Evolution of thermotolerance and the heat-shock response: evidence from inter/intraspecific comparison and interspecific hybridization in the virilis species group of Drosophila. I. Thermal phenotype
David Garbuz1,
Michael B. Evgenev1,2,
Martin E. Feder3,4,* and
Olga G. Zatsepina1
1 Engelhardt Institute of Molecular Biology, Russian Academy of Sciences,
Vavilov str. 32, 117984 Moscow, Russia
2 Institute of Cell Biophysics, Puschino, Russia
3 Department of Organismal Biology & Anatomy
4 The Committee on Evolutionary Biology, The University of Chicago, 1027 E.
57th Street, Chicago, IL 60637, USA
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Fig. 1. Inter- and intraspecific variation of basal thermotolerance in D.
virilis group species. Strain 160, although D. virilis, is a
marker strain with at least one known recessive mutation on each chromosome;
all other strains are wild-type. See Table
1 for additional descriptions of all strains. Data for D.
lummei strain 200 and D. virilis strains 9, 160 and 1433 are
replotted from Garbuz et al.
(2002 ), in which D.
virilis strain 1433 is mistakenly labeled strain 1590.
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Fig. 2. Effect of species, parental genotype and pre-treatment (PT) on (A) basal
and (B) inducible thermotolerance. Data for D. lummei strain 200 and
D. virilis strain 9 are replotted from Garbuz et al.
(2002). In B, two-headed
arrows represent the change in thermotolerance from basal levels (broken
lines) to tolerance after PT (solid lines). In pretreated D. virilis
strain 9 (solid red), PT was 30 min at 35°C, 36°C or 37°C. In
pretreated D. lummei strain 200 (solid blue), PT was 30 min at
35°C (as shown), 36°C (not shown) or 37°C (not shown). No D.
lummei pre-treated at 36°C or 37°C survived the ensuing heat
shock. The inset indicates color coding for reciprocal hybrids of D.
lummei strain 200 and D. virilis strain 9 and the species
identity of female (F) and male (M) parent. Broken and solid lines indicate
thermotolerance with and without pretreatment, respectively, after 35°C PT
for 30 min. Hybrids also underwent PT at 36°C for 30 min with heat shock
either following immediately (triangles) or 3 h later (squares); these symbols
signify the LT50s.
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Fig. 5. Variation in Hsp70 concentration in salivary glands due to species, strain
and heat-shock conditions. All determinations are for equivalent amounts of
total protein extracted 3 h after a 30-min heat shock and are from immunoblots
with 7FB, an antibody recognizing only the 70-kDa inducible Hsp70 family
member in D. melanogaster (see Materials and methods). (A) Effect of
heat-shock temperature on Hsp70 levels in D. virilis strains (solid
lines) and D. lummei strains (broken lines). Symbols represent the
mean densitometric signal ± 1 S.E.M. from at least five
independent immunoblots. All data are normalized to the densitometric signal
for equivalent amounts of protein extracted from D. melanogaster
salivary glands 1 h after a 30-min heat shock at 37.5°C. (B) Effect of
heat-shock temperature on Hsp70 levels in D. novamexicana (solid
line) and D. texana (broken line). Data are standardized and plotted
as for A. (C) 7FB-immunoblots of Hsp70 for various species and strains. Each
pair of lanes corresponds to 40°C and 41°C heat shock. See
fig. 2 in Garbuz et al.
(2002) for additional
determinations of Hsp70 levels.
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Fig. 6. Immunoblots of Hsp70 and Hsp70 family members in D. virilis strain
9, D. lummei strain 200 and their hybrid. In
Fig. 4, the box in the Hsp70
region for D. lummei strain 1109 represents the region of the present
figure. Data for the parental strains are repeated from Garbuz et al.
(2002) and are included to
facilitate comparison with data for hybrids. Primary antibody 7FB recognizes
only the 70-kDa inducible Hsp70 family member in D. melanogaster;
primary antibody 7.10.3 recognizes all Hsp70 family members (see Materials and
methods). Heat shock was 38°C for 30 min, with 3 h recovery at 25°C
before lysis. In the right-hand column, blue represents constitutively present
proteins recognized by 7.10.3 only, red represents inducible (i.e.
undetectable in glands not undergoing heat shock) proteins recognized by both
7.10.3 and 7FB, and green represents inducible proteins recognized by 7.10.3
only.
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Fig. 3. One-dimensional electrophoretic separation of 35S-labeled
proteins after 30-min heat shock. vir refers to D. virilis,
and lum refers to D. lummei; numbers represent strains. Size
markers refer to expected molecular masses of Drosophila heat-shock
proteins.
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Fig. 4. Two-dimensional electrophoretic separation of 35S-labeled
proteins after 30-min heat shock at 40.5°C and 3 h of recovery at
25°C. Species and strains are noted. Labels refer to molecular masses of
Drosophila heat-shock proteins; 70c represents constitutively
expressed Hsp70 family members. The box in the Hsp70 region for D.
lummei strain 1109 represents the region detailed in
Fig. 6. See Garbuz et al.
(2002) for additional results
after less-severe heat shock.
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Fig. 7. Effect of species, strain and thermal regime on hsp70 (above) and
actin (below) mRNA levels.
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Fig. 8. Electrophoretic mobility-shift assay for HSF (heat-shock factor) activation
at various temperatures in D. virilis strain 9 and D. lummei
strain 200. Appearance of a high-molecular-mass HSF complex indicates HSF
activation.
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© The Company of Biologists Ltd 2003
