University
of Minnesota Monarch Reproduction Research Projects:
Diapause in Monarchs
Liz Goehring & Karen Oberhauser
University Scientist
University of Minnesota
St. Paul MN
Overview
of Diapause Research
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Effects of photoperiod, temperature, and host plant age on induction of reproductive
diapause and development time in Danaus plexippus
LIZ GOEHRING† and KAREN S. OBERHAUSER
† Current affiliation RIDGE 2000 Program, Pennsylvania State University,
State College, U.S.A
Abstract
We studied diapause induction in monarch butterflies using adults
captured from the wild in Minnesota and Wisconsin, and individuals reared under
outdoor and controlled conditions. Oocyte presence in females and ejaculatory
duct mass in males were used to indicate reproductive status. Some wild individuals
were in diapause in mid August, and all males and females were in diapause by
late August and early September, respectively.
Individuals reared under decreasing day lengths and fluctuating
temperatures were more likely to be in diapause than were individuals reared
under long or short day lengths or constant temperatures. Individuals fed potted
old Asclepias curassavia plants were more likely to be in diapause than were
those fed potted young host plants; when cuttings of A. syriaca plants from
the field or greenhouse pots were used, there was no effect of host plant age.
Extremely high temperatures increased the number of day-degrees required for
development from egg to adult, while decreasing day lengths and older host plants
tended to decrease the number of day-degrees required for development.
Our results suggest that there is a continuum of reproductive
development in monarchs, with gradual declines in mean ejaculatory duct mass
and oocyte production during the late summer. None of the experimental treatments
led to 100% diapause, and diapause was more likely to occur in monarchs subjected
to more than one diapause-inducing cue.
Introduction
For an introduction to diapause in monarchs, see Background
on Diapause.
We studied several environmental cues involved in diapause
induction in eastern North American monarchs. To relate our laboratory findings
to conditions in the wild, we assessed the natural incidence of male and female
diapause in Minnesota and Wisconsin (north-central U.S.A.) populations. We then
conducted a series of controlled induction experiments to test the effects of
photoperiod, host plant characteristics, and temperature on both diapause incidence
and development rate.
Methods
Natural incidence. We
collected weekly samples of adults in south-central Minnesota and south-western
Wisconsin (~ 45°N, 90°W) from mid-summer to early autumn 1995 to assess
monarch reproductive status. Adults were held in outdoor cages (2 x 2 x 2 m)
on the University of Minnesota St Paul campus, fed a 25% (by volume) honey solution
daily, and their mating and oviposition behaviour was observed. In addition,
we reared weekly cohorts of 15-20 eggs from wild-captured females outdoors (the
initial cohort was collected as eggs and early-instar larvae from the wild on
19 July). We kept the cohorts outdoors in 56 x 40 x 31 cm screen cages until
we dissected the adults. Every day, we fed larvae fresh, wild-collected common
milkweed (A. syriaca) cuttings that were held in bottles of water to maintain
hydration. Adult mass and wing length were measured 24 h after eclosion, and
adults fed once each day and dissected at age 9 days as described below. We
obtained temperature data from National Oceanic and Atmospheric Administration
climatological records.
Diapause induction experiments. We conducted three experiments
in which developing monarchs experienced varying conditions in order to explore
the effects of specific environmental factors on diapause induction. These experiments
tested the effects of photoperiod, host plant characteristics, and temperature
on the proportion of adults in diapause (details below). We chose values for
each treatment variable to mimic natural environmental conditions in the northern
part of the monarch breeding range. In each experiment, adults were kept in
glassine envelopes in treatment chambers, and fed a 25% honey water solution
ad libitum every other day until dissection at age 9 days. All animals were
first- or second-generation offspring of adults captured in east-central Minnesota
and west-central Wisconsin. Only females were assessed in the first two experiments.
Experiment 1: photoperiod. We tested
the effect of photoperiod using three treatments: long day length (LD 16:8 h),
decreasing day length (starting with LD 15:9 h and decreasing by 3 min day until
adults were dissected), and short day length (LD 13:11 h). The long day length
treatment mimicked natural conditions in Minnesota during early summer, when
all monarchs are reproductive; the decreasing day length treatment mimicked
conditions in late July-late August, when diapause individuals are developing.
Each treatment chamber contained a standard
fixture with one 40 W and one 30 W fluorescent bulb (Sylvania Cool White Deluxe
brand) suspended 1 m above a tabletop on which larva cages were kept. Programmable
appliance timers were used to control photoperiod. The chambers were three adjoining
rooms (3 x 3 x 2.75 m) on one heating and ventilation system. We measured temperature
every time we fed or checked the monarchs (at least once each day); it did not
vary significantly among chambers or over time (mean = 23.2 °C, SE = 0.4
°C). This temperature is similar to average summer temperatures in Minnesota,
but field temperatures are more variable. Pans of water in the rooms maintained
~ 25% RH (checked every other day using a sling psychromoter).
At the start of the experiment, we transferred 50 newly hatched larvae per treatment
to potted, greenhouse-grown A. curassavica plants in screen cages (56 x 40 x
31 cm with 25 larvae per cage), and provided additional plants were provided
as needed to maintain a constant food supply. The greenhouse in which milkweed
was grown was maintained at LD 14:10 h, and we watered plants approximately
every 3 days and fertilized tehm weekly with a 20:20:20 NPK mixture. Larvae
pupated in the cages and adult mass and forewing length were measured 24 h posteclosion.
Experiment 2: photoperiod and host plant. We examined
the effects of day length and host plant age in a 3 x 2 factorial design, with
three photoperiod treatments and two host plant treatments. Photoperiod treatments
were the same as above, except that the short day length treatment was shortened
from LD 13:11 h to LD 10:14 h, and the decreasing day length began at LD 14:10
h instead of LD 15:9 h. Other conditions remained the same as in expt 1. We
reared larvae on greenhouse A. curassavica plants. Young plants were ~ 1 month
old; old plants were 8-9 month-old flowering plants that had been cut back and
allowed to leaf out for 8-12 weeks. Old plants were watered half as frequently.
There were 33-40 larvae per treatment, reared as described above.
Experiment 3: photoperiod, temperature and host plant. We
examined the effects of photoperiod, temperature, and host plant quality in
a 2 x 2 x 2 factorial design, with two blocks, using temperature- and photoperiod-controlled
Percivel growth chambers. Long and decreasing day length treatments were the
same as in expt 2; the short day length treatment was omitted. Temperature regimes
included a constant (27 °C) and a fluctuating temperature (27 °C thermophase
to 21 °C cyrophase, with temperature exposures coinciding with LD periods).
This experiment was conducted when A. syriaca is widely available in Minnesota.
To obtain young and old plants simultaneously, we used a combination of wild
and greenhouse-grown A. syriaca. In the first block, early in the summer, we
used cuttings from wild milkweed for young plant treatments cuttings from 4-5-month-old
greenhouse plants for old host plant treatments. In the second block, later
in the summer, we used cuttings from old ramets (with seed pods and yellowing
leaves) and new growth from plants with unblemished, green leaves for the old
and young plant treatments, respectively. “Young plants” had been
mowed within the past one or two months, so it was actually the leaves, and
not the entire plants, that were young. In both blocks, we kept plant cuttings
in floral tubes and changed them daily. We reared larvae in plastic cages with
screened lids (30 x 17 x 11 cm).
Assessing diapause
Females. We dissected
nine-day-old females under 6x magnification; an absence of mature oocytes
was used as the criterion for diapause. Females kept outdoors in the summer
have mature oocytes 6 days after eclosion (Oberhauser & Hampton, 1995),
while females in reproductive diapause have small, undeveloped ovarioles
at the same age (Herman, 1973). We assessed the degree of ovarian development
in females not in diapause by tallying the number of mature oocytes.
Males. We used the wet mass of the ejaculatory
duct to assess male diapause; diapause males have smaller reproductive
organs than reproductively active males (Herman, 1985). We dissected males
were dissected under 12x magnification in insect saline, cleared fat bodies
and tracheae from the lower portion of the reproductive tract complex,
and removed the ejaculatory duct. This portion of the tract is the lowest
section from the aedeagus to the tubular gland and is separated from the
tubular gland by a narrow region. Once removed and cleared of remaining
fat bodies, we blotted the ejaculatory duct on absorbent tissue to uniform
dryness and weighed to 0.01 mg on a Mettler AE 240 balance (Mettler Instruments,
Greifensee, Switzerland).
Wild-caught individuals. Because adults collected
from the wild are of unknown ages and mating histories, diapause cannot
be assessed in the same manner as in laboratory-reared animals. Mating
by males and oviposition by females, however, indicate non-diapause status.
We held wild-captured males in a large, outdoor mating cage with reproductive
laboratory females (with a 1:1 sex ratio). Males that mated within 5 days
were considered reproductive and were subsequently released. We assessed
the status of wild-captured females both behaviourally and through dissection.
After capture, they were held in individual mesh cages (66 x 66 x 66 cm)
with fresh milkweed for 2 days. Females that oviposited were considered
reproductive and released. To allow for the possibility that the non-ovipositing
females were not mated, we transferred them to a cage with reproductive
males for up to 5 days. If they mated, we transferred them to oviposition
cages with fresh milkweed. Non-mating females and females that did not
oviposit within 5 days of mating were dissected as described above. Because
monarchs continue to produce oocytes throughout their lives (Oberhauser,
1997), old reproductive females do not run out of eggs and will thus not
be mistaken for diapause females. This variability in treatment minimised
the number of wild adults that were killed; females were only dissected
if other methods of assessing reproductive status were inconclusive.
Statistical analyses. We used logistic regression
models, which are appropriate for binomial (e.g. yes/no) data (Hardy &
Field, 1998), in analyses of female diapause. For the analyses of ejaculatory
duct mass and mature oocyte production, we used a stepwise linear regression
to test the effects of treatment variables, interaction terms, and adult
mass. The effects of treatment variables on mass and development time
were analysed using ANOVA.
Results
Natural incidence of diapause. All wild-caught
females collected and held until 23 August were reproductive, although
sample sizes during August were small (Table 1).
Table 1. Reproductive activity in wild-captured
butterflies
| |
Females |
Males |
Week captured |
N |
Number that laid eggs |
Number with mature oocytes |
Per cent reproductive |
N |
Number that mated within 5 days |
Per cent reproductive
|
17-26 July |
5 |
3 |
2 |
100 |
8 |
8 |
100 |
27 July – 2 August |
4 |
3 |
1 |
100 |
2 |
2 |
100 |
3-9 August |
2 |
2 |
0 |
100 |
5 |
5 |
100 |
10-16 August |
3 |
3 |
0 |
100 |
4 |
4 |
100 |
17-23 August |
1 |
0 |
10 |
100 |
5 |
3 |
60 |
24-30 August |
3 |
1 |
1 |
67 |
8 |
2 |
25 |
31 August-6 September |
16 |
4 |
1 |
31 |
24 |
0 |
0 |
7-12 September |
5 |
0 |
0 |
0 |
10 |
0 |
0 |
Logistic regression analysis of deviance
using week as the predictor for diapause was significant. (females:
 deviance
= 28.94, d.f.
= 1, p < 0.001; males: deviance
= 69.1, d.f.
= 1, p < 0.001). |
By the second week in September, all females were in diapause.
Male mating behaviour began to decline a week earlier, in mid-August,
and ceased by the end of August (Table 1). Almost all reproductive behaviour
ceased in wild-caught adults in the last 2 weeks of collection, corresponding
to the peak of migration in Minnesota (K. S. Oberhauser & L. Goehring,
pers. obs.).
In cohorts of monarchs reared outdoors (Table 2), all females
that emerged on or before 25 August developed mature oocytes, with the
exception of one female in cohort 1. In the weeks of 30 August and 10
September, 46 and 100% of the females were in reproductive diapause. There
was a significant, negative relationship between date of emergence and
diapause. Among females that did not diapause, there was a significant
relationship between the number of mature oocytes and date, with those
emerging later producing fewer oocytes.
Table 2. Reproductive
development in cohorts of monarchs reared outdoors
| |
Females |
Males |
Date eggs laid |
Date adults emerged |
N |
Per cent reproductive† |
Mean mature oocytes‡ (SD) |
Mean mass§ (g) |
N |
Mean
ED/mass¥ (SD)
|
Mean mass§ (g) |
NA |
9-18 August |
7 |
86 |
84.2a(67.6) |
0.532 |
2 |
0.041a(0.002) |
0.523 |
27 July – 2 August |
18-21 August |
7 |
100 |
40.4ab(43.0) |
0.532 |
8 |
0.035a(0.006) |
0.485 |
| 28 July |
24-25 August |
11 |
100 |
|
0.502 |
9 |
0.027ab(1.005) |
0.502 |
3 August |
30 August – 1 September |
13 |
54 |
15.3b(8.6) |
0.485 |
9 |
0.021b(0.008) |
0.488 |
| 12 August |
10-13 September |
7 |
0 |
na |
0.517 |
8 |
0.011c(0.008) |
5.546 |
† Per cent containing mature
oocytes. Logistic regression analysis of deviance using date of
emergence as the predictor for reproductive status was significant
(deviance
= 27.0, d.f.
= 1, p < 0.001).
‡ Mean excludes females in reproductive diapause. ANOVA F3,27
= 3.01, p < 0.05; means followed by the same letter are not significantly
different at the 0.05 level of confidence (Tukey least significant
difference comparisons).
§ No difference in adult mass among cohorts (females: F4,40
= 2.17, NS; males: F4,36 = 2.37, NS).
¥ Ejaculatory duct mass/adult mass (F4,31 = 16.94, p < 0.001);
means followed by the same letter are not significantly different
at the 0.05 level of confidence (Tukey least significant difference
comparisons).
|
Male reproductive tract development also changed over time.
There was a significant relationship between ejaculatory duct mass and
date of emergence, with late season cohorts having smaller ejaculatory
ducts (Table 2). The gradual decrease over time of male reproductive tract
mass is illustrated in Fig. 1a; the transition period
is characterised by intermediate masses during the last third of August.
Only in the final cohort did most males have small ejaculatory ducts.
|
|
Table 3. Summary of
cohort development
Cohort (n) |
Development period |
Mean temperature† |
Mean daily fluctuation‡ |
Mean development time§ |
Mean development time (day-degree)¥ |
| ....°C ............SD |
....°C .........SD |
....Days............SD |
......DD............SD |
1 (21) |
20 July – 20 August |
23.6ab.........2.0 |
10.8......... 2.7 |
30.3a .........0.8 |
363.3a .........7.8 |
2 (26) |
1-25 August |
23.7ab.........
2.0 |
10.4......... 2.7 |
22.8d.........
0.5 |
282.4c.........
5.7 |
| 3 (26) |
7 August – 1 September |
24.0a .........1.8 |
9.7......... 3.0 |
|
294.4b .........6.1 |
4 (16) |
15 August – 13 September |
22.0b .........4.0 |
11.1......... 3.2 |
26.9b.........
1.0 |
279.8c .........7.3 |
† Mean temperature experienced
during development period, hatching to eclosion. Numbers followed
by the same letter were not significantly different at the 0.05
confidence level (F3,103 = 3.33, p < 0.05, Tukey least significant
difference comparisons).
‡ Means did not differ among cohorts (F3,103 = 1.12, NS).
§ Time from hatching to adult. Means differed among cohorts
(F3,85 = 509.3, p < 0.001).
¥ Degree days =  (daily
mean temperature - 12 °C threshold temperature) from hatching
to adult. Means differed among cohorts (F3,85 = 740.1, p < 0.001) |
Temperatures experienced by cohorts affected
the length of the development period, although day-degrees were
roughly consistent among groups, with the exception of the first cohort
(Table 3). This cohort experienced 7 days on which temperatures reached
or exceeded 30 °C. Cohort 3 experienced 5 days over 30 °C, while
cohorts 2 and 4 experienced 4 days over 30 °C. Mean daily temperature
fluctuation (maximum-minimum) did not vary among cohorts. Neither female
nor male body mass varied among cohorts.
Diapause induction
Photoperiod. Diapause incidence varied significantly
between decreasing and other day length treatments (Table 4, Fig.
2a) (significant contrasts are evident when the log-odds ratio is
different from one). The log-odds ratio of 8.14 indicates that the odds
of inducing diapause in the decreasing day length treatment are about
eight times those of other photoperiod treatments. Adult size did not
vary among treatments, and the size of reproductive and diapause females
did not differ. While the difference in the number of mature oocytes produced
in reproductive females (Fig. 3a) was not significant
at the 0.05 level (F2,44 = 2.84, p = 0.069), there was a trend towards
more oocytes produced by females in the long day length treatment.
|
 |
|
| Table 4.
Summary of final binomial regression models testing factors affecting
female diapause probabilities.
Predictor |
Coefficient |
SE |
p |
Log-odds |
95% CI
|
| Experiment 1:
photoperiod (effects of long and short day treatments also
tested) |
Constant |
-2.00 |
0.47 |
< 0.0001 |
|
282.4c.........
5.7 |
| Decreasing day |
2.10 |
0.64 |
< 0.01 |
|
294.4b .........6.1 |
| |
Deviance |
59.73 |
d.f. |
61 |
| Experiment 2: photoperiod and host
plant (effects of long and short day length treatments and interactions
also tested) |
Constant |
-4.54 |
1.08 |
< 0.0001 |
|
|
Old host plant |
2.51 |
1.06 |
< 0.05 |
12.26 |
1.53 – 98.44 |
Decreasing day |
1.62 |
0.60 |
< 0.01 |
5.04 |
1.54 – 16.5 |
| |
Deviance |
72.28 |
d.f. |
112 |
Experiment 3: photoperiod, host
plant, and temperature (effects of long and short day treatments,
host plant and block, and interactions also tested) |
Constant |
-4.66 |
0.76 |
< 0.0001
|
|
|
Decreasing day |
3.65 |
0.74 |
< 0.0001 |
38.5 |
9.1 – 163.0 |
Fluctuating temp |
1.17 |
0.41 |
< 0.01 |
3.2 |
1.5 – 7.2 |
|
|
| |
Deviance |
150.68 |
d.f. |
214
|
Development time in day-degrees, from hatching to eclosion,
was significantly longer in the long day treatment (Fig.
4a).
Mean development times for diapause and reproductive females
did not differ significantly.
Photoperiod and host plant. Females were most likely
to be in diapause when reared under decreasing day length and fed old
milkweed (Fig. 2b). To assess the importance of each
treatment variable, four models were tested in a stepwise analysis of
deviance: null, a photoperiod effect, a plant-quality effect, and a combination
of both cues. The most parsimonious model for predicting diapause included
only host plant and decreasing day length variables (Table 4). The odds
of diapause for females reared on old plants were 12 times those for females
reared on young plants. The odds of diapause in decreasing day length
treatments were five times the odds for other day lengths. Both factors
contributed to the likelihood of diapause but the lack of a significant
interaction implies that their functions are additive. |
|
|
| To rule out an effect of nutrition
on reproductive development, mass at emergence was examined. There was
a relationship between mass and host plant age, however females fed old
plants were significantly larger (young plant mean = 0.473 g, old plant
mean = 0.537 g; F1,113 = 60.16, p < 0.001). The sizes of diapause and
reproductive females did not differ significantly.
Stepwise linear regression of mass, host plant, and photoperiod
(the latter two were included as indicator variables in the model) on
oocyte production in reproductive females revealed that only the long
day length treatment had a significant effect, with females reared in
this treatment producing more mature oocytes (Table 5, Fig.
3b).
Table 5. Stepwise linear regression of
reproductive development in exp 2 and 3.
Predictor |
Coefficient |
SE |
p |
Oocyte production in photoperiod and host plant experiment
Adj. R2 = 0.38, N = 100, overall p <
0.001 (no effect of host plant or mass)
|
Constant |
52.2 |
52.2 |
<0.001 |
| Long day length |
74.6 |
|
<0.001 |
| Oocyte production in photoperiod,
host plant, and temperature induction experiment
Adj. R2 = 0.525, N = 173, overall p <
0.0001 |
Constant |
20.5 |
30.4 |
0.501 |
Mass |
281.2 |
50.3 |
<0.001 |
Block |
38.1 |
5.7 |
<0.001 |
Decreasing day length |
-42.2 |
5.9 |
<0.001 |
Fluctuating temperature |
-17.0 |
5.6 |
0.0003 |
Ejaculatory duct mass in photoperiod, host
plant, and temperature induction experiment Adj. R2 = 0.413, N =
212, overall p < 0.0001 |
Constant |
0.0135 |
0.0028 |
<0.001 |
Decreasing day length |
-0.0053 |
0.0005 |
<0.001 |
Fluctuating temperature |
-0.0027 |
0.0047 |
<0.001 |
Mass |
0.0117 |
0.0005 |
0.014 |
Monarchs reared under decreasing day lengths and fed old
plants developed more quickly (in day-degrees) (Table 6,
Fig. 4b). There was no significant difference in development
time between diapause and reproductive females, and no relationship between
development time and size, after controlling for host plant.
Photoperiod, host plant, and temperature. Female
diapause in this experiment was most likely to occur under decreasing
day length and fluctuating temperature conditions (Fig.
2c). A summary of the resulting binomial regression model from the
analysis of deviance is shown in Table 4. The odds of
diapause under decreasing day length conditions were 38 times those under
long day lengths. The odds of diapause under the fluctuating temperatures
were three times those of the constant temperature regime. The effects
of photoperiod and temperature were similar in the two blocks, and host
plant had no effect even when the blocks were analysed separately. There
were no interaction effects. |
|
|
Stepwise linear regression on
the number of mature oocytes in reproductive females revealed several
significant relationships (Table 5, Fig. 3). Heavier
females contained more eggs, while those reared in decreasing day length
treatments and fluctuating temperature regimes produced fewer eggs. Females
in the second block produced fewer mature oocytes than females in the
first block, although the pattern of relative mature oocyte production
in each treatment was consistent between blocks. There was no effect of
plant quality on oocyte production.
Males from decreasing day length treatments
had smaller reproductive tracts, as did males reared under fluctuating
temperature treatments (Table 5, Fig.
1b). There was no effect of the interaction of day length and temperature,
indicating that the effects of these two factors are additive; there was
also no effect of block or plant quality on male reproductive tract mass.
Mean development time in day-degrees varied among treatments.
In block 1, where old greenhouse plants and young plants from the wild
were used, individuals fed old plants and kept in fluctuating temperatures
developed more quickly (Table 6, Fig. 4c). In block
2, where both old and new plants were from the wild, monarchs raised in
fluctuating temperatures developed more quickly, as did those fed young
plants and kept in long day lengths (Table 6, Fig. 4d).
There was no difference in mean development time between diapause and
reproductive females, and no correlation between ejaculatory duct mass
and development time.
Table 6. Analysis of
factors affecting development time.
Source |
d.f. |
SS |
F |
p |
| Experiment
2: photoperiod and host plant† (N = 227, comparisons
of means showed that decreasing day and old host plants resulted
in shorter development times) |
Photoperiod |
2 |
10051 |
35.5 |
<0.001 |
| Plant |
1 |
|
68.9 |
<0.001 |
Photoperiod x plant |
2 |
836 |
2.96 |
0.05 |
Residual |
221 |
31285 |
|
|
| Predictor |
Coefficient |
SE |
Student's t |
p |
| Experiment 3:
photoperiod, host plant, and temperature; block 1†,
N = 244, adj R2 = 0.52 |
Constant |
290.35 |
0.97 |
298.40 |
<0.001 |
Old host plant |
-4.42 |
1.34 |
-3.22 |
<0.01 |
Fluctuating temperature |
|
1.27 |
-15.69 |
<0.001 |
| Experiment 3:
block 2†, N = 243, R2 = 0.59 |
Constant |
284.23 |
1.30 |
217.86 |
<0.001 |
Old host plant |
9.42 |
1.35 |
7.00 |
<0.001 |
| Fluctuating temperature |
-15.34 |
1.35 |
-11.37 |
<0.001 |
Decreasing day length |
16.75 |
1.34 |
12.44 |
<0.001 |
| †ANOVA used to analyse
expt 2, and stepwise linear regression used to analyse development
time in expt 3 due to unbalanced sample sizes in expt 3 treatments.
Indicator variables used for treatments. Expt 3 blocks were analysed
separately due to different host plant sources in two blocks (see
text). |
|
|
|
|
Discussion
Assessing the timing and progression of diapause
There was a pronounced change in female reproductive behaviour and physiology
at the end of the summer (Table 1). By late August, a third
of females did not oviposit in captivity and by the second week of September
all were in diapause. There was a similar progression in cohorts reared outdoors;
half of the females that emerged during the last week of August and all females
that emerged after 1 September were in diapause (Table 2).
The onset of male diapause followed a similar pattern. Mating behaviour in wild-caught
males tapered off beginning in mid-August, and reproductive tract mass decreased
steadily over 5 weeks in the cohorts (Table 1). By the end
of August, mean ejaculatory duct mass was roughly half that of the earliest
cohort, indicating diapause. While sample sizes of wild-captured adults were
low, the clear pattern and correspondence with cohorts reared outdoors suggest
that the observed patterns are real.
The time during which these changes occur in the northern part
of the monarch breeding range is characterised by decreasing day lengths (2
min day-1 in July to 3 min day-1 in August) and generally decreasing temperatures,
especially during cryophase. The duration of thermophase also decreases. The
influence of these factors and host plant characteristics on monarch diapause
induction is discussed below.
Environmental cues and diapause induction
Decreasing day length. In each experiment, there was
a significant effect of decreasing day length on diapause induction in females
(Fig. 2). Likewise, ejaculatory duct mass was smaller in
males reared in decreasing day length treatments in expt 3 (Fig.
1b). It is unlikely that the salient feature of the photoperiod treatments
was the absolute length of photophase rather than the rate of change over time;
if monarchs respond to an absolute critical day length, the short day length
treatment should have induced diapause as effectively as the decreasing day
treatment. These results do not, however, rule out the possibility that an intermediate
average day length induces diapause in monarchs. The number of available incubators
did not allow simultaneous testing of a constant, intermediate photophase.
There is increasing evidence that changes in photoperiod induce
diapause (Solbreck, 1979; Tauber et al., 1986; Nylin, 1989; Han & Gatehouse,
1991; Blanckenhorn, 1998). Decreasing photoperiod is likely to have a more pronounced
effect in higher latitudes where the change is more perceptible (Taylor &
Spalding, 1986; Han & Gatehouse, 1991; Gatehouse & Zhang, 1995) and
also in insects (like monarchs) in which the offspring of different generations
are exposed to different photoperiods (Solbreck, 1979). The results reported
here support Solbreck’s suggestion that response to decreasing day length
enables synchronisation with habitat at different latitudes; however it will
be important to test monarch responses to less pronounced changes in photoperiod,
such as those experienced in the central and southern U.S.A. in late summer
and early autumn.
Temperature. Diapause was twice as likely to occur in
females reared under a conservative fluctuating temperature treatment where
night temperatures were lower than day temperatures (Fig. 2c),
and males reared under fluctuating temperatures developed smaller ejaculatory
duct tracts (Fig. 1b). While it is possible that the monarchs
responded to cool average temperatures per se, as opposed to temperature fluctuation,
adults kept in an incubator at constant 21 °C under summer photoperiods
do not diapause (K. S. Oberhauser, pers. obs.)
Although not as consistent a cue as
photoperiod, temperature is seasonably variable. James (1983) showed that cool
temperatures induce reproductive dormancy in post-eclosion
monarchs, regardless of photoperiod during the immature states. Most investigations
of temperature have focused on the modulating effect of a particular critical
temperature on photoperiod cues, with few studies focusing on the primary effect
of temperature, in particular thermoperiod, on diapause induction (Beck, 1982;
van Houten et al., 1987). Response to a fluctuating temperature regime may
be a function of
reaching a threshold temperature in cryophase,
of the duration of each phase of the cycle, or of the differences between phases
(Beck, 1983). While the precise mode of action is
uncertain, the results suggest that temperature intensifies the effect of photoperiod
on diapause induction and that monarchs
respond to some aspect of thermoperiod with
amplitude as little as 6 °C and thermophase duration of 14 h. Thermophase/cyrophase
amplitudes typical of late summer in the north central U.S.A. are closer to
10 °C (Watson et al., 1999; Table 2). The duration of
thermophase, which decreases as the season progresses, may also be an important
cue.
Host plant characteristics. Response to host plant characteristics
was mixed. In expt 2, in which potted, greenhouse-grown A. curassavica were
used, monarchs fed old plants were more likely to be in diapause (Fig.
2b). In expt 3, in which limits imposed by plant rearing necessitated comparing
cuttings from greenhouse and wild A. syriaca, plant characteristics had no effect.
It is possible that monarchs respond differently to A. curassavica and A. syriaca.
This difference may also have resulted from incomplete control of factors affecting
plant characteristics. Greenhouse plants were consistently manipulated, whereas
controlling for changes in wild milkweed was difficult. All greenhouse plants
were kept on the same photoperiod (LD 14:10 h), whereas wild plants experienced
natural conditions. Thus, the experimental design would not have detected insect
response to plant cues affected by the light:dark regime experienced by the
plants. In addition, plant cuttings may not convey accurate age cues. Latex
flow depends on a pressure delivery system destroyed in cuttings, and it is
possible that latex quality provides a cue to plant age. Results with A. curassavica
suggest a plant function in diapause induction in monarchs, and the effects
of plant age warrant further study.
Several studies (Sims, 1980; Hare, 1983; Koveos & Tzanakakis,
1989; Hunter & McNeil, 1997) have demonstrated differential diapause response
in animals reared on different plant species, but the mechanisms by which plant
cues within a species affect diapause are largely uninvestigated. Any cue from
the plant must be a consistent response to late season growing conditions (e.g.
withdrawal of protein from leaf tissue, changes in phytochemical concentrations,
toughening of leaves, presence of flower and seed pod). Rankin (1985) demonstrated
delayed reproduction in female Oncopeltus fasciatus when fed sub-optimal milkweed
(green pods and flowers), suggesting an effect of starvation on diapause induction.
Hunter and McNeil (1997) proposed a nutritional mechanism for diapause induction
in Choristoneura rosaceana, suggesting that plant protein levels affect insect
development rate in relation to a photoperiod-sensitive stage for diapause induction.
In the mite Petrobia harti, more females lay diapause eggs when they are fed
leaves from flowering plants vs. non-flowering plants under diapause-inducing
photoperiods (Koveos & Tzanakakis, 1989).
Response to multiple cues. When the effects of multiple
cues were tested, a second cue resulted in an increase in the percentage of
animals in diapause. In expt 2, feeding on old plants increased the percentage
of females in diapause under decreasing day length treatments, as did a fluctuating
temperature regime in expt 3. The lack of a significant interaction between
the cues suggests that they act additively but not synergistically. Blanckenhorn
(1998) reported similar findings with diapause response in dung flies; shorter
photoperiod/cooler temperature combinations resulted in increasing proportions
of females in reproductive diapause. Using multiple cues to assess current and
near future habitat suitability could be an optimal strategy for organisms in
unpredictable environments, in which selection should favour individuals best
able to exploit habitat while it is available.
Individual variation in response to environmental cues. There is significant
within-population variation in response to diapause-inducing stimuli in monarchs.
First, while the percentage of diapause in males and females increases with
combinations of cues, diapause occurred in response to a single cue. Second,
there was a gradual shift to diapause in monarchs reared under natural conditions;
increasing numbers of individuals were in diapause as the season progressed.
Finally, none of the experiments resulted in 100% diapause; the highest proportion
of individuals in diapause in any treatment was 56%. This variation could be
due to genetic or environmental effects; the experiments cannot differentiate
between these possibilities but this is a promising avenue for further study.
There was also variation in the degree of reproductive development.
Reproductive females in outdoor conditions produced fewer mature oocytes as
the season progressed (Table 2), and in laboratory experiments,
treatments that contained the highest proportions of diapause females also resulted
in reproductive females with fewer mature oocytes (Fig. 3),
although this effect was not statistically significant in expt 1. Ejaculatory
duct masses were not distributed bimodally (Fig. 1), which
is expected if there is a clear distinction between diapause and reproductive
males. Instead, their mass declined gradually over time in cohorts reared outdoors,
and there was a great deal of overlap among the males in the different treatments
in expt 3. It is possible that females with fewer mature oocytes and males with
ejaculatory ducts of intermediate mass eclosed in a physiological state that
could have developed into either diapause or reproductive maturity, depending
on environmental conditions.
Variation in response to environmental cues has been described in other insects.
Both reproductive and diapause seasonal forms of the leafwing Anaea andria eclose
from identical larval photoperiods of 13 h day length (Riley, 1988). In Papilio
zelicaon, Sims (1980) demonstrated shortened critical photoperiod and decreased
frequency of diapause after five generations of selection for non-diapause.
Variation in diapause response may be expected particularly along geographical
gradients (Taylor & Spalding, 1986; Sims, 1980), with variation typically
declining at higher latitudes (Vinogradova, 1986). Seasonal habitat variability
from year to year could favour this kind of bet-hedging.
In addition to within-population variation in monarch diapause,
there appears to be a great deal of between-population variation, with populations
in different locations showing a spectrum of dormancy ranging from no dormancy
to complete diapause (Tuskes & Brower, 1978; James, 1982, 1983; Herman,
1985, and references therein). The degree to which these differences are environmentally
or genetically determined remains to be discovered.
While results reported here are the first to document effects
of environmental cues on diapause induction in eastern North American monarchs,
important questions about diapause induction in this species remain. The study
did not identify conditions leading to 100% diapause. Constant temperatures
in expts 1 and 2 may have had an inhibitory effect because constant temperatures
are rare under natural conditions. It is possible that the actual temperature,
in addition to the degree of fluctuation, is important, and that lower temperatures,
or a greater fluctuation, would have resulted in more individuals in diapause.
It is also possible that monarchs respond to cues that are difficult to reproduce
in a laboratory. In addition, the metamorphic stage at which diapause is induced
in monarchs remains to be determined because monarchs were kept under experimental
conditions throughout their development.
Development rates
Development times (in day-degrees) for monarchs reared outdoors were approximately
equivalent, with the exception of the first cohort that experienced several
days above 30 °C (Table 3). Temperatures above 30 °C
may retard growth without being lethal (Zalucki, 1982; Baker et al., 1985; Malcolm
et al., 1987; York and Oberhauser 2002), and the method used to calculate day-degrees
does not correct for the effects of upper threshold temperatures.
The effects of temperature on monarch development rates are well
documented, and the results reported here are similar to those reported elsewhere
(Rawlins & Lederhouse, 1981; Zalucki, 1982; Malcolm et al., 1987; Masters,
1993). In addition, monarchs reared under conditions most likely to induce diapause
tended to require fewer day-degrees to develop from egg to adult (Table
6). Decreasing and short day length treatments in expt 1, decreasing day
length and old host plants in expt 2, and fluctuating temperatures in expt 3
all tended to shorten development time; however the effects of host plants differed
in the two blocks of expt 3, and decreasing day lengths in block 2 of expt 3
were associated with longer development time. While the experiments were not
designed to test factors that may affect development time, these results warrant
further investigation. A similar finding was reported by James (1987), who found
that two Australian migratory butterflies, Vanessa kershawi and Junionia villida,
developed faster under short day lengths.
These experiments did not compare growth rates on different host plants explicitly,
but development time (in day-degrees) was shorter in expt 3, in which A. syriaca
was used, than in expts 1 and 2, in which A. curassavica was used (Table
1, Fig. 4). These two species vary in cardenolide content,
with A. curassavica having much higher concentrations of cardenolides (Malcolm
& Brower, 1986); the effects of cardenolide concentration on development
rates would also be a productive avenue for future study.
Acknowledgements
Sonia Altizer and Imants Pone helped to catch and rear monarchs,
Bill Herman taught dissection techniques and shared insights, Dick Phillips
stimulated early interest in diapause and Don Alstad, Sonia Altizer, Michelle
Prysby, Michelle Solensky, Melody Ng and Gina Hupton contributed insights during
discussions of the work. Bill Herman, Myron Zalucki, David James and Gina Hupton
commented on earlier versions of the manuscript. This work was supported by
National Science Foundation Grants DEB-9220829 and ESI-9554476 to K.S.O. and
a James W. Wilkie Award from the Bell Museum of Natural History at the University
of Minnesota to E.G
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