax length (mm) and wing centroid size (mm) of males from 18 Drosophila melanogaster populations collected in 2008. Size was measured on males from the mass bred populations maintained in the laboratory. Note longitudes in data are approximate. When using this data, please cite the original publication:
Rako, L., Poulsen, N. A., Shirriffs, J., and Hoffmann, A. A. (2009). Clinal variation in post-winter male fertility retention; an adaptive overwintering strategy in Drosophila melanogaster. Journal of Evolutionary Biology 22: 2438-2444
40_Umina_et_al_2005_Adh_locus
This data set contains frequencies of the alcohol dehydrogenase (Adh)S allele for 46 Drosophila melanogaster locations collected during 1978-1982 and for 34 locations collected during 2002-2004 (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Umina, P. A., Weeks, A. R., Kearney, M. R., McKechnie, S. W., and Hoffmann, A. A. (2005). A Rapid Shift in a Classic Clinal Pattern in Drosophila Reflecting Climate Change. Science 308: 691-693
42_Van_Heerwaarden_&_Sgro_2011_D._melanogaster_thorax_length
This data file contains raw thorax length of female and male D. melanogaster from three replicate vials at three rearing temperatures and from 18 populations collected in 2008 (Fig. 1). When using this data, please cite the original publication:
van Heerwaarden, B. and Sgrò, C. M. (2011). The effect of developmental temperature on the genetic architecture underlying size and thermal clines in Drosophila melanogaster and D. simulans from the east coast of Australia. Evolution 65: 1048-1067
42_Van_Heerwaarden_&_Sgro_2011_Dmelanogaster_thorax_length.csv
43_Van_Heerwaarden_&_Sgro_2011_D._melanogaster_wing_centroid_size
This data file contains raw wing centroid size of female and male D. melanogaster from three replicate vials at three rearing temperatures and from 18 populations collected in 2008. When using this data, please cite the original publication:
van Heerwaarden, B. and Sgrò, C. M. (2011). The effect of developmental temperature on the genetic architecture underlying size and thermal clines in Drosophila melanogaster and D. simulans from the east coast of Australia. Evolution 65: 1048-1067
43_Van_Heerwaarden_&_Sgro_2011_Dmelanogaster_wing_centroid_size.csv
44_Van_Heerwaarden_&_Sgro_2011_D._melanogaster_wing_thorax_ratio
This data file contains wing-to-thorax ratio of 10 female and male D. melanogaster from three replicate vials at three rearing temperatures and from 18 populations collected in 2008 (Fig. 1). When using this data, please cite the original publication:
van Heerwaarden, B. and Sgrò, C. M. (2011). The effect of developmental temperature on the genetic architecture underlying size and thermal clines in Drosophila melanogaster and D. simulans from the east coast of Australia. Evolution 65: 1048-1067
44_Van_Heerwaarden_&_Sgro_2011_Dmelanogaster_wing_thorax_ratio.csv
45_Van_Heerwaarden_&_Sgro_2011_D. simulans_thorax_length
This data file contains raw thorax length of female and male D. simulans from three replicate vials at three rearing temperatures and from 16 populations collected in 2008 (Fig. 2). When using this data, please cite the original publication:
van Heerwaarden, B. and Sgrò, C. M. (2011). The effect of developmental temperature on the genetic architecture underlying size and thermal clines in Drosophila melanogaster and D. simulans from the east coast of Australia. Evolution 65: 1048-1067
45_Van_Heerwaarden_&_Sgro_2011_Dsimulans_thorax_length.csv
46 Van Heerwaarden & Sgrò 2011, D. simulans wing centroid size
This data file contains raw wing centroid size of female and male D. simulans from three replicate vials at three rearing temperatures and from 16 populations collected in 2008 (Fig. 2). When using this data, please cite the original publication:
van Heerwaarden, B. and Sgrò, C. M. (2011). The effect of developmental temperature on the genetic architecture underlying size and thermal clines in Drosophila melanogaster and D. simulans from the east coast of Australia. Evolution 65: 1048-1067
46_Van_Heerwaarden_&_Sgro_2011_Dsimulans_wing_centroid_size.csv
47_Van_Heerwaarden_&_Sgro_2011_D. simulans_wing_thorax_ratio
This data file contains wing-to-thorax ratio of female and male D. simulans from three replicate vials at three rearing temperatures and from 16 populations collected in 2008 (Fig. 2). When using this data, please cite the original publication:
van Heerwaarden, B. and Sgrò, C. M. (2011). The effect of developmental temperature on the genetic architecture underlying size and thermal clines in Drosophila melanogaster and D. simulans from the east coast of Australia. Evolution 65: 1048-1067
47_Van_Heerwaarden_&_Sgro_2011_Dsimulans_wing_thorax_ratio.csv
48_Weeks_et_al_2005_Clock_locus
This data set contains frequencies of the two most common alleles (repeats 31 and 29) of the Gln clock gene for 18 Drosophila melanogaster populations collected in 2004 (Fig. 4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Weeks, A. R., McKechnie, S. W. and Hoffmann, A. A. (2005). In search of clinal variation in the period and clock timing genes in Australian Drosophila melanogaster populations. Journal of Evolutionary Biology 19: 309-656
49_Weeks_et_al_2005_Period_locus
This data set contains frequencies of the (Thr-Gly)17 and (Thr.Gly)20 period allele (Frequency17 and Frequency20) for 18 Drosophila melanogaster populations collected in 2004 and for 16 populations collected 2002 (Fig. 1). When using this data, please cite the original publication:
Weeks, A. R., McKechnie, S. W. and Hoffmann, A. A. (2005). In search of clinal variation in the period and clock timing genes in Australian Drosophila melanogaster populations. Journal of Evolutionary Biology 19: 309-656
50_Weeks_et_al_2005_ThrGly_locus
This data set contains mean Thr-Gly repeat length for 18 Drosophila melanogaster populations collected in 2004 and for 20 populations collected 2002 (Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Weeks, A. R., McKechnie, S. W. and Hoffmann, A. A. (2005). In search of clinal variation in the period and clock timing genes in Australian Drosophila melanogaster populations. Journal of Evolutionary Biology 19: 309-656
53_Collinge_et_al_2006_Ovariole_number
This data file contains ovariole numbers of both ovaries of four mated and four non-mated D. melanogaster females originating from a high and low altitude population at five latitudes (ten populations) collected in 2002 (Fig. 3). When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
54_Collinge_et_al_2006_Development_time
This data file contains egg to adult development times (days) for female and male D. melanogaster originating from a high and low altitude population at five latitudes collected in 2002. Development times were scored for groups of 10 eggs and emerging flies were collected, counted and sexed every 24h (ten populations) (Fig. 3). When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
55_Collinge_et_al_2006_Wing_area
This data file contains wing are (mm2) for female and male D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002 (Fig. 3). When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
56_Collinge_et_al_2006_Egg_viability
This data file contains egg viability for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002. When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
58_Collinge_et_al_2006_Hsp70_locus
This data file contains number of genotypes (56H8/56H8, 56H8/122, 122/122 and others) and allele frequencies for hsp70 for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002. The number of alleles scored (N) is shown for each population. When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
59_Collinge_et_al_2006_DMTRXIII_locus
This data file contains allele frequencies (25 alleles) for DMTRXIII for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002. DMTRXIII_MCA was the most common allele. The number of alleles scored (N) is shown for each population. When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
60_Collinge_et_al_2006_Hsr-omega_locus
This data file contains number of genotypes (LL, LS and SS) and allele frequencies for hsr-omegaL/S for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002. The number of alleles scored (N) is shown for each population. When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
61_Collinge_et_al_2006_DMU25686_locus
This data file contains allele frequencies (19 alleles) for DMU25686 for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002. DMU25686_MCA was the most common allele. The number of alleles scored (N) is shown for each population. When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
62_Collinge_et_al_2006_AC008193_locus
This data file contains allele frequencies (17 alleles) forAC008193 for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002. AC008193_MCA was the most common allele. The number of alleles scored (N) is shown for each population. When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
63_McKechnie_et_al_2010_Dca_MCA
This data set contains frequencies of the two most common alleles (MCA: 237 and 246 bp in length) in the Dca promoter region for 17 D. melanogaster populations collected in 2005 (Fig. 3). Frequencies are given for all data independent of the In(3R)P inversion and for inverted and standard arrangements only. Note longitudes in data are approximate. When using this data, please cite the original publication:
McKechnie, S. W., Blacket, M. J., Song, S. V., Rako, L., Carroll, X., Johnson, T. K., Jensen, L. T., Lee, S. F., Wee, C. W., and Hoffmann, A. A. (2010). A clinally varying promoter polymorphism associated with adaptive variation in wing size in Drosophila. Molecular Ecology 19: 775-784
64_McKechnie_et_al_2010_Dca_locus
This data set contains allelic variation (numbers of fragments between 237 and 250 bp in length) in the Dca promoter region for 17 Drosophila melanogaster populations collected in 2005. Note longitudes in data are approximate. When using this data, please cite the original publication:
McKechnie, S. W., Blacket, M. J., Song, S. V., Rako, L., Carroll, X., Johnson, T. K., Jensen, L. T., Lee, S. F., Wee, C. W., and Hoffmann, A. A. (2010). A clinally varying promoter polymorphism associated with adaptive variation in wing size in Drosophila. Molecular Ecology 19: 775-784
71_James_et_al_1997_Thorax_length_and_wing_traits
This data file contains means and 95% confidence limits for thorax length (mm), wing area (mm2), cell area (µm2) and cell number (x103) for females and males of 20 Drosophila melanogaster populations collected in 1993. Traits were measured for wild caught flies and laboratory reared flies after 7 and 9 months of captivity (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
James, Avis C., Azevedo, Ricardo B. R. and Partridge, Linda (1997). Genetic and Environmental Responses to Temperature of Drosophila melanogaster From a Latitudinal Cline. Genetics 146: 881-890
77_Arthur_et_al_2008_Cold_resistance
This data file contains cold recovery time (minutes) for females and males of 10 Drosophila simulans populations collected in 2004. For each population, 11-15 lines were tested for females and 9-15 lines for males (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Arthur, A. L., Weeks, A. R. and Sgrò, C. M. (2008). Investigating latitudinal clines for life history and stress resistance traits in Drosophila simulans from eastern Australia. Journal of Evolutionary Biology 21: 1470-1479
78_Arthur_et_al_2008_Desiccation_resistance
This data file contains desiccation resistance (time to death in hours) for individual females of 10 Drosophila simulans populations collected in 2004. For each population, 12-15 lines were tested (Fig. 3). Note longitudes in data are approximate.When using this data, please cite the original publication:
Arthur, A. L., Weeks, A. R. and Sgrò, C. M. (2008). Investigating latitudinal clines for life history and stress resistance traits in Drosophila simulans from eastern Australia. Journal of Evolutionary Biology 21: 1470-1479
80_Loeschcke_et_al_2000_Thorax_&_wing_traits_natural pops
This data file contains thorax length (mm), wing to thorax ratio (wing loading) and different wing measurements (l2, l3p, lpd, l3, w1, w2, w3) for wild-caught females and males of 5 Drosophila buzzatii and aldrichi populations that were collected in 1994 (Fig. 2). When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
81_Loeschcke_et_al_2000_Wing_traits_&_asymmetry_natural_pops
This data file contains wing area (mm2), wing shape, wing vein ratio and fluctuating asymmetry (FA) for wing area, wing shape and wing vein ratio for wild-caught females and males of 5 Drosophila buzzatii and aldrichi populations that were collected in 1994 (Fig. 2). When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
82_Loeschcke_et_al_2000_Wing_asymmetry_natural pops
This data file contains fluctuating asymmetry for different wing measurements (l2, l3p, lpd, l3, w1, w2, w3) for wild-caught females and males of 5 Drosophila buzzatii and aldrichi that were collected in 1994. When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
83_Loeschcke_et_al_2000_Thorax_&_wing_traits_lab pops
This data file contains thorax length (mm), wing to thorax ratio (wing loading) and different wing measurements (l2, l3p, lpd, l3, w1, w2, w3) for females and males of 5 Drosophila buzzatii and aldrichi lab populations that were collected in 1994. These populations were kept in the lab for five generations at 25°C and measurements were taken on progeny of the fifth generation which were reared at three temperature treatments (20, 25 and 30°C) (Fig. 3).When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
84_Loeschcke_et_al_2000_Wing_traits_&_asymmetry_lab pops
This data file contains wing area (mm2), wing shape, wing vein ratio and fluctuating asymmetry (FA) for wing area, wing shape and wing vein ratio for females and males of 5 Drosophila buzzatii and aldrichi lab populations that were collected in 1994. These populations were kept in the lab for five generations at 25°C and measurements were taken on progeny of the fifth generation which were reared at three temperature treatments (20, 25 and 30°C) (Fig. 3).When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
85_Loeschcke_et_al_2000_Wing_asymmetry_lab_pops
This data file contains fluctuating asymmetry for different wing measurements (l2, l3p, lpd, l3, w1, w2, w3) for females and males of 5 Drosophila buzzatii and aldrichi lab populations that were collected in 1994. These populations were kept in the lab for five generations at 25°C and measurements were taken on progeny of the fifth generation which were reared at three temperature treatments (20, 25 and 30°C). When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
86_Loeschcke_et_al_2000_Development_time_&_viabiliy_lab_pops
This data file contains mean development time (days) and viability (%) for 5 Drosophila buzzatii and aldrichi lab populations that were collected in 1994. These populations were kept in the lab for five generations at 25°C and measurements were taken on progeny of the fifth generation which were reared at three temperature treatments (20, 25 and 30°C).When using this data, please cite the original publication:
Loeschcke, Volker, Bundgaard, Jørgen, and Barker, J S F (2000). Variation in body size and life history traits in Drosophila aldrichi and D. buzzatii from a latitudinal cline in eastern Australia. Heredity 85: 423-433
88_Barker_2013_Allozyme_allele_frequencies_195_collections
This data file contains allele frequencies of seven allozyme loci (phosphoglucomutase (Pgm), aldehyde oxidase (Aldox), hexosaminadase (Hex), alcohol dehydrogenase-1 (Adh-1), esterase-1 (Est-1) and esterase-2 (Est-2) and leucine aminopeptidase (Lap)) for 67 D. buzzatii populations collected between 1972 and 1996. Some of these populations were sampled two or more times and in total 195 samples were collected. When using this data, please cite the original publication:
Barker, J. Stuart F. (2013). Genetic history of a colonizing population: Drosophila buzzatii (Diptera: Drosophilidae) in Australia. Biological Journal of the Linnean Society 109: 682-698
89_Barker_2013_GENEPOP_allozyme_file_195_collections
This data file contains the GENEPOP data file with genotypes of seven allozyme loci (phosphoglucomutase (Pgm), aldehyde oxidase (Aldox), hexosaminadase (Hex), alcohol dehydrogenase-1 (Adh-1), esterase-1 (Est-1) and esterase-2 (Est-2) and leucine aminopeptidase (Lap)) for 67 D. buzzatii populations collected between 1972 and 1996. Some of these populations were sampled two or more times and in total 195 samples were collected. When using this data, please cite the original publication:
Barker, J. Stuart F. (2013). Genetic history of a colonizing population: Drosophila buzzatii (Diptera: Drosophilidae) in Australia. Biological Journal of the Linnean Society 109: 682-698
94_Barker_2005_S_aclinata_microsatellite_markers
This data set contains raw genotypes of 17 microsatellite markers for 5 Scaptodrosophila aclinata populations collected in 1995. When using this data, please cite the original publication:
Barker, J S F (2005). Population structure and host-plant specialization in two Scaptodrosophila flower-breeding species. Heredity 94: 129-138
95_Barker_2005_S_hibisci_microsatellite_markers
This data set contains raw genotypes of 19 microsatellite markers for 9 S. hibisci populations collected in 1998. When using this data, please cite the original publication:
Barker, J S F (2005). Population structure and host-plant specialization in two Scaptodrosophila flower-breeding species. Heredity 94: 129-138
96_Magiafoglou_et_al_2002_microsatellite_markers
This data set contains raw genotypes of 8 microsatellite markers for Drosophila serrata populations collected before (14 populations) and after (10 populations) winter in 1999 (Table 4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Magiafoglou, A., Carew, M. E. and Hoffmann, A. A. (2002). Shifting clinal patterns and microsatellite variation in Drosophila serrata populations: a comparison of populations near the southernborder of the species range. Journal of Evolutionary Biology 15: 763-774
97_Hoffmann_et_al_2005_Desiccation_resistance
This data file contains desiccation resistance (LT50 in hours) for groups of 10 females of 8 Drosophila melanogaster populations collected in 2001 and kept under three seasonal conditions (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Shirriffs, J. and Scott, M. (2005). Relative importance of plastic vs genetic factors in adaptive differentiation: geographical variation for stress resistance in Drosophila melanogaster from eastern Australia. Functional Ecology 19: 222-227
98_Hoffmann_et_al_2005_Starvation_resistance
This data file contains starvation resistance (LT50 in hours) for groups of 10 females of 8 Drosophila melanogaster populations collected in 2001 and kept under three seasonal conditions (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Shirriffs, J. and Scott, M. (2005). Relative importance of plastic vs genetic factors in adaptive differentiation: geographical variation for stress resistance in Drosophila melanogaster from eastern Australia. Functional Ecology 19: 222-227
99_Hoffmann_et_al_2005_Heat_resistance
This data file contains heat knockdown time in minutes (corrected for different runs) for individual females of 8 Drosophila melanogaster populations collected in 2001 and kept under three seasonal conditions (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Shirriffs, J. and Scott, M. (2005). Relative importance of plastic vs genetic factors in adaptive differentiation: geographical variation for stress resistance in Drosophila melanogaster from eastern Australia. Functional Ecology 19: 222-227
201_Barker_2005_S_aclinata_collection_records
This data set contains collection records for Scaptodrosophila aclinata for 24 locations where flies were sampled directly from Hibiscus flowers in 1995 (Fig. 1). Hibiscus species, coordinates and altitude are reported for each location. When using this data, please cite the original publication:
Barker, J S F (2005). Population structure and host-plant specialization in two Scaptodrosophila flower-breeding species. Heredity 94: 129-138
202_Barker_2005_S_hibisci_collection_records
This data set contains collection records for Scaptodrosophila hibisci for 63 locations where flies were sampled directly from Hibiscus flowers in 1998 (Fig. 1). Hibiscus species, coordinates and altitude are reported for each location. When using this data, please cite the original publication:
Barker, J S F (2005). Population structure and host-plant specialization in two Scaptodrosophila flower-breeding species. Heredity 94: 129-138
203_Barker_et_al_2005_D_buzzatii_and_aldrichi_distribution
This data set contains collection records for the cactophilic Drosophila aldrichi and Drosophila buzzatii for 97 locations where Opuntia cacti occurred and which were sampled between 1971 and 2002 (Fig. 1). Opuntia species, coordinates and altitude are reported for each location and year and season (W=cool, winter/spring; S=warm, summer/autumn) are given for each collection. When using this data, please cite the original publication:
Barker, J S F (2005). Population structure and host-plant specialization in two Scaptodrosophila flower-breeding species. Heredity 94: 129-138
204_Schiffer_&_McEvey_2006_Montium_distribution
This data set contains distributions of Australian members of the montium subgroup (Drosophila bunnanda, D. serrata, D. birchii, D. kikkawai and D. sp. Cf. jambulina). Distribution data are available for 122 locations that were sampled between 1924 and 2005 and data are based on records in the literature, collections made by the authors and specimens in the Australian Museum (Figures 16-20). When using this data, please cite the original publication:
Schiffer, Michele, and McEvey, Shane F. (2006). Drosophila bunnanda - a new species from northern Australia with notes on other Australian members of the montium subgroup (Diptera: Drosophilidae). Zootaxa : 1-23
6 Griffiths et al. 2005 Stress resistance & wing size
This data file contains means and standard errors (SE) of wing centroid size (mm), starvation resistance (LT50 in hours), desiccation resistance (hours to death), heat knockdown time (minutes) and cold recovery time (seconds) of female Drosophila birchii originating from 11 populations collected in 2002 (Table 3, Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Griffiths, J. A., Schiffer, M., and Hoffmann, A. A. (2005). Clinal variation and laboratory adaptation in the rainforest species Drosophila birchii for stress resistance, wing size, wing shape and development time. Journal of Evolutionary Biology 18: 213-222
6_Griffiths_et_al_2005_Stress_resistance_&_wing_size.csv
7 Hallas et al. 2002 Stress resistance and size
This data file contains means and standard deviations (SD) of starvation resistance (time to death in hours), mass (mg) and wing length (mm) for females and males and desiccation resistance (time to death in hours) and cold recovery time (minutes) for females. All traits were measured for 20 Drosophila serrata populations collected in 2000 (Fig. 2-4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hallas, Rebecca, Schiffer, Michele, and Hoffmann, Ary A. (2002). Clinal variation in Drosophila serrata for stress resistance and body size. Genetical Research 79: 141-148
7_Hallas_et_al_2002_Stress_resistance_and_size.csv
10 Hoffmann et al. 2001 Starvation resistance
This data file contains starvation resistance (hours to death) of female and male Drosophila melanogaster of two types of lines (isofemale lines and F1s of a cross between two isofemale lines from the same population) and originating from 18 populations collected in 2000 (Fig. 4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, A. A., Hallas, R., Sinclair, C., and Mitrovski, P. (2001). Levels of variation in stress resistance in Drosophila among strains, local populations, and geographic regions: Patterns for desiccation, starvation, cold resistance, and associated traits. Evolution 55: 1621-1630
10_Hoffmann_et_al_2001_Starvation_resistance.csv
12_Hoffmann_et_al_2002_Cold_recovery_time
This data contains cold recovery time for female Drosophila melanogaster from 83 isofemale lines and originating from 18 populations collected in 1999-2000 (Fig. 1b). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, Ary A., Anderson, Alisha and Hallas, Rebecca (2002). Opposing clines for high and low temperature resistance in Drosophila melanogaster. Ecology Letters 5: 614-618
13 Hoffmann et al. 2002 Cold resistance survival
This data file contains survival (out of 20) after exposure to -2°C for 2 hours for female Drosophila melanogaster originating from eight populations collected in 1999-2000 (Fig. 1c). Note longitudes in data are approximate. When using this data, please cite the original publication:
Hoffmann, Ary A., Anderson, Alisha and Hallas, Rebecca (2002). Opposing clines for high and low temperature resistance in Drosophila melanogaster. Ecology Letters 5: 614-618
13_Hoffmann_et_al_2002_Cold_resistance_survival.csv
23_Knibb_et_al_1981_Inversion_frequencies
This data file contains frequencies of the In(2L)t, In(2R)NS, In(3L)Payne, In(3R)Payne and the In(3R)C inversion of 12 Drosophila melanogaster populations collected in 1978-1979 (extracted from Table 1). When using this data, please cite the original publication:
Knibb, W. R., Oakeshott, J. G. and Gibson, J. B. (1981). Chromosome inversion polymorphism in Drosophila melanogaster. I. Latitudinal clines and associations between inversions in Australasian populations. Genetics 98: 833-847
26 Mitrovski & Hoffmann 2001 Mean overwinter egg counts_and_longevity
This data file contains total egg counts, midpoint of egg laying (days), mean egg laying rate per female and day, mean longevity (days) and fitness estimates per field cage held at temperate winter conditions for seven Drosophila melanogaster populations collected in 2000 (Fig. 2). Note longitudes in data are approximate. When using this data, please cite the original publication:
Mitrovski, Paul and Hoffmann, Ary A. (2001). Postponed reproduction as an adaptation to winter conditions in Drosophila melanogaster: evidence for clinal variation under semi-natural conditions. Proceedings of the Royal Society of Biological Sciences 268: 2163-2168
26_Mitrovski_&_Hoffmann_2001_Mean_overwinter_egg_counts_and_longevity.csv
41_Umina_et_al_2005_In(3R)Payne_inversion
This data set contains frequencies of the inversion In(3R)Payne for 46 Drosophila melanogaster locations collected during 1978-1982 and for 34 locations collected during 2002-2004 (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Umina, P. A., Weeks, A. R., Kearney, M. R., McKechnie, S. W., and Hoffmann, A. A. (2005). A Rapid Shift in a Classic Clinal Pattern in Drosophila Reflecting Climate Change. Science 308: 691-693
51_Collinge_et_al_2006_Cold_recovery_time
This data file contains cold recovery time (minutes) for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002 (Fig. 2). When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
72 Magiafoglou et al. 2002 Development time
This data file contains mean development time (hours) for female and male Drosophila serrata populations collected before (14 populations) and after (10 populations) winter in 1999 (Fig. 1). Note longitudes in data are approximate. When using this data, please cite the original publication:
Magiafoglou, A., Carew, M. E. and Hoffmann, A. A. (2002). Shifting clinal patterns and microsatellite variation in Drosophila serrata populations: a comparison of populations near the southernborder of the species range. Journal of Evolutionary Biology 15: 763-774
72_Magiafoglou_et_al_2002_Development_time.csv
79 Arthur et al. 2008 Development time
This data file contains egg-to-adult development time (hours) for 10 Drosophila simulans populations collected in 2004. For each population, 12-15 lines were tested (Fig. 4). Note longitudes in data are approximate. When using this data, please cite the original publication:
Arthur, A. L., Weeks, A. R. and Sgrò, C. M. (2008). Investigating latitudinal clines for life history and stress resistance traits in Drosophila simulans from eastern Australia. Journal of Evolutionary Biology 21: 1470-1479
79_Arthur_et_al_2008_Development_time.csv
87 Barker 2013, Allozyme allele frequencies 67 populations
This data file contains allele frequencies of seven allozyme loci (phosphoglucomutase (Pgm), aldehyde oxidase (Aldox), hexosaminadase (Hex), alcohol dehydrogenase-1 (Adh-1), esterase-1 (Est-1) and esterase-2 (Est-2) and leucine aminopeptidase (Lap)) for 67 Drosophila buzzatii populations collected between 1972 and 1996. When using this data, please cite the original publication:
Barker, J. Stuart F. (2013). Genetic history of a colonizing population: Drosophila buzzatii (Diptera: Drosophilidae) in Australia. Biological Journal of the Linnean Society 109: 682-698
87_Barker_2013_Allozyme_allele_frequencies_67_populations.csv
91_Barker_et_al_2009_Microsatellite_markers
This data set contains raw genotypes of 15 microsatellite markers for 9 Drosophila buzzatiI populations collected in 2002. When using this data, please cite the original publication:
Barker, J S F, Frydenberg, J, González, J, Davies, H I, Ruiz, A, Sørensen, J G, and Loeschcke, V (2009). Bottlenecks, population differentiation and apparent selection at microsatellite loci in Australian Drosophila buzzatii. Heredity 102: 389-401
73_Magiafoglou_et_al_2002_Viability_and_cold_resistance
This data file contains mean and coefficient of variation (CV) of pupal to adult viability (%), mean egg to adult viability (%) and mean cold resistance (survival %) for Drosophila serrata populations collected before (14/12 populations) and after (10 populations) winter in 1999 (Fig. 2&3). Note longitudes in data are approximate. When using this data, please cite the original publication:
Magiafoglou, A., Carew, M. E. and Hoffmann, A. A. (2002). Shifting clinal patterns and microsatellite variation in Drosophila serrata populations: a comparison of populations near the southernborder of the species range. Journal of Evolutionary Biology 15: 763-774
52 Collinge et al. 2006, Heat knockdown time
This data file contains hardened and unhardened heat knockdown time (minutes) for D. melanogaster originating from a high and low altitude population at five latitudes (ten populations) collected in 2002 (Fig. 2). When using this data, please cite the original publication:
Collinge, J. E., Hoffmann, A. A. and McKechnie, S. W. (2006). Altitudinal patterns for latitudinally varying traits and polymorphic markers in Drosophila melanogaster from eastern Australia. Journal of Evolutionary Biology 19: 473-482
52_Collinge_et_al_2006_Heat_knockdown_time.csv
21_Kennington_&_Hoffmann_2013_Molecular_markers_&_In(2L)t_inversion
This data set contains haplotypes of 20 microsatellite loci located within and near the In(2L)t inversion and genotypes of the alcohol dehydrogenase (Adh) gene and the In(2L)t inversion (standard or inversion) for three Drosophila melanogaster populations collected in 2008 (Fig. 2&3). When using this data, please cite the original publication:
Kennington, W Jason, and Hoffmann, Ary A (2013). Patterns of genetic variation across inversions: geographic variation in the In(2L)t inversion in populations of Drosophila melanogaster from eastern Australia. BMC Evolutionary Biology 13.