Effects of intestinal nematodes during lactation: consequences for host morphology, physiology and offspring mass
Department of Biology, University of California, Riverside, CA 92521,
USA
Present address: Department of Biological Sciences, University of Idaho,
Moscow, ID 83844, USA
(e-mail: kristand{at}uidaho.edu)
Accepted 16 September 2002
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Summary |
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Key words: lactation, phenotypic plasticity, parasites, host reproduction, offspring mass, Heligmosomoides polygyrus, nematode
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Introduction |
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It is useful to understand how multiple simultaneous demands affect
morphological and physiological responses. Although some demands occur
serially, animals typically face multiple, simultaneous demands in nature; for
example, parasite infection and reproduction. Some potential consequences of
changes in resource allocation within an individual resulting from concurrent
parasitism and lactation include increased morbidity or mortality, behavioral
changes, changed organ morphology and function, or a shift in life-history
traits such as host reproductive output. Because many wild animals encounter
parasites during their lives, it is important to know if there is a fitness
consequence of parasitism during host response. Also, because response to
parasitism can affect the host's response to a second demand
(Carlomagno et al., 1987;
Banerjee et al., 1999
;
Kristan and Hammond, 2001
), it
is also important to understand if the demands of parasitism and lactation act
independently or synergistically.
Effects of ectoparasites on host reproduction have been demonstrated for a
number of species (e.g. Richner and Heeb,
1995; Van Vuren,
1996
; Richner and Tripet,
1999
), and, more recently, the physiological costs of sublethal
endoparasite infection, and the consequences of these costs to host
reproduction and other life-history traits, have also been addressed
(Kyriazakis et al., 1996
).
Some researchers found no effect of sublethal endoparasites on host
reproduction (Munger and Karasov,
1991
), whereas others revealed negative effects on host
reproduction (Feore et al.,
1997
); for example, small rodents with a naturally occurring
infection of cowpox virus increased the time to first-litter production
(Feore et al., 1997
), which may
affect lifetime reproductive success in short-lived rodents.
The objective of my study was to compare how infection with H.
polygyrus affected host morphology and physiology in the laboratory mouse
during lactation and non-reproduction, and, for reproducing mice, to determine
if there were consequences for host reproductive output. I hypothesized that
(1) the effects of parasitism would be greater during lactation than for
virgin mice and (2) parasitized mice would experience differential resource
allocation (evidenced by changes in morphology and physiology) that would
result in changes in reproductive output compared with unparasitized mice. To
examine these hypotheses, I conducted two experiments. First, I designed a
lactation experiment to examine changes in resting metabolism, organ
morphology, body composition and small intestine function during lactation. I
measured these variables at peak lactation, approximately 15 days post-partum,
when the energetic demand to the mother is at its greatest
(Hammond et al., 1994). Based
on previous studies (Kristan and Hammond,
2000
,
2001
), I predicted that
parasitized lactating mice would have a greater decrease in small intestine
function, greater resting metabolism, less body fat and greater lean mass than
lactating mothers without parasites. Second, I conducted a reproductive-output
experiment where I used continuously mated pairs of mice (some with
parasitized females and some with unparasitized females) to examine
reproductive output (e.g. litter size and offspring mass). I predicted that
parasitized mothers would have an increased time to first-litter production
(Feore et al., 1997
), longer
inter-litter intervals, more pup loss from birth to weaning, more unsuccessful
litters, and smaller offspring than unparasitized mothers, because energy
normally invested in offspring would be used in response to parasite infection
or, possibly, less energy would be absorbed when infected with intestinal
parasites.
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Materials and methods |
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Mouse infection procedures
H. polygyrus infective-stage larvae (L3) were
cultivated from non-experimental mice. Parasitized mice from both experiments
were infected with 300±11 L3 suspended in tapwater as
described by Kristan and Hammond
(2000). Unparasitized mice
were given an approximately equal volume of tapwater. For both experiments,
parasitized females were checked for parasite eggs using a modified McMaster
technique (Bowman, 1995
) at 14
days post-infection (PI) to be sure that they were infected prior to mating,
and unparasitized females were checked to be sure they were not infected.
Thereafter, females from the reproductive-output experiment were checked for
the presence of infection at the weaning of each litter or every 3 weeks if
litters were not successfully produced or weaned. Males from mated pairs were
also checked every 2-6 weeks to determine if the infection was transferred
from the female to the male. At weaning, a subset of pups was also checked for
the presence of parasites.
Lactation experiment
Digestive efficiency measures
Mice were maintained at 14 h: 10 h L:D, 23°C and initially fed standard
rodent diet (LabDiet® 5001, Purina Mills, Inc., St Louis, MO, USA). On day
33 PI, mice were switched to a high carbohydrate diet (Custom Karasov diet,
ICN Nutritional Biochemicals, Cleveland, OH, USA: 55% sucrose, 15% casein, 7%
cottonseed oil, 2% brewer's yeast, 4% salt mix, 1% vitamin and 16%
non-nutritive bulk; Diamond and Kasarov, 1984) to determine maximal
glucose-transport capacity. On day 47-49 PI, body mass, food-intake rate
(I; measured in g day-1) and fecal output rate
(O; measured in g day-1) were measured
(Hammond and Diamond, 1992).
Average percentage apparent dry-matter digestibility (i.e. digestive
efficiency) was calculated as
[(IO)I-1]x100 for days 47-49 PI.
Females from the reproductive-output experiment were maintained on standard laboratory diet for the first 14 days PI. On day 14, a male was added to their cage and the diet was switched to the Custom Karasov diet to allow comparisons between reproductive output measures for mated pairs and physiological and morphological measures obtained from mice in the lactation experiment.
Resting metabolic rate
Resting metabolic rate (RMR) of non-postabsorptive mice was measured as
oxygen consumption
(O2; measured in
ml min-1) using open-flow respirometry starting between 08.00 h and
09.30 h on day 49 PI. Dried air (Drierite, W. A. Hammond Drierite Co., Xenia,
OH, USA) entered a 600 ml Plexiglas chamber housed in a dark cabinet
(30±1°C; within the M. musculus thermoneutral zone;
Hart, 1971
) at 650-700 ml
min-1 from mass-flow controllers (Porter Instrument Company, Inc.,
Hatfield, PA, USA). Air leaving the chamber was dried, scrubbed of
CO2 (soda lime) and re-dried before entering an Applied
Electrochemistry S-3A/II oxygen analyzer (AEI Technologies, Pittsburgh, PA,
USA) that was connected to a Macintosh computer.
O2 was measured
[using equation 4a of Withers
(1977
)] for 3 h, recorded
every 5 s, and data was analyzed using customized software (WartHog Systems,
M. A. Chappell, Riverside, CA, USA; custom software available at
warthog.ucr.edu).
Each mouse was sampled for approximately 2.5 h. RMR was calculated as the
lowest 5-min interval of
O2.
Organ morphology and body fat measures
Between 08.30 h and 11.30 h on day 50 PI, mice were anesthetized by
intraperitoneal injection of 0.07 ml sodium pentobarbital (65 mg
ml-1). The small intenstine was removed (see below) while mice were
alive. Mice were euthanized by cutting the diaphragm and then the stomach,
cecum, large intestine, heart, liver, spleen, pancreas and associated
mesentery (for another experiment), kidneys and lungs were removed. Excess fat
and connective tissue were trimmed from each organ and returned to the
carcass. For the stomach, cecum and large intestine, each organ was weighed
with and without contents (flushed with mammalian Ringer's solution; for
composition, see Karasov and Diamond,
1983). The dry mass of the organs and the carcass after drying at
55-60°C (for 2 days for organs and for 2 weeks for the carcass) was
measured.
The dried carcass was ground and lipids were extracted using petroleum
ether (Goldfische apparatus; Labconc, Kansas
City, MD, USA), and absolute fat mass and fat mass as a percentage of body
mass were calculated. The fat content of all organs, except the small
intestine, were measured together. Organ fat was removed by soaking organs in
10 ml aliquots of petroleum ether for six 24-h periods (pouring off ether at
the end of 24 h and replacing it with fresh ether), and absolute fat mass and
percentage organ fat were calculated. Total absolute fat mass was the sum of
the masses of body and organ fat. Lean mass was calculated as initial whole
body mass minus total absolute fat mass.
Small intestine morphology and glucose-uptake measurements
While the mouse was anesthetized, the small intestine was rinsed in
situ with cold Ringer's solution, then excised and placed in cold
oxygenated Ringer's solution (bubbled with 5% CO2:95% O2
at 2-3 l min-1). The small intestine was cut into three regions of
equal length (proximal, mid and distal), the wet mass of each region was
measured and the three masses were added together to determine the total
intestinal mass (corrected for mass of the parasites, as described below).
Mucosal/submucosal tissue (hereafter called `mucosa') was separated from
muscularis/serosal tissue (hereafter called `serosa') for two 1.5-cm sleeves
per region (Diamond and Karasov,
1984). The dry mass:wet mass ratio was calculated for each sleeve,
and the average of these ratios was used to calculate mucosal and serosal wet
mass and dry mass of the entire small intestine
(Diamond and Karasov, 1984
;
Hammond and Diamond, 1992
).
For parasitized mice, all adult H. polygyrus from the small intestine
during rinsing, from intestinal sleeves used for mucosa/serosa measures and
from remaining tissue were collected and counted
(Kristan and Hammond, 2001
).
The number of worms on the sleeves used for glucose uptake was assumed to be
the same as for adjacent sleeves used for mucosal scrapes, and this number was
added to the number of worms directly counted to determine the final infection
intensity. The wet mass of H. polygyrus (0.0002 g x the number
of worms; Kristan and Hammond,
2001
) was subtracted from the wet mass of the small intestine
prior to the calculation of small intestine dry mass used in analyses. When
each intestinal region was examined separately, parasite mass was subtracted
only from the mass of the proximal region, because adult parasites occupy that
portion of the small intestine almost exclusively
(Bansemir and Sukhdeo,
1996
).
The everted sleeve technique was used to measure carrier-mediated (sodium
glucose transporter I, SGLT1) glucose uptake by the small intestine
(Diamond and Karasov, 1984;
Karasov and Diamond, 1983
).
Each region of the small intestine was everted so that the mucosa faced
outwards. From each region, four 1.5-cm-long sleeves immediately adjacent to
each other were cut: two sleeves for measuring relative mucosal and serosal
mass, as described above, and two sleeves for measuring glucose uptake. To
measure carrier-mediated (SGLT1) glucose uptake, everted sleeves were mounted
on stainless steel rods, incubated for 2 min in 36°C Ringer's solution
containing 50 mmol l-1 D-glucose and trace amounts of
[14C]D-glucose. The incubating solution also contained trace
amounts of [3H]L-glucose, which was used to correct for glucose in
the adherent mucosal fluid and for passive uptake of D-glucose. The amount of
isotope taken up by each sleeve was measured using liquid scintillation
counting (LS 6500 scintillation system, Beckman, Fullerton, CA, USA) to
determine glucose-uptake rates (mmol day-1 g wet mucosal
tissue-1). The average uptake rate of the two sleeves from each
region was then calculated. The glucose-uptake capacity for each region of the
small intestine was calculated by multiplying the mean glucose-uptake rate by
the wet mucosal mass (g) of the region. The products of each region were added
together to determine total glucose-uptake capacity for the entire small
intestine.
Reproductive-output experiment
Litter production
Pairs were checked daily, beginning at 18 days post-mating, and seven
variables were recorded: (1) the date that each litter was produced, (2) the
number of pups on the day the litter was born (natal litter size), (3)
inter-litter intervals, calculated as the number of days between the birth of
one litter and the birth of the next, (4) whether or not a litter was
successfully weaned (litter success was designated as either `1', if at least
one pup survived to 20 days old, or `0', if no pups survived to 20 days old),
(5) the number of pups that died (either eaten by parents or found dead)
between the first observation on the day of birth and weaning at 20 days old,
(6) the number of pups weaned in each litter (weaning litter size) and (7) the
sex ratio at weaning.
Litter and individual pup masses
Litters were weighed and pups were counted on days 5, 10, 15 and 20 after
birth. On day 20 after birth, pups were removed from the parental cage and
each pup was individually weighed and sexed. Pups from the second litter were
checked for parasites to determine if pups contracted the infection from their
mother.
Statistics
Lactation experiment
This experiment consists of two independent [parasite infection
(parasitized, unparasitized) and reproductive status (lactating, virgin)] and
numerous dependent variables (food intake, digestive efficiency, body mass,
small intestine morphological variables, organ masses, body fat,
glucose-uptake rate and capacity, and RMR). First, a multivariate analysis of
variance (MANOVA), which tested for significant differences between treatments
for all dependent variables together, was used. Because this MANOVA was
significant (P<0.0001), the results from subsequent independent
analyses of variance (ANOVAs) were used to determine which treatment and which
dependent variables were statistically significant. For RMR data, because
virgin mice had smaller body mass than lactating mice, analysis of covariance
(ANCOVA), with whole body mass as a covariate, was used. Also, because
parasitized mice had greater lean body mass than unparasitized mice, and
lactating mice had a greater lean mass than virgin mice, ANCOVA with lean mass
as the covariate was also used for RMR data.
Reproductive-output experiment
For this experiment, repeated measures ANOVA (RM ANOVA; Wilk's Lambda) was
used to examine the effects of maternal parasite infection on reproductive
output (inter-litter interval, success of weaning a litter, number of pups
lost from birth to weaning, and sex ratio). Individual pup mass at weaning was
analyzed with a nested ANCOVA (pups nested by maternal pair ID; independent
variables: pup sex and maternal parasite treatment; covariates: parity and
litter size, with factors tested against the between-pairs error term). The
time to first litter production was tested with a t-test comparing
parasitized pairs with unparasitized pairs. Regression was used to test for
relationships between the first litter size and the subsequent inter-litter
interval, between first litter size and second litter size, and for food
intake and litter size separately for parasitized and unparasitized mice.
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Results |
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Body mass and composition and organ masses
Whole body mass was 18% heavier for lactating mice than for virgin mice
(F1,32=39.9, P<0.0001) and 8% heavier for
parasitized mice than for unparasitized mice (F1,32=4.3,
P=0.046; Fig. 1).
Post-hoc analysis showed that the effect of parasites on whole body
mass was significant for virgin but not for lactating mice. Total body fat did
not differ with parasite treatment, but lean mass of parasitized mice was 10%
heavier than for unparasitized mice (F1,32=4.6,
P=0.041). Total body fat was 53% less for lactating than for virgin
mice (F1,29=131.4, P<0.0001), and lean mass
was 36% more for lactating than for virgin mice
(F1,29=23.1, P<0.0001). Percentage body fat
was similar for parasitized and unparasitized mice (18%) but was 55% less for
lactating than for virgin mice (11% and 25%, respectively;
F1,30=253.1, P<0.0001). Because body mass
differed with both reproductive and parasite treatments, I used analysis of
covariance (ANCOVA) to determine which dependent variables were affected. Body
mass was a significant covariate for mass of liver, kidney, spleen, heart,
lung, mucosa and small intestine, and for food intake, RMR and total
glucose-uptake capacity. Therefore, I present least-squares means ± 1
S.E.M. for these variables. Body mass was not a significant covariate for mass
of stomach, large intestine, cecum or serosa or for percentage mucosa, small
intestine length, digestive efficiency or glucose-uptake rate, so I present
the arithmetic mean ± 1 S.E.M. for these variables.
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I used data for organ dry masses (including fat content) to examine the effects of each treatment on organ mass. Parasitized mice had heavier cecae (22%) and spleens (30%) but lighter stomachs (8%) than unparasitized mice (Table 1). Lactating mice had heavier stomachs (47%), cecae (47%), large intestines (60%), kidneys (8%), liver (22%) and hearts (22%), but lighter spleens (28%) and marginally lighter lungs (7%) than virgin mice (Table 1). Small intestine length was 5% longer for parasitized compared with unparasitized mice (F1,32=5.5, P=0.026) and 11% longer for lactating compared with virgin mice (F1,32=21.6, P<0.0001; Fig. 2). Similarly, small intestine dry mass (after adjusting for body mass and mass of the parasites) was 24% heavier for parasitized than unparasitized mice (F1,29=17.8, P<0.0001) and 38% heavier for lactating compared with virgin mice (F1,29=20.9, P<0.0001; Fig. 2). Dry mass per unit length of small intestine yielded qualitatively the same results as absolute dry mass, so I used absolute dry mass when examining each region of the small intestine.
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Parasitized mice had 18% more mucosal and 61% more serosal tissue than did unparasitized mice (F1,29=8.4, P=0.007 and F1,30=28.8, P<0.0001, respectively; Fig. 2). Because parasitized mice had a disproportionate increase in serosal compared with mucosal tissue, the percentage mucosa was 6% less in parasitized than unparasitized mice (F1,30=11.5, P=0.002). Mucosal and serosal dry mass both increased by approximately 45% with lactation (F1,29=19.5, P<0.0001 and F1,30=18.3, P<0.0001, respectively), but percentage mucosal mass was unchanged. When examining intestinal regions separately, parasitized mice had 38% heavier proximal and 15% heavier mid regions (F1,31=16.7, P<0.0001 and F1,31=9.2, P=0.005, respectively) but had a similar mass for the distal region compared with those of unparasitized mice (Fig. 3).
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Lactating mice had 45-65% heavier masses of all three small intestine regions compared with virgin mice (proximal: F1,31=31.1, P<0.0001; mid: F1,31=35.2, P<0.0001; distal: F1,31=20.3, P<0.0001; Fig. 3). There were no significant interactions among treatments for mass of any intestinal region. Changes in the serosal and mucosal components of the regional masses also varied with treatment. Mucosal mass was heavier for lactating compared with virgin mice for each region (proximal by 68%: F1,30=35.8, P<0.0001; mid by 81%: F1,30=28.6, P<0.0001; distal by 37%: F1,30=5.2, P=0.029), but parasite treatment did not affect mucosal mass of any region. For the parasite treatment, serosal mass increased by 219% in the proximal region (F1,30=117.4, P<0.0001), 39% in the mid region (F1,30=6.9, P=0.014) and 8% in the distal region (P>0.05). There were no significant interactions among treatments for components of regional masses.
Food intake and digestive efficiency
Parasitism had no effect on food intake, and digestive efficiency was
79±0.4% for all mice regardless of treatment. After adjusting for body
size, females at peak lactation (15 days post-partum) ate 174% more food than
did virgin mice (virgin, parasitized=5.98±0.79 g day-1;
virgin, unparasitized=6.17±0.74 g day-1; lactating,
parasitized=16.29±0.54 g day-1, lactating,
unparasitized=16.98±0.49 g day-1;
F1,29=160.8, P<0.0001). Food intake increased
with larger litter sizes for unparasitized mice (r2=0.364,
P=0.049, N=11) and marginally for parasitized mice
(r2=0.360, P=0.051, N=11;
Fig. 4).
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Resting metabolic rate
Of the 22 lactating mice measured, four (three unparasitized and one
parasitized) did not attain RMR conditions (i.e. did not show a lowered,
steady rate of oxygen consumption) within 3 h of measuring and were thus
excluded from analyses. Because whole body mass and lean body mass increased
with infection and lactation, I examined the relationship among both mass
variables and RMR. There was a significant relationship for whole body mass
(r2=0.67, P<0.0001, N=32) and lean
body mass (r2=0.64, P<0.0001, N=32)
with RMR (Fig. 5). RMR did not
change with parasite infection when corrected for either whole body mass or
lean body mass (ANCOVA). RMR was 27% greater for lactating compared with
virgin mice (F1,27=4.9, P=0.036) when whole body
mass was used as the covariate (least-square-adjusted mean ± 1 S.E.M.:
virgin, parasitized=35.7±4.4 kJ day-1; virgin,
unparasitized=36.1±3.3 kJ day-1; lactating,
parasitized=47.4±3.1 kJ day-1; lactating,
unparasitized=43.8±3.2 kJ day-1), but RMR did not differ
between lactating and virgin mice when lean body mass was used as the
covariate. For lactating mice, RMR was not affected by litter size or litter
mass.
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Glucose transport
Intestinal glucose-transport rate was normalized to wet mucosal mass of the
small intestine. Average mass-specific glucose-uptake rate (mmol
g-1 day-1) was 17% lower for parasitized than for
unparasitized mice (F1,30=5.3, P=0.028) but did
not differ between lactating and virgin mice
(Fig. 6). However, because of
increases in mucosal mass with parasitism, total glucose-uptake capacity (mmol
day-1) summed for the entire small intestine (adjusted to whole
body mass) did not differ between parasitized and unparasitized mice
(Fig. 7). There was no
significant difference in total glucose-transport capacity between lactating
and virgin mice.
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I next examined each region separately to determine if parasites had only a localized effect in the proximal region and to determine if lactation affected the small intestine uniformly. Glucose-transport rate was 28% greater for parasitized than unparasitized mice in the proximal region (F1,30=7.9, P=0.009), but there was no effect of parasite infection on glucose-transport rate of the mid or distal regions and no effect of lactation for any region (Fig. 6). There was a significant interaction for glucose-transport rate in the mid and distal regions (F1,30=7.3, P=0.011 and F1,30=5.4, P=0.027, respectively) because, for both regions, unparasitized lactating mice had lower glucose-transport rates than virgins but parasitized lactating mice had higher glucose-transport rates than virgins. Parasites had marginal effects on total glucose-transport capacity in the proximal (a 28% decrease; F1,29=3.5, P=0.071) and distal regions (a 24% increase; F1,30=3.6, P=0.068), and lactating mice had a 78% greater glucose-transport capacity in the distal region (F1,30=24.9, P<0.0001) but no effect on other small intestine regions (Fig. 7). There was a significant interaction among treatments for the mid region because, when mice were parasitized, lactating mice had a greater glucose-transport capacity than virgin mice but the opposite was true for unparasitized mice (F1,29=6.1, P=0.019).
Reproductive-output experiment
One female that was given parasites cleared the infection prior to
producing her first litter, otherwise all infected females (N=18) had
a mature parasite infection while producing at least one litter. The male from
one pair became infected, but this pair was not significantly different from
other pairs with uninfected males for any measured variable and so was
included in analyses. None of the pups checked for H. polygyrus that
were born to parasitized mothers were infected at weaning.
Litter production and success
Numbers of pairs included in repeated measures analyses varied because not
all data were recorded for all pairs for every litter, and pairs produced
different numbers of litters (Table
2). Maternal parasite infection did not affect the time to first
litter production (N=18 parasitized, 15 unparasitized) or any of the
variables in Table 2. Numbers
of litters produced by parasitized pairs ranged from 1 to 8 (sample size in
parentheses): one litter (2), two litters (2), three litters (3), four litters
(3), five litters (3), seven litters (3) and eight litters (2). Numbers of
litters produced by unparasitized pairs ranged from 2 to 10: two litters (1),
three litters (1), six litters (1), seven litters (5), eight litters (2), nine
litters (3) and 10 litters (1). Natal litter size decreased with increasing
parity, starting at litter number 5 (F5,10=4.1,
P=0.028; Table 2) for
both parasitized and unparasitized pairs. When the time to first litter
production was included in the inter-litter interval analysis, mice produced
their first litter more quickly than they produced subsequent litters
(F5,12=7.4, P=0.002;
Table 2) but there were no
other differences in inter-litter intervals with parity.
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Pup mass
A total of 1243 pups were measured, of which 1091 were sexed and used in
the analysis. The covariates litter size and parity were significant
(F1,22=5.7, P=0.027 and
F1,22=4.9, P=0.037, respectively). Pups from
large litters were smaller than pups from small litters for both sexes
combined (Fig. 8A,B) and for
males and females separately (males: F1,24=7.6,
P=0.011; females: F1,24=12.4, P=0.002;
Fig. 8A,B). Pup mass increased
with increasing parity, up to litter number 5 for all pups combined
(Fig. 9), which was due to the
effects of males (F1,24=5.3, P=0.030) but not
females.
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After accounting for effects of litter size and parity, parasitized mothers had pups that were 4% smaller at weaning (20 days after birth) compared with pups from unparasitized mothers (F1,22=4.4, P=0.049; Fig. 8A,B), and male pups were 2% larger than female pups (F1,22=6.5, P=0.018; least-square-adjusted mean ± 1 S.E.M.: male pups, parasitized mother=8.8±0.1 g; male pups, unparasitized mother=9.1±0.1 g; female pups, parasitized mother=8.6±0.1 g; female pups, unparasitized mother=9.0±0.1 g). As a post-hoc analysis, I examined the effect of maternal parasite status for male and female pups separately. Parasitized females produced 6% smaller female pups than did unparasitized mothers (F1,24=7.0, P=0.014), but maternal parasite status did not affect male pup mass at weaning (F1,24=1.9, P=0.185).
To examine whether pups from parasitized mothers were smaller at ages 5 days, 10 days and 15 days, I calculated average pup mass (litter mass/litter size) for the first litter produced by mated pairs (parasitized mothers, N=15; unparasitized mothers, N=13). Average pup mass did not differ with maternal parasite treatment for pups at ages 5 days, 10 days or 15 days (F1,26=3.0, P=0.095) using an RM ANOVA. However, the percentage differences in pup mass from parasitized and unparasitized mothers increased from day 5 (6%) to day 10 (7%) to day 15 (9%; day 5, parasitized mother: 2.95±0.12 g; day 5, unparasitized mother: 3.14±0.13 g; day 10, parasitized mother: 5.27±0.18 g; day 10, unparasitized mother: 5.65±0.19 g; day 15, parasitized mother: 6.91±0.24 g; day 15, unparasitized mother: 7.61±0.26 g).
Litter size and inter-litter intervals
Based on the first and second litters produced, pairs with larger litters
had a longer subsequent inter-litter interval than did pairs with smaller
litters for both parasitized (r2=0.58, P=0.004,
N=12) and unparasitized females (r2=0.41,
P=0.019, N=13). Current litter size was not affected by
previous litter size for unparasitized mice, but parasitized mice that
produced large first litters had small second litters, or, conversely,
parasitized mice that produced small first litters had large second litters
(r2=0.42, P=0.022, N=12).
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Discussion |
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Parasite infection during lactation
A change in resource allocation with parasitism, as evidenced by a change
in body composition, suggests that infection with H. polygyrus
affects energy use in the laboratory mouse despite no changes in energy input
(food intake did not vary with parasite infection). Part of the change in body
composition with parasitism resulted from an increase in mucosal mass of the
small intestine, which is important because the mucosal layer is responsible
for nutrient digestion and absorption. Unlike previous studies (Kristan and
Hammond, 2000,
2001
), parasitized mice in
this study were able to attain similar total glucose-transport capacity,
despite a decreased rate of glucose transport per gram of tissue, by
increasing the total mass of mucosal tissue. One explanation for these
contradictory results may be that mice in this study were parasitized for
approximately 26 days longer than in previous studies (Kristan and Hammond,
2000
,
2001
), and the potential
negative effects of larval-stage parasites on mucosal tissue function may have
been overcome. For example, if immune responses to larval parasites affect the
function of small intestine tissue [perhaps by the proliferation of cells in
the small intestine (Symons,
1965
) yielding an accumulation of immature enterocytes rather than
functional mucosal tissue] then the more time that has passed since the larval
stages, the less H. polygyrus should impact on total glucose
acquisition. As in previous studies (Kristan and Hammond,
2000
,
2001
), the effects of H.
polygyrus on small intestine function reached beyond the site of worm
occupation to other regions of the small intestine. This is likely to be an
indirect effect of parasitism, possibly resulting from changes in the nutrient
density of the ingesta, which results in `nutrient spilling' into more distal
parts of the small intestine that will then change the capacity of these
regions for nutrient uptake.
In contrast to previous studies (Kristan and Hammond,
2000,
2001
), after accounting for
mass, resting metabolism did not change with parasite infection. This
difference in response to parasitism again may reflect different experimental
protocols. In previous work (Kristan and Hammond,
2000
,
2001
), mice were parasitized
for 23 days prior to metabolism measures, whereas in the present study mice
were infected on average for 49 days. It is well documented that H.
polygyrus elicits an immune response by the host during larval stages
(e.g. Monroy and Enriquez,
1992
). If this immune response is partly responsible for the
increased resting metabolism of mice then the more time that has passed since
the larval stages of the infection, the more likely it is that resting
metabolism will return to levels similar to those of uninfected mice.
Differences between the present study and our previous work suggest that at
least part of the increased resting metabolism shown with parasitism may
reflect the time-course of the infection and the related immune response to
H. polygyrus by M. musculus.
Energy acquisition and metabolism during lactation
Both energy intake and allocation changed with lactation and, for lactating
mice, larger litter sizes explained approximately 36% of the variation in
increased food intake for both parasitized and unparasitized mice
(Fig. 4). As with parasitism,
lactation was associated with increases in mucosal mass of the small
intestine. Similar to previous studies (Hammond et al.,
1994,
1996a
,b
),
maximal glucose-transport rate did not differ between lactating and virgin
mice. However, in contrast to previous studies, lactating mice in my
experiment did not have greater total glucose-transport capacity than virgin
mice, despite their increased small intestine mucosal mass. This discrepancy
may reflect differences in calculations of glucose-transport capacity (using
mucosal mass versus whole small intestine mass), mass relationships
(changes in intestine mass with lactation) or mammary pressure (amount of
suckling per teat). For example, one previous study showed that body mass was
a significant covariate with total glucose-transport capacity
(Hammond et al., 1996b
),
whereby capacity did not differ between virgins and lactating mice having five
teats but only differed between virgins and lactating mice with 10 teats
(after experimental manipulation of teat number and litter sizes). In two
other studies (Hammond et al.,
1994
,
1996a
), body mass was not a
significant covariate with glucose-transport capacity; therefore, body mass
effects on glucose-uptake capacity remain somewhat elusive.
After accounting for changes in whole body mass, lactating mice had a greater resting metabolism than virgin mice, which was partially due to the increased lean mass (metabolically active tissue) because, when the effects of lean mass were removed (ANCOVA with lean mass as the covariate), there were no effects of lactation on resting metabolism. Regardless of the cause of increased metabolism during lactation, this response must be fueled either with increased food intake (as seen in laboratory mice) or possibly by decreased activity or catabolism of body fat stores, which may occur in nature if extra food is unavailable.
Response to simultaneous demands
In this study, physiological or morphological responses to one demand were
not affected by the presence of a second demand. This is similar to the
finding that simultaneous demands of cold exposure and H. polygyrus
did not interact with each other (Kristan
and Hammond, 2000) but is in contrast to the finding that
simultaneous demands of caloric restriction and H. polygyrus did
significantly interact (Kristan and
Hammond, 2001
). Whether demands interact
(Carlomagno et al., 1987
;
Kristan and Hammond, 2001
) or
remain independent (Kristan and Hammond,
2000
; the present study) varies with combinations of demands
presented to the mice; therefore, general conclusions about effects of
simultaneous demands on physiological and morphological responses are not
forthcoming.
It is important to note that some simultaneous demands elicit similar responses (e.g. both cold exposure and parasitism generally result in greater organ sizes and resting metabolism) whereas others elicit contradictory responses (e.g. short-term caloric restriction results in decreased organ masses and resting metabolism, and parasites elicit increased organ masses and resting metabolism). When multiple demands elicit responses that occur in the same direction (either increases or decreases), the animal may be able to respond to each demand relatively independently, but, when demands require conflicting responses by the animal, a response to one demand may compromise an animal's ability to respond to the second demand.
Reproductive output and parasitism
Despite changes in morphology and physiology that occurred during parasite
infection, parasitized mice showed no change in reproductive output except for
differences in offspring mass and effects of current litter size on subsequent
litter size. I found that female pup mass at weaning, a potential measure of
pup quality as related to adult reproductive performance
(Solomon, 1994), was
significantly affected by maternal parasite infection. Interestingly, this was
not true for male offspring.
Sex-biased effects
Differential investment in male versus female offspring between
reproductive events has been examined both theoretically and empirically (e.g.
Trivers and Willard, 1973;
Clutton-Brock, 1991
); however,
differential investment in male and female offspring within a reproductive
event is not so well studied. Differential investment in males versus
females within a reproductive event may reflect differences in maternal
behavior. Helminth parasite infection can affect maternal behavior as shown by
female Sprague-Dawley rats (Rattus norwegicus), which, when infected
with a tapeworm, retrieved their offspring more quickly than did unparasitized
rats (Willis and Poulin,
1999
). If maternal behavior of laboratory mice infected with
H. polygyrus differs towards female and male offspring (e.g. access
to teats, brooding behavior) then differential mass at weaning may result.
Moreover, if parasitized mothers cannot produce pups of the same mass as
unparasitized mothers then there may be selection for sex-biased investment in
offspring. Given that male mice must compete for mates and thereby potentially
have more variable reproductive success than do female mice, it would be
predicted that mothers invest more in sons than in daughters
(Willson and Pianka, 1963
;
Trivers and Willard, 1973
;
Clutton-Brock, 1991
) under
certain circumstances. In this experiment, parasitized mothers had male
offspring of similar mass to those of unparasitized mothers (i.e. no effect of
parasites on male offspring mass) but had smaller female offspring (i.e.
decreased investment in female offspring when parasitized). Alternatively,
sex-biased effects of maternal parasite infection on offspring mass may
reflect differences in offspring behavior. For example, adult mice can detect
the presence of H. polygyrus in a conspecific based on odor cues in
the urine (Kavaliers and Colwell,
1995
). It is possible that male and female pups differentially
detect or respond to these odor cues in maternal urine, which may affect how
pups interact with their mother. Sex-biased parental investment within a
reproductive event warrants further investigation in general for this and
other hostparasite systems.
Current versus future reproduction
In contrast to unparasitized females, infected females that produced large
first litters had relatively smaller second litters, which implies that the
cost of producing a large litter may be more for parasitized females than for
unparasitized females. Importantly, parasitized females that produced small
first litters tended to have larger second litters. A shift in optimal
allocation of energy between current and future offspring associated with
parasitism can occur (Richner and Tripet,
1999), and further exploration of relative changes in reproductive
effort over the course of numerous reproductive events will provide valuable
insight into how parasites may influence this life-history parameter.
Conclusions
This study adds to the body of literature showing that simultaneous demands
that include parasitism can either remain independent of each other
(Kristan and Hammond, 2000) or
interact with each other (Carlomagno et
al., 1987
; Banerjee et al.,
1999
; Kristan and Hammond,
2001
) depending on the combination of demands presented. Parasite
infection affected host morphology and physiology, the size of female
offspring at weaning, and the relationship between litter sizes of two
adjacent reproductive events but not other measures of reproductive output.
Future studies to determine why female pups from parasitized mice are smaller
(e.g. due to maternal care, milk output, milk quality, pup behavior), whether
female pups show compensatory growth and whether pup reproduction at adulthood
is ultimately affected will help elucidate whether H. polygyrus could
have important evolutionary consequences to its host.
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