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Microcalorimetric investigations of the energy metabolism of some reptiles
ThermochzmzcaActa,
94(1985)
161
161-167
ElsevierSciencePublishersB.V.. Amsterdam
MICROCALORIMETRIC
INVESTIGATIONS
- Printed
OF THE ENERGY METABOLISM
I.H.D. LAMPRECHT' and F.-R. MATUSCHKA' 1 Institut fiir Biophysik, Freie Universitat D-1000 2
Berlin
Institut
in The Netherlands
Berlin,
OF SOME REPTILES
Thielallee
63,
33 (Germany)
fur Angewandte
Haderslebener
StraBe
Zoologie,
9, D-1000
Freie Universitat
Berlin,
Berlin 41 (Germany)
ABSTRACT Energy metabolism of 16 lacertide lizards and 12 snakes was investigated by Heat production is compared with oxygen means of two Calvet microcalorimeters. consumption, rendering a value near to the theoretical value (19.3 J/ml oxygen) predicted for food mainly composed of lipids and proteins. Electrical stimulation of some of the experimental lizards and snakes showed burst-off behaviour and a strong increase in anaerobic metabolism with a consequent compensation of the oxygen debt. The experiments are discussed in connection with the usual indirect calorimetry.
INTRODUCTION In recent years lizards tiles
no direct
and snakes.
All knowledge
has been derived
graphy)
of oxygen
piratory
calorimetric
of indirect
known to calculate
The aim of the present thermic
reptiles
under complete Reptiles
ano&iosis
(ref.4, ref.5).
As direct
heat production, the animals cal tests
ref.2).
is that the form of metabolism
must be
In
it is an ideal method
animal's
the ability
time was of special
to anaerobic
under stress without
the individual
this context
calorimetry
heat production
metabolism
interest
while escaping
to investigate
weight
of reptiles
is not bound to gas exchange
sacrificing
of poikilo-
anaerobic
(ref.3).
or hunting but detects
metabolism
them, as is necessary
and
to live
in
for biochemi-
(ref.6).
Therefore, aerobic
(ref.1,
resin
from gas exchanges.
for a certain
are able to switch
of repor polaro-
concentration
for several minutes
on the species,
temperature.
on
air) of so-called
the lactate
study was to investigate
depending
the environmental
stressed
metabolism
(Warburg manometry
(in the inlet and outlet
calorimetry
heat losses
have been performed
and anaerobic
measurements
face masks or by determining
blood and body tissue of animals The disadvantage
about aerobic
from respiratory
concentration
chambers,
experiments
it seemed worthwhile
metabolism
in lizards
to measure
heat production
of the Calvet type (ref.7). 00406031/85/$03.30
of aerobic
and snakes with a usual isoperibolic
0 1985 Elsevier Science Publishers
B.V.
and an-
calorimeter
162 METHODS
AND MATERIALS
Animals Calorimetric
experiments
were performed
on the following
lizards
- 4 Milos wall lizards (Podarcis milensis) - 2 Common wall lizards
(Podarcis muralis)
- 3 Sand lizards
(Lacerta agilis) ~lizards (Lacerta lepida) --
- 3 Ocellated
- 3 Libanon wall -1
lizards
(Lacerta laevis) ~(Lacerta viridis) ___-
Green lizard
and the following - 1 Smooth
snakes
snake
(Coronella
- 1 Balkan whip snake -10 Aesculapian The weight
(Coluber
snakes
of the animals
gemonensis)
(Elaphe longissima). ranged between
ratory reared and increased ing maintenance
austriaca)
their weight
have been reported
4 and 18 g. All individuals during
previously
the experiments.
(ref.8,
were
labo-
Details concern-
ref.9).
Instrumentation Heat production of 100 ml vessels duction
was measured at changing
in two Calvet microcalorimeters
temperatures
rates of several mW and fivefold
the recording
system
(Micrograph
ever, it had to be increased power-time
curves
production,
the calorimetric
signal
The calorimetric
of
was set to 2mV. How-
temperatures. integrated
folded with the instrumental
vessels
The obtained
to find the mean heat
time constant
were open to air or hermetically
oxygen
determination
in the air. Without continuously
BD5; KIPP & ZONEN/Delft)
at low environmental
heat pro-
rates the sensitivity
to 'desmeare"
(ref.10).
nected to a polarographic simultaneous
higher maximum
(P-t curves) were mechanically
in some cases
(SETARAMILyon)
from 18 to 35°C. With mean
sensor
(Monitor System,
of heat production
larger disturbances
by means of a peristaltic
sealed and then con-
BECKMAN/Irvine)
and decrease
of oxygen
for a
concentration
the air in the vessel could be exchanged pump or discontinuously
by a larger sy-
ringe. The animals calorimetric high voltages
were electrically
vessel.
an electrode
cream
smeared
on the animals.
voltage
of 30 V was sufficient
to keep it moving. "appropriate" electrodes.
stimulated
In oder to facilitate
(HELLIGE/Freiburg)
to cause an explosive
of the animal
extending
into the
and to avoid dangerous
as used for EEG and ECG was
With the help of the electrode
Prior to stimulation
position
by two electrodes the experiments
the voltmeter
cream a stimulating
movement
pulsed
of the animal and
was used to monitor
by means of the resistance
an
between the two
163 RESULTS Figure 1 exhibits and its "desmearing"
the P-t curve of a Milos wall lizard by the Tian equation
(Podarcis milensis)
(ref.10).
t P/mW
b
80
60
40
20
0
t/min
Fig. 1. Power-time curve (strong line) of a Milos wall lizard (Podarcis milensis) and the original signal (thin line) calculated by means of the -equation (see text). There are periods of high activity can be determined. zards and snakes
and of rest from which
included
in these
investigations
stimulation
experiments.
and minimum
rates of heat production
has recently Table
the basal metabolism
Table 1 shows the mean rates of heat production
A detailed
been reported
(ref.8,
analysis
except
of the result together
and the correlation
for all li-
those animals
to oxygen
used for
with maximum consumption
ref.9).
1
Mean weights m(g) and mean specific rates of heat production p (mW/g) with standard deviation (mW/g) at 25'C for the different lizards and snakes in these investigations (n = number of experiments)
P.milensis P.muralis L.agilis C.austriaca C.gemonensis t.longissima
108 26 50
4.18 t 0.24 2.05 f 0.13 7.91 * 0.44
2.01 f 0.43 2.56 f 1.00 1.46 t 0.12
19 18 49
7.41 * 0.45 9.20 f 0.29 14.06 f 3.79
0.51 * 0.29 0.59 t 0.42 0.73 t 0.26
164
Fig. 2. Power-time curve (structured line) and change of oxygen concentration with time for an Aesculapian snake (Elaphe longissima) at 25°C. Figure 2 compares crease
the calorimetric
in oxygen concentration
longissima)
at 25'C. The oxygen
as much information
naturally
bic degradation
of glucose
are less structured
consumption
occuring
lizards
from the vessel
does not offer
Fig. 2 shows that the
are mainly
run by anaero-
P-t curves of snakes
because of the lower locomotor for many
down to an oxygen
activi-
hours.
concentration
mainly
coefficient
to the expected
of lipids and proteins.
found values
of anaerobic
In the stimulation
sharply
fermentation experiments
After thermal Usually
if the oxygen concentration
equilibration
At very low oxygen pointing
to energy metabolism
the two-electrode
the resistance
with the electrodes.
for a
concentrations
to a predominant
con-
(ref.9).
vessel allowed
to those obtained between
it is in the MOhm range and dropped
the animal was in contact
the limits of
value of 19.3 J/ml oxygen
increase,
are similar
decreased
of 18.6 f 3.2 J/ml oxygen
and 20.4 & 5.8 J/ml for snakes; within
to move around and the P-t curves
determined.
signal. Moreover,
keep their normal metabolism
for lizards
the experimentally
trodes.
snake (Elaphe
In the present study the animals became more active and ap-
error these figures correspond
tribution
for an Aesculapian
the snakes did not move
below 16%. In most cases an oxycaloric
food composed
line) with the de-
as an integral method
down to lactic acid. Usually,
temperature
parently tried to escape
was calculated
(structured
bursts of activity
than those of lizards
ties. At their prefered Lacertid
(smooth slope)
as the calorimetric
non-stimulated,
of 16% (ref.11).
P-t curve
the animals
without
elec-
the electrodes
was
to some IO kOhms when
This was the moment
the voltage
165
. ..-12.5
i 0
20
60
10
80
t/h
Fig. 3. Simulation of an Ocellated lizard (Lacerta lepida) at 30°C for 30 s with 30 V. The area between the P-t curve and the extrapolated heat production (dotted line) corresponds to 22.9 J, the maximum deviation of the oxygen slope after stimulation to 1.1 ml oxygen. was switched response
on for 30 s leading
is seen immediately
rographic
to the burst of activity
in strong oscillations
signal due to the vehement
the slopes of heat production the thermal
inertia
of the instrument
nal of a short pulsed
heat production
to the level prior to stimulation. literature
consumption
20.8 J/ml oxygen
is specific
If the duration additional observed.
Figure 3 exhibits
is smeared
consumption
to the typical
(steepness
the obtained
in the
of slope) oxygen
value of
Further
to the burst-off
sig-
decline
described
this additional
of glucose.
Due to
exponential
to observations
by stimulation,
contributions
information
metabolism
will
(ref.12). of the stimulation
heat production Sometimes,
the animals
in oxygen
for the metabolism
and anaerobic
be given elsewhere
heat output
with an approximately
The
and pola-
after stimulation.
of the oxygen debt. Comparing
with the heat production
about the aerobic
of the animal.
consumption
In contrast
there is a quick response
and a slow compensation
movement
and oxygen
of the reptiles.
of the calorimetric
these longer
find a position
is increased,
by the burst-off lasting
in which
a linear dependence
behaviour
stimulations
on this duration are without
of the can be
effect
because
they touch only one electrode.
DISCUSSION Except (ref.13)
for one very early calorimetric no direct calorimetric
experiments
investigation
on a lacertid
lizdrd
are found in the literature.
There-
166 fore, it seemed
interesting
energy metabolism
calorimetrically
with those obtained
vestigations
concern
experiments.
In the present
which would
to compare
reptiles
from respiratory
that were much heavier
study it was necessary
not only fit into the calorimetric
find space to move around and have enough crease
in oxygen
concentration.
bolism and weight be compared;
motory
the P-t curves
activity;
taneously
when
heat production
(ref.4) to the energy output
naturally
The P-t curves exhibit dissipation
debt
bolism of the animals.
heat output.
consumption
activities
ties of snakes were As lizards lism strongly
depends
30°C (ref.8,
was observed
by temperature
meta-
to the basal meta-
heat production
under investigation
Within
due to the "temperament"
animals
temperature.
the locomotory
one species of the indiactivi-
(ref.8, ref.9).
their energy metaboIn most cases a para-
temperature activity
than the basal metabolism
and
and from
the locomotory
than those of lizards
with a flat optimum
ren-
to the total
for the lizards
for the snakes.
to poikilothermic
ref. 9). For lizards
that these
by anaerobic
activities
on the species
upon the environmental
are
and of low levels of energy
to 79% for P.muralis
found to be smaller
activity
only over a longer period oftime.
from 65% to 88%. In general
and snakes belong
bolic dependence
depends
simul-
metabolism
it can be assumed
of locomotory
differences
e.g. in E.longissima
size can
are measured
are sustained
of high activities
to 81% for C.austriaca
there are often considerable
between meta-
about the loco-
of anaerobic
The ratio of the mean to the minimum
This figure strongly
74% for C.gemonensis
fluenced
and oxygen consumption
about the contribution
from 68% for P.milensis
viduals,
render information
is compensated
periods
also
values agree quite well
(Fig. 1 and 2). The latter ones can be attributed
ders information
changes
relation
of different
(Fig.2). As the bursts of locomotory
not stimulated
bolism and that the oxygen
of 100 ml, but would
the problem of a fast de-
for animals
to the contribution
in the slopes of oxygen
occuring,
Most in-
(ref.2).
of the reptiles
they allow deductions
never reflected
vessels
the limits of error the observed
with those cited in the literature Moreover,
measurements.
to chose small specimens
air without
figures
levels of
than those used in these
By means of the allometric
(ref.1) the obtained
within
determined
slightly
above
is more strongly
indicating
in-
that at lower tem-
peratures
the animals move more often or for longer times to find a place of
preferred
temperature
As direct processes trically
(ref.8).
calorimetry
in the absence stimulated
tric response
is a suitable
of gas exchange,
burst-offs.
heat production
area between
equals
to monitor
special
These burst-offs
(Fig.3) with a subsequent
getic level. The additional polated
means
attention
metabolic
was paid to elec-
showed an immediate
exponential
decrease
the observed
a stimulated
anaerobic
calorime-
to the former ener-
P-t curve and the extra-
heat production
of 22.9 J. As it
167 was provoked within
30 s i't corresponds
to an additional
higher than the value of 22 mW prior to stimulation, values
amount
servations
to 100.1 mW/g and 2.89 mW/g,
of Cragg
proximately
The results
movements
and attains
which
the larger volume
nel to the polarographic of oxygen
consumption
cate that an immediate the chosen
experimental
Direct calorimetry metabolism
of lizards response
that it takes apits usual,
in oxygen
consumption
of the slope changes 20 min. The time
as well as to the instrumental
retards
vessel
setup in
and the small connecting
the signal.
and snakes
Parallel
chan-
investigations
in a larger container
in the oxygen consumption
conditions
(ref.9) indi-
rate is observed
under
(ref.l2),
proves to be a suitable
of poikilothermic
other methods
observed
the steepness
of the calorimetric electrode
from 7.06 mW/g
with
a new steady state after approximately reasons
specific
vessel.
Nevertheless,
lag may be due to physiological
animals
tooi in the investigation
to render information
and to avoid the sacrifice
of the animal
of the
not obtainable
for anaerobic
by
analyses.
REFERENCES 1 2 3 4 5 6 7 8
A.F. Bennett and W.R. Dawson, in C. Gans (Ed.), Biology of the reptilia. Academic Press, London, vol 5A/3, 1976, pp. 127-223. A.F. Bennett, in C. Gans (Ed.), Biology of the reptilia. Academic Press, London, vol 130/3, 1982, pp. 156-199. D.A. Belkin, Science NY 139 (1963) 492-493. A.F. Bennett and P. Licht, J. Comp. Physiol. 81 (1972) 277-288. A.F. Bennett and P. Licht, J. Comp. Physiol. 82 (1973) 351-360. A.F. Bennett, R.B. Huey and H. John-Alder, J. Comp. Physiol. B154 (1984) 113-118. E. Calvet and H. Prat, Microcalorimetrie - Applications physicochimiques et bioloaiaues. Masson et Cie, Paris, 1956.
F.R. Matuschka and I.H.D. Lamprecht, submitted 9 I.H.D. Lamprecht and F.R. Matuschka, submitted 10 W. Hemminger and G. Hoehne, Grundlagen der Kalorimetrie. 11 12
13 14
fold
agree with ob-
of L.viridis
to recover and to continue
is not as promptly
(Fig.3).
results
Fig. 3 indicates
stimulation.
in the calorimetric
of stimulation
as in heat production immediately
at maximum
40 min for the animal
non-stimulated
The corresponding
resp. These
(ref.14) who found a stimulation
at rest to 173.7 mW/g
power of 763 mW,35
Verlag Chemie, Weinheim, 1979. B. Nielsen, J. Exp. Biol. 39 (1982) 107-117. I.H.D. Lamprecht and F.R. Matuschka, submitted L. Krehl and F. Soetbeer, Arch. Ges. Physiol. 77 (1899) 611-638. P.A. Cragg, Comp. Biochem. Physiol. 60A (1978) 399-410.
94(1985)
161
161-167
ElsevierSciencePublishersB.V.. Amsterdam
MICROCALORIMETRIC
INVESTIGATIONS
- Printed
OF THE ENERGY METABOLISM
I.H.D. LAMPRECHT' and F.-R. MATUSCHKA' 1 Institut fiir Biophysik, Freie Universitat D-1000 2
Berlin
Institut
in The Netherlands
Berlin,
OF SOME REPTILES
Thielallee
63,
33 (Germany)
fur Angewandte
Haderslebener
StraBe
Zoologie,
9, D-1000
Freie Universitat
Berlin,
Berlin 41 (Germany)
ABSTRACT Energy metabolism of 16 lacertide lizards and 12 snakes was investigated by Heat production is compared with oxygen means of two Calvet microcalorimeters. consumption, rendering a value near to the theoretical value (19.3 J/ml oxygen) predicted for food mainly composed of lipids and proteins. Electrical stimulation of some of the experimental lizards and snakes showed burst-off behaviour and a strong increase in anaerobic metabolism with a consequent compensation of the oxygen debt. The experiments are discussed in connection with the usual indirect calorimetry.
INTRODUCTION In recent years lizards tiles
no direct
and snakes.
All knowledge
has been derived
graphy)
of oxygen
piratory
calorimetric
of indirect
known to calculate
The aim of the present thermic
reptiles
under complete Reptiles
ano&iosis
(ref.4, ref.5).
As direct
heat production, the animals cal tests
ref.2).
is that the form of metabolism
must be
In
it is an ideal method
animal's
the ability
time was of special
to anaerobic
under stress without
the individual
this context
calorimetry
heat production
metabolism
interest
while escaping
to investigate
weight
of reptiles
is not bound to gas exchange
sacrificing
of poikilo-
anaerobic
(ref.3).
or hunting but detects
metabolism
them, as is necessary
and
to live
in
for biochemi-
(ref.6).
Therefore, aerobic
(ref.1,
resin
from gas exchanges.
for a certain
are able to switch
of repor polaro-
concentration
for several minutes
on the species,
temperature.
on
air) of so-called
the lactate
study was to investigate
depending
the environmental
stressed
metabolism
(Warburg manometry
(in the inlet and outlet
calorimetry
heat losses
have been performed
and anaerobic
measurements
face masks or by determining
blood and body tissue of animals The disadvantage
about aerobic
from respiratory
concentration
chambers,
experiments
it seemed worthwhile
metabolism
in lizards
to measure
heat production
of the Calvet type (ref.7). 00406031/85/$03.30
of aerobic
and snakes with a usual isoperibolic
0 1985 Elsevier Science Publishers
B.V.
and an-
calorimeter
162 METHODS
AND MATERIALS
Animals Calorimetric
experiments
were performed
on the following
lizards
- 4 Milos wall lizards (Podarcis milensis) - 2 Common wall lizards
(Podarcis muralis)
- 3 Sand lizards
(Lacerta agilis) ~lizards (Lacerta lepida) --
- 3 Ocellated
- 3 Libanon wall -1
lizards
(Lacerta laevis) ~(Lacerta viridis) ___-
Green lizard
and the following - 1 Smooth
snakes
snake
(Coronella
- 1 Balkan whip snake -10 Aesculapian The weight
(Coluber
snakes
of the animals
gemonensis)
(Elaphe longissima). ranged between
ratory reared and increased ing maintenance
austriaca)
their weight
have been reported
4 and 18 g. All individuals during
previously
the experiments.
(ref.8,
were
labo-
Details concern-
ref.9).
Instrumentation Heat production of 100 ml vessels duction
was measured at changing
in two Calvet microcalorimeters
temperatures
rates of several mW and fivefold
the recording
system
(Micrograph
ever, it had to be increased power-time
curves
production,
the calorimetric
signal
The calorimetric
of
was set to 2mV. How-
temperatures. integrated
folded with the instrumental
vessels
The obtained
to find the mean heat
time constant
were open to air or hermetically
oxygen
determination
in the air. Without continuously
BD5; KIPP & ZONEN/Delft)
at low environmental
heat pro-
rates the sensitivity
to 'desmeare"
(ref.10).
nected to a polarographic simultaneous
higher maximum
(P-t curves) were mechanically
in some cases
(SETARAMILyon)
from 18 to 35°C. With mean
sensor
(Monitor System,
of heat production
larger disturbances
by means of a peristaltic
sealed and then con-
BECKMAN/Irvine)
and decrease
of oxygen
for a
concentration
the air in the vessel could be exchanged pump or discontinuously
by a larger sy-
ringe. The animals calorimetric high voltages
were electrically
vessel.
an electrode
cream
smeared
on the animals.
voltage
of 30 V was sufficient
to keep it moving. "appropriate" electrodes.
stimulated
In oder to facilitate
(HELLIGE/Freiburg)
to cause an explosive
of the animal
extending
into the
and to avoid dangerous
as used for EEG and ECG was
With the help of the electrode
Prior to stimulation
position
by two electrodes the experiments
the voltmeter
cream a stimulating
movement
pulsed
of the animal and
was used to monitor
by means of the resistance
an
between the two
163 RESULTS Figure 1 exhibits and its "desmearing"
the P-t curve of a Milos wall lizard by the Tian equation
(Podarcis milensis)
(ref.10).
t P/mW
b
80
60
40
20
0
t/min
Fig. 1. Power-time curve (strong line) of a Milos wall lizard (Podarcis milensis) and the original signal (thin line) calculated by means of the -equation (see text). There are periods of high activity can be determined. zards and snakes
and of rest from which
included
in these
investigations
stimulation
experiments.
and minimum
rates of heat production
has recently Table
the basal metabolism
Table 1 shows the mean rates of heat production
A detailed
been reported
(ref.8,
analysis
except
of the result together
and the correlation
for all li-
those animals
to oxygen
used for
with maximum consumption
ref.9).
1
Mean weights m(g) and mean specific rates of heat production p (mW/g) with standard deviation (mW/g) at 25'C for the different lizards and snakes in these investigations (n = number of experiments)
P.milensis P.muralis L.agilis C.austriaca C.gemonensis t.longissima
108 26 50
4.18 t 0.24 2.05 f 0.13 7.91 * 0.44
2.01 f 0.43 2.56 f 1.00 1.46 t 0.12
19 18 49
7.41 * 0.45 9.20 f 0.29 14.06 f 3.79
0.51 * 0.29 0.59 t 0.42 0.73 t 0.26
164
Fig. 2. Power-time curve (structured line) and change of oxygen concentration with time for an Aesculapian snake (Elaphe longissima) at 25°C. Figure 2 compares crease
the calorimetric
in oxygen concentration
longissima)
at 25'C. The oxygen
as much information
naturally
bic degradation
of glucose
are less structured
consumption
occuring
lizards
from the vessel
does not offer
Fig. 2 shows that the
are mainly
run by anaero-
P-t curves of snakes
because of the lower locomotor for many
down to an oxygen
activi-
hours.
concentration
mainly
coefficient
to the expected
of lipids and proteins.
found values
of anaerobic
In the stimulation
sharply
fermentation experiments
After thermal Usually
if the oxygen concentration
equilibration
At very low oxygen pointing
to energy metabolism
the two-electrode
the resistance
with the electrodes.
for a
concentrations
to a predominant
con-
(ref.9).
vessel allowed
to those obtained between
it is in the MOhm range and dropped
the animal was in contact
the limits of
value of 19.3 J/ml oxygen
increase,
are similar
decreased
of 18.6 f 3.2 J/ml oxygen
and 20.4 & 5.8 J/ml for snakes; within
to move around and the P-t curves
determined.
signal. Moreover,
keep their normal metabolism
for lizards
the experimentally
trodes.
snake (Elaphe
In the present study the animals became more active and ap-
error these figures correspond
tribution
for an Aesculapian
the snakes did not move
below 16%. In most cases an oxycaloric
food composed
line) with the de-
as an integral method
down to lactic acid. Usually,
temperature
parently tried to escape
was calculated
(structured
bursts of activity
than those of lizards
ties. At their prefered Lacertid
(smooth slope)
as the calorimetric
non-stimulated,
of 16% (ref.11).
P-t curve
the animals
without
elec-
the electrodes
was
to some IO kOhms when
This was the moment
the voltage
165
. ..-12.5
i 0
20
60
10
80
t/h
Fig. 3. Simulation of an Ocellated lizard (Lacerta lepida) at 30°C for 30 s with 30 V. The area between the P-t curve and the extrapolated heat production (dotted line) corresponds to 22.9 J, the maximum deviation of the oxygen slope after stimulation to 1.1 ml oxygen. was switched response
on for 30 s leading
is seen immediately
rographic
to the burst of activity
in strong oscillations
signal due to the vehement
the slopes of heat production the thermal
inertia
of the instrument
nal of a short pulsed
heat production
to the level prior to stimulation. literature
consumption
20.8 J/ml oxygen
is specific
If the duration additional observed.
Figure 3 exhibits
is smeared
consumption
to the typical
(steepness
the obtained
in the
of slope) oxygen
value of
Further
to the burst-off
sig-
decline
described
this additional
of glucose.
Due to
exponential
to observations
by stimulation,
contributions
information
metabolism
will
(ref.12). of the stimulation
heat production Sometimes,
the animals
in oxygen
for the metabolism
and anaerobic
be given elsewhere
heat output
with an approximately
The
and pola-
after stimulation.
of the oxygen debt. Comparing
with the heat production
about the aerobic
of the animal.
consumption
In contrast
there is a quick response
and a slow compensation
movement
and oxygen
of the reptiles.
of the calorimetric
these longer
find a position
is increased,
by the burst-off lasting
in which
a linear dependence
behaviour
stimulations
on this duration are without
of the can be
effect
because
they touch only one electrode.
DISCUSSION Except (ref.13)
for one very early calorimetric no direct calorimetric
experiments
investigation
on a lacertid
lizdrd
are found in the literature.
There-
166 fore, it seemed
interesting
energy metabolism
calorimetrically
with those obtained
vestigations
concern
experiments.
In the present
which would
to compare
reptiles
from respiratory
that were much heavier
study it was necessary
not only fit into the calorimetric
find space to move around and have enough crease
in oxygen
concentration.
bolism and weight be compared;
motory
the P-t curves
activity;
taneously
when
heat production
(ref.4) to the energy output
naturally
The P-t curves exhibit dissipation
debt
bolism of the animals.
heat output.
consumption
activities
ties of snakes were As lizards lism strongly
depends
30°C (ref.8,
was observed
by temperature
meta-
to the basal meta-
heat production
under investigation
Within
due to the "temperament"
animals
temperature.
the locomotory
one species of the indiactivi-
(ref.8, ref.9).
their energy metaboIn most cases a para-
temperature activity
than the basal metabolism
and
and from
the locomotory
than those of lizards
with a flat optimum
ren-
to the total
for the lizards
for the snakes.
to poikilothermic
ref. 9). For lizards
that these
by anaerobic
activities
on the species
upon the environmental
are
and of low levels of energy
to 79% for P.muralis
found to be smaller
activity
only over a longer period oftime.
from 65% to 88%. In general
and snakes belong
bolic dependence
depends
simul-
metabolism
it can be assumed
of locomotory
differences
e.g. in E.longissima
size can
are measured
are sustained
of high activities
to 81% for C.austriaca
there are often considerable
between meta-
about the loco-
of anaerobic
The ratio of the mean to the minimum
This figure strongly
74% for C.gemonensis
fluenced
and oxygen consumption
about the contribution
from 68% for P.milensis
viduals,
render information
is compensated
periods
also
values agree quite well
(Fig. 1 and 2). The latter ones can be attributed
ders information
changes
relation
of different
(Fig.2). As the bursts of locomotory
not stimulated
bolism and that the oxygen
of 100 ml, but would
the problem of a fast de-
for animals
to the contribution
in the slopes of oxygen
occuring,
Most in-
(ref.2).
of the reptiles
they allow deductions
never reflected
vessels
the limits of error the observed
with those cited in the literature Moreover,
measurements.
to chose small specimens
air without
figures
levels of
than those used in these
By means of the allometric
(ref.1) the obtained
within
determined
slightly
above
is more strongly
indicating
in-
that at lower tem-
peratures
the animals move more often or for longer times to find a place of
preferred
temperature
As direct processes trically
(ref.8).
calorimetry
in the absence stimulated
tric response
is a suitable
of gas exchange,
burst-offs.
heat production
area between
equals
to monitor
special
These burst-offs
(Fig.3) with a subsequent
getic level. The additional polated
means
attention
metabolic
was paid to elec-
showed an immediate
exponential
decrease
the observed
a stimulated
anaerobic
calorime-
to the former ener-
P-t curve and the extra-
heat production
of 22.9 J. As it
167 was provoked within
30 s i't corresponds
to an additional
higher than the value of 22 mW prior to stimulation, values
amount
servations
to 100.1 mW/g and 2.89 mW/g,
of Cragg
proximately
The results
movements
and attains
which
the larger volume
nel to the polarographic of oxygen
consumption
cate that an immediate the chosen
experimental
Direct calorimetry metabolism
of lizards response
that it takes apits usual,
in oxygen
consumption
of the slope changes 20 min. The time
as well as to the instrumental
retards
vessel
setup in
and the small connecting
the signal.
and snakes
Parallel
chan-
investigations
in a larger container
in the oxygen consumption
conditions
(ref.9) indi-
rate is observed
under
(ref.l2),
proves to be a suitable
of poikilothermic
other methods
observed
the steepness
of the calorimetric electrode
from 7.06 mW/g
with
a new steady state after approximately reasons
specific
vessel.
Nevertheless,
lag may be due to physiological
animals
tooi in the investigation
to render information
and to avoid the sacrifice
of the animal
of the
not obtainable
for anaerobic
by
analyses.
REFERENCES 1 2 3 4 5 6 7 8
A.F. Bennett and W.R. Dawson, in C. Gans (Ed.), Biology of the reptilia. Academic Press, London, vol 5A/3, 1976, pp. 127-223. A.F. Bennett, in C. Gans (Ed.), Biology of the reptilia. Academic Press, London, vol 130/3, 1982, pp. 156-199. D.A. Belkin, Science NY 139 (1963) 492-493. A.F. Bennett and P. Licht, J. Comp. Physiol. 81 (1972) 277-288. A.F. Bennett and P. Licht, J. Comp. Physiol. 82 (1973) 351-360. A.F. Bennett, R.B. Huey and H. John-Alder, J. Comp. Physiol. B154 (1984) 113-118. E. Calvet and H. Prat, Microcalorimetrie - Applications physicochimiques et bioloaiaues. Masson et Cie, Paris, 1956.
F.R. Matuschka and I.H.D. Lamprecht, submitted 9 I.H.D. Lamprecht and F.R. Matuschka, submitted 10 W. Hemminger and G. Hoehne, Grundlagen der Kalorimetrie. 11 12
13 14
fold
agree with ob-
of L.viridis
to recover and to continue
is not as promptly
(Fig.3).
results
Fig. 3 indicates
stimulation.
in the calorimetric
of stimulation
as in heat production immediately
at maximum
40 min for the animal
non-stimulated
The corresponding
resp. These
(ref.14) who found a stimulation
at rest to 173.7 mW/g
power of 763 mW,35
Verlag Chemie, Weinheim, 1979. B. Nielsen, J. Exp. Biol. 39 (1982) 107-117. I.H.D. Lamprecht and F.R. Matuschka, submitted L. Krehl and F. Soetbeer, Arch. Ges. Physiol. 77 (1899) 611-638. P.A. Cragg, Comp. Biochem. Physiol. 60A (1978) 399-410.