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First published online October 17, 2008
Journal of Experimental Biology 211, 3409-3420 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.019877
Correlated patterns of tracheal compression and convective gas exchange in a carabid beetle
1 Advanced Photon Source, Argonne National Laboratory, Argonne, IL 60439,
USA
2 Section of Organismal, Integrative and Systems Biology, Arizona State
University, Tempe, AZ 85287, USA
3 Department of Zoology, Field Museum of Natural History, Chicago, IL 60605,
USA
* Author for correspondence at present address: Department of Engineering Science and Mechanics, Virginia Tech, Blacksburg, VA 24061, USA (e-mail: jjsocha{at}vt.edu)
Accepted 3 September 2008
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: beetle, convection, gas exchange, imaging, synchrotron x-ray, tracheal compression
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Weis-Fogh, 1964), many species
are known to augment gas exchange using convection
(Buck, 1962;
Miller, 1966a). Two general
mechanisms are recognized that produce convection in insect tracheal systems:
(i) suction ventilation, in which air movement is driven passively by pressure
differences (e.g. Miller,
1974), and (ii) collapse of tracheal tubes or air sacs, in which
air is driven mechanically by active external or internal body movements that
deform the tracheal system (e.g.
Sláma, 1988). Until
recently, internal processes in most insect species have been difficult to
observe in live specimens, and previous understanding of convection by
tracheal collapse has been based primarily on secondary inference. The
historical inability to visualize tracheal structures has meant that
mechanisms of active ventilation have not been thoroughly investigated in
insects, and their role in gas exchange may be grossly underestimated. The
relative importance of convection and diffusion in insect gas exchange thus
remains an open question among the great diversity of insect taxa.
Convection in the tracheal system of insects has been recognized for over a
century (see Babak, 1921). In
suction ventilation, air is driven passively through the tracheae due to a
pressure gradient between the tube interior and the external environment. Two
variants are recognized. In Bernoulli suction ventilation, air is drawn into
the main thoracic tracheae by pressure differences between the open ends of
the tracheal system (Stride,
1958); this may occur in flying insects in which one spiracle is
located in the fast-moving airstream and another is shielded from flow. This
mechanism has only been identified in one species, the beetle Petrognatha
gigas (Amos and Miller,
1966), but it is thought to occur in other species as well
(Dudley, 2000). In passive
suction ventilation, the pressure gradient is created by the depletion of
tracheal oxygen when all spiracles are closed, lowering the intra-tracheal
pressure; when the spiracles open, air flows in (e.g.
Kestler, 1985;
Mand et al., 2005;
Miller, 1974;
Schneiderman, 1960).
Most convection, however, is assumed to be produced via muscular
contractions that deform tracheae or air sacs
(Chapman, 1998). In this
mechanism, muscles compress the exoskeleton, leading to a volume reduction of
a tracheal tube or air sac, displacing air and forcing bulk flow. Depending on
physical conditions (e.g. tube length and diameter, pressure differences,
etc.), the resulting convection can transport gases much faster than diffusion
alone. Muscular convection behaviors include: (1) abdominal or thoracic
pumping, in which a body segment is actively shortened in one dimension,
causing an increase in hemolymph pressure (e.g.
Harrison, 1997;
Miller, 1971); (2)
autoventilation, a form of thoracic pumping caused by the movement of the
wings or legs during movement (e.g.
Bartholomew and Barnhart, 1984;
Weis-Fogh, 1967); and (3)
hemolymph transport, in which hemolymph is pumped from one region of the body
to another by the heart, locally increasing or decreasing pressure in
different body compartments (e.g.
Wasserthal, 1996). However,
due to the previous inability to see through the opaque insect exoskeleton,
deformation or movement of tracheal structures has been inferred rather than
observed directly (but see Herford,
1938; Westneat et al.,
2003) and, overall, the paradigmatic view of insect tracheal
systems is that most tracheal tubes function as rigid, static conduits. Owing
to this prior methodological limitation, for most insect taxa it is not known
whether and which tracheal tubes collapse, under what conditions, and what
functional roles the process serves. Convection in insect tracheal systems is
thus poorly understood in terms of function, anatomical mechanism, and
ecological and evolutionary significance.
Synchrotron x-ray imaging is a technique that has recently opened a new
window to visualizing internal processes in small animals. Providing
micrometer-scale resolution of millimeter-sized subjects, it enables an
experimenter to view real-time events in living animals
(Socha et al., 2007). More
commonly used as a tool by physical science communities
(Fitzgerald, 2000;
Nugent et al., 2001), it has
been applied only recently to questions of organismal biology
(Westneat et al., 2008).
Tracheal structures are particularly easy to visualize because of the large
density difference between air and tissue, enabling for the first time direct
observation of the morphology and dynamics of compressible tracheae in insects
with opaque exoskeletons.
Convective mechanisms involving deformable tracheae have been studied
recently using this form of x-ray imaging. By exploring a range of insect
taxa, Westneat and colleagues (Westneat et
al., 2003) discovered rapid cycles of collapse and reinflation in
tracheal tubes of multiple species including a beetle (Platynus
decentis), an ant (Camponotus pennsylvanicus) and a cricket
(Achaeta domesticus). The kinematics of these rhythmic tracheal
compression cycles, which were observed in parts of the basal head and thorax,
consisted of tube width decreasing dramatically in one axis while slightly
increasing in the orthogonal axis, decreasing the volume by an estimated 50%
on average. Compressions lasted for 0.7 to 1.6 s and occurred at a frequency
of 24–42 cycles min–1. The cycles were observed to
occur synchronously in different tracheal tubes, but isolated compressions
were noted in some species.
Although the volume displacement and rhythmicity of these newly discovered tracheal compression cycles strongly suggest a role in gas exchange, their specific biological function remains uncertain. One possibility is that tracheal compressions occur while spiracles are closed, driving pressure differences that enhance diffusion. Another possibility is that the compressions primarily drive airflow within the insect, between spiracles and tissues. Finally, tracheal compressions may flush the entire system, including producing convection through the spiracles (if synchronized with spiracular opening).
In this study, we focus on the function of tracheal collapse in a carabid
beetle species (Pterostichus stygicus) that prominently compresses
its tracheal tubes in a rhythmic fashion, specifically addressing the question
of whether tracheal compressions produce convection that increases gas
exchange through the spiracles. To determine the connection between internal
dynamics and external gas exchange, we imaged live beetles with synchrotron
x-rays while simultaneously recording gas exchange patterns. Although many
natural behaviors such as breathing and feeding are performed by insects in
the synchrotron x-ray beam, this method can lead to a number of deleterious
effects (including eventual death), depending on the location, energy,
intensity and duration of exposure (Socha
et al., 2007). Therefore, an important technical issue is whether
the tracheal compressions observed with synchrotron imaging vanish or change
their characteristics in undisturbed insects not being x-rayed. To control for
this possible complication, we compared high-resolution CO2
emission patterns before, during and after x-ray exposure.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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)
identified rhythmic tracheal compressions in the ground beetle Platynus
decentis, we chose to work with Pterostichus stygicus for its
larger body size (ca. 4–6x in mass), providing
CO2 signals of greater magnitude and tracheal tubes of larger
maximum size for easier visualization. Preliminary exploratory x-ray imaging
identified that Pterostichus stygicus compresses its tracheal tubes
in a similar manner to Platynus decentis. Beetles were collected
locally in pitfall traps in the woods at Argonne National Laboratory and were
kept in a terrarium with ad libitum food and water prior to testing.
Fifteen specimens (both male and female) were used, with mass
186.1±44.3 mg (mean ± s.d., hereafter).
Concurrent respirometry and x-ray imaging
To determine the relationship between gas exchange and internal compression
of tracheal tubes, beetles were concurrently imaged with synchrotron x-rays
while CO2 release patterns were recorded
(Fig. 1).
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Beetles were held immobile in a custom-made acrylic Plexiglas respirometry chamber. Two walls of the chamber were constructed of x-ray translucent polyimide film (Kapton, Dupont, DE, USA) so that the x-ray beam would pass through the sample unobstructed. The dimensions of the inner rectangular chamber containing the beetle were 0.5 cmx1.0 cmx2.0 cm, with a volume of 1.0 ml. Clay-like adhesive (Bostik Prestik, Bostik, Wauwatosa, WI, USA) was molded to the sides of the chamber to reduce the airflow volume, minimize washout time, and to keep the beetle immobile. With the beetle and clay in place, the remaining volume of air in the chamber was less than 0.25 ml.
Control trials were conducted to test whether the Prestik adhesive absorbed CO2. Boluses of air containing 301 p.p.m. CO2 were injected into a 60 ml chamber with either a 5.5 g mass of Prestik or a glass stopper (as control). The Prestik mass was shaped to match the size and volume of the stopper in order to create equivalent volumes and flow patterns within the chamber. The resulting CO2 records show that boluses did not differ in volume (Student's t-test, d.f.=21, t=0.43), and that the chamber washout was similar for the two (Z-correction, 0.04 and 0.05, respectively), confirming that the Prestik adhesive did not significantly absorb CO2.
|
). We
used high flow rates (1.5–2.5 l min–1), which, coupled
with our small chamber volume, provided temporal resolution sufficient to
identify similar potential CO2 pulses in Pterostichus
stygicus. High flow rates are required to prevent CO2 pulses
of short duration from being masked by washout in the respiratory chamber and
tubing, and by transit through the infrared gas analyzer's detection chamber
(Bartholomew et al., 1981;
Gray and Bradley, 2006). In
our system, the time constant (volume/flow rate) of the chamber was
approximately 0.01 s, giving a 99% washout time of 0.05 s, and the transit
time through the infrared gas analyzer's cylindrical detection chamber
(length=152 mm, radius=4.8 mm) was 0.43 s. These parameters were sufficient to
identify CO2 events with sub-second precision. Although high flow
rates mean that airspeed over the beetle was fast (
3 m
s–1, estimated), the spiracles of Pterostichus
stygicus are shielded under the elytra or the thoracic ventral plates, so
it is unlikely that significant flow-induced Bernoulli effects occurred in the
tracheal system.
An additional factor to consider in designing a high-precision respiratory
system is the transit time from chamber to CO2 detector, which
creates a time lag between gas release and its recording. Here this lag is
critical to understanding the relative timing of gas exchange and behaviors
recorded with x-ray video. Theoretically, time lag can be calculated as:
 | (1) |
0.32 cm) diameter tube of length 1.53 m and flow
rate of 1.5 l min–1, the theoretical time lag in our system
is 0.49 s. However, the time lag in practice is greater than predicted due to
factors such as the uneven flow around the specimen, the presence of a
particulate filter just upstream of the detector and diffusive spread of
CO2 during transit. To determine experimental values of time lag in
our system, off-line trials were conducted using controlled CO2
injections of known timing. A pressure-controlled picoliter volume ejector
(Picospritzer III, Parker Hannifin Corporation, Fairfield, NJ, USA), which
sends a 5 V signal at the time of injection, was used to measure the time lag
directly. These trials were set up to simulate CO2 release from the
beetle in the respiratory chamber: CO2 from the Picospritzer III
was injected just upstream of the chamber, which contained a dead, dried
beetle, and all else was the same. Time lag was measured as the time between
the start of the voltage signal and the start of the detected CO2
pulse (with start defined as the data point just prior to the first detectable
rise in CO2 in the pulse). The transit time of the CO2
pulse from the Picospritzer to the free-stream flow was determined by varying
the length of tubing from injection to the CO2 detector and
calculating the y-intercept of a linear regression of tube length
vs lag time. This transit time (0.26 s) was subtracted from the
total measured time to provide the lag time. With a flow rate of 1.5 l
min–1, the experimentally determined lag time in our system
was 0.90 s.
Synchrotron x-ray imaging
Synchrotron x-ray image data were collected at the XOR-1ID and XOR-32ID
undulator beamlines at the Advanced Photon Source (Argonne National
Laboratory, Argonne, IL, USA). Phase-enhanced images were created using
monochromatic x-rays (25 keV), a scintillator screen (cerium-doped yttrium
aluminum garnet), and a sample-to-scintillator distance of 0.5 m. For
more details of this method, see Socha et al.
(Socha et al., 2007). To
minimize potential harm to the animal, the lowest possible incident beam flux
to form a viewable image was used; in some trials, shutters were used to
reduce the field of view to the tracheal tube of interest, further reducing
x-ray flux. Total exposure time on the animal was generally less than 15 min,
and no apparent behavioral changes were observed in any specimen
post-irradiation.
Images were recorded at standard video rates (30 Hz) using a video camera (Cohu 4920 or Cohu 2700, Cohu, San Diego, CA, USA) and a x2 microscope objective. The full field of view was 3.2 mmx2.4 mm, and the reduced field of view (to reduce radiation exposure) was 3.2 mmx1.3 mm. Movie clips were downloaded to a Macintosh computer using Adobe Premiere software (Adobe, San Jose, CA, USA).
Trial protocol
Beetles were anesthetized with N2, weighed to the nearest 0.1 mg
with a Mettler AG245 balance (Mettler-Toledo, Columbus, OH, USA), and placed
in the respiratory chamber, which was then mounted on a translatable stage in
line with the x-ray beam. After the beetle had fully recovered from anesthesia
(ca. 10 min), the chamber was connected to the flow-through
respirometry system and the beetle's CO2 release pattern was
recorded for 5 min or longer. This pre-beam measurement provided a control
against which we could compare respiratory patterns during x-ray exposure. The
x-ray beam was then turned on, and the beetle was translated until a major
tracheal tube of the mesothorax was brought into view. After 5 min of x-ray
video recording showing rhythmic tracheal compression, the beetle was
translated to view other parts of the body to determine the regions and
tracheal tubes in which compression took place, and to determine whether such
compressions occurred with the same timing as the compressions in the
mesothorax. After the beam was turned off, the CO2 recording was
continued for 5 min or longer. Before and after each trial, air flow was
diverted past the chamber to produce CO2-free baselines. Although
the chamber was bypassed, prior testing was conducted to ensure that the empty
chamber did not significantly alter the baseline. All trials were recorded at
21°C.
In each trial, a synchronization event was introduced both pre- and post-x-ray recording, which permitted the video and CO2 signals to be synchronized post hoc. Two methods were used. In early trials, a mark in the CO2 trace was made using a keyboard stroke concurrent with the time of beam on and beam off, providing synchrony of ±0.97 s. This level of synchrony enabled us to associate pulses in the CO2 trace with compressions observed in the movies. To obtain greater precision of timing of events, in later trials we synchronized the signals using pulses of light instead of keyboard strokes. The light was produced using a voltage source connected to the UI-2, with a voltage spike recorded in Expedata at the same time that the light pulse was recorded on videotape. This method provided synchronization of ±0.07 s.
Analyses
Fifteen trials were recorded (one per specimen), and 10 were selected for
detailed analysis. For each trial, the x-ray video was analyzed frame by frame
to determine the kinematics of tracheal compression. In the mesothorax, the
beginning and end of each tracheal compression were noted in a subsample of 2
min. These data were used to calculate compression duration and frequency, and
were mapped onto the CO2 trace to characterize the relationship
between compression and gas release. Similar analyses were conducted in
different regions of the body in representative trials.
The kinematics of compression in deformable tracheal tubes were broadly
characterized by digitizing the width of a representative tracheal tube
throughout multiple compression cycles. Movie sequences were imported into NIH
Image and landmark points were digitized using QuickImage software
(Walker, 2001). For each
specimen, a large tracheal tube (for most, a main tube of the mesothorax) was
used. Because in general the amount of compression varied with location along
the tube, a point of maximal compression was chosen for digitization. Two
points were digitized per frame, one on each side of the tracheal wall,
oriented orthogonally (representing a diameter). Because line thickness in
phase-contrast images is artifactual (i.e. the width of a line is greater than
the true anatomical width), the boundary of the tracheal tube was estimated as
the midpoint of the line width. The diameter of the tracheal tube was
calculated as the distance between these two points. Five compression
sequences for each specimen were digitized, with the beginning and ending of
each compression sequence determined by tracheal movement patterns observed in
the movie records.
Statistics
To test differences among pre-beam, beam on and post-beam treatments, we
used JMP software (SAS Institute, Cary, NC, USA) to perform repeated measures
ANOVA. Percentage data were arcsine transformed prior to analysis.
Post-hoc Tukey–Kramer honestly significant difference (HSD)
tests were used to determine specific differences between means.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Relationship between tracheal compression and external gas exchange
For each and every tracheal compression observed in the x-ray video, there
was a corresponding local peak in the CO2 trace; there were no
compressions that occurred in the absence of a CO2 peak (Figs
4 and
5). The lag between the start
of compression and the rise in CO2 was 0.16±0.24 s in
specimens synchronized with low precision (N=7), and 0.11±0.04
s in specimens synchronized with higher precision (N=2). In the light
of the synchronization error (±0.97 and ±0.07 s, respectively),
we cannot distinguish these values as different from zero, but these data show
that the start of tracheal compression and the start of CO2 rise
occurred almost simultaneously. In some instances, the burst of CO2
was followed immediately by a local decrease in CO2 output (e.g.
Fig. 4); however, other
specimens did not show this pattern (e.g.
Fig. 5).
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We wondered whether we might be underestimating the contribution of tracheal compressions to CO2 emission because the time resolution of our respirometry system was insufficient to discern the true drop in CO2 emission that occurred between compressions. If compressions occurred rapidly enough, the individual bursts may have been superimposed. To test this possibility, we took advantage of a single trial in which the beetle occasionally compressed its tracheae during periods of zero (or near-zero) background CO2 release, providing isolated `singlet' pulses (Fig. 6A). We used a large singlet burst (Fig. 6A, red arrow) to determine the effect of superimposition by simulating burst repeat rates of 14, 20, 33 and 50 min–1 (Fig. 6B). At the compression frequencies near those measured for the beetle, CO2 emission rate dropped to near zero, and high continuous baselines of CO2, as recorded in all beetles, did not occur until frequencies were much greater than those actually observed. This simulation suggests that our estimate of CO2 emission associated with tracheal compressions was not significantly underestimated by the time resolution of our respiratory system. The baseline CO2 emission is probably due to diffusive CO2 emission through open spiracles, or is associated with convection occurring at frequencies higher than we could observe with our measuring system.
Effect of x-ray beam on gas exchange patterns
Although tracheal compressions could not be visualized without the x-ray
beam on, similar pulses of CO2 occurred both prior to and after the
x-ray beam irradiation (Figs 4,
5 and
7). On average, these pulses
were not significantly different in frequency (ANOVA:
F2,25=1.90, P=0.17) or duration (ANOVA:
F2,23=1.75, P=0.20) in pre-beam, beam on and
post-beam treatments, and the average mass-specific metabolic rate did not
vary (ANOVA: F2,23=0.45, P=0.64;
Table 1;
Fig. 8). The only variable that
changed was absolute CO2 pulse volume, which was approximately
twice as large when the x-ray beam was turned on (ANOVA:
F2,23=4.26, P=0.03; Tukey–Kramer HSD
P<0.05); however, it was not significantly different (ANOVA:
F2,20=1.73, P=0.21) when calculated as a fraction
of the total CO2 released. When considering individual trials, most
specimens changed some aspect of their gas exchange pattern during irradiation
(e.g. Fig. 7), including
increased tracheal compression frequency (5 of 8 specimens) and increased
volume per pulse (6 of 8 specimens). These changes suggest that exposure to
the x-ray increased the magnitude of tracheal compression. However, the fact
that similar patterns of CO2 pulses occurred in and out of the
x-ray beam strongly suggests that tracheal compression occurs in inactive
beetles. Interestingly, in one trial the beetle stopped compressing when the
beam was turned on (see supplementary material Fig. S1), and resumed
compressing after the beam was turned off, suggesting that occasionally these
beetles may silence their tracheal compressions in response to disturbance or
stress.
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Stress of the x-ray environment
Given sufficient time, synchrotron x-rays used to image the tracheal system
will change the respiratory pattern and kill most insects
(Socha et al., 2007). Are the
tracheal compressions reported here a consequence of the stress of x-ray
imaging, or do they also occur in unirradiated animals? The observation that
respiratory patterns are very similar in pattern and frequency of bursts
before and during initial beam exposure strongly suggests that tracheal
compressions were occurring in the beetles prior to x-ray exposure. These
beetles were clearly not `undisturbed', as they had been handled in the hour
prior to recording, and their movements were constrained. Thus we cannot say
for certain whether tracheal compressions occur in beetles under other
conditions, for example when foraging in the field, or when kept in the dark
without food for many hours, as is sometimes done with insects to record
discontinuous gas exchange. However, it does not appear that these beetles
were under excessive stress, as their metabolic rates [average: 0.0090 ml
CO2 g–1 min–1, 95% confidence
interval (CI): 0.0060–0.0121 ml CO2 g–1
min–1, N=9] overlapped the predicted value for
resting carabid beetles reported by Chown and colleagues [predicted value for
a 181 mg beetle, with respiratory quotient RQ=0.85: 0.0067 ml CO2
g–1 min–1
(Chown et al., 2007)]. Thus,
tracheal compressions occurred in beetles exhibiting metabolic rates in the
range of those considered `resting' by the current literature. Exposure to the
beam did double the amount of CO2 emitted per pulse, suggesting
that variation in tracheal compression may be an important mechanism of
grading gas exchange in response to stress or metabolic need.
The role of convection in Pterostichus stygicus
Generally, in species that deform parts of the tracheal system, patterns of
CO2 release should depend on the kinematics of compression, the
connectivity of the tracheal system, and the timing of spiracle opening and
closing. In Pterostichus stygicus, the exact architecture of the
tracheal system and the spiracle dynamics are not yet known, but because at
least one spiracle was open at the start of a compression, the air displaced
during tracheal deformation must have contributed to a convective movement of
air out of the body.
How does the volume of compressed tracheae compare with the volume of
expressed air? To explore this question, we estimate the volume of air
displaced in the tracheae and compare it with the volume of air in the
recorded CO2 bursts. As a simple first-order model, we consider
only the major tracheal tubes involved in compression and assume round,
cylindrical tubes with dimensions based on the measured anatomy of a typical
specimen of Pterostichus stygicus
(Fig. 9; mass=182 mg). In this
model, the resting (uncompressed) volume of the trachea section is 468 nl. To
calculate the volume of air displaced in the tubes during compression, we
follow Westneat and colleagues (Westneat
et al., 2003) and assume a uniform cross-sectional shape change in
the tracheae from circular to elliptical and a constant perimeter. In this
model, a tracheal tube width change of 60–72% would displace
197–272 nl of air. Assuming CO2 partial pressures in the
tracheae of 1–5%, the CO2 volume is therefore calculated to
be 2–14 nl. This estimated displaced gas in the tracheae overlaps the
measured range of CO2 burst volumes (4–40 nl). Although we
have made many simplifying assumptions, this comparison lends plausibility to
our conclusion that tracheal compressions convectively pushed air out of the
beetle's body. Precise calculations of displaced volume require a more
thorough understanding of the location and three-dimensional geometry of
compression, or experimental manipulations to controllably produce collapse.
We are currently conducting detailed morphological analyses to precisely
determine the volume of air displaced during compression; in theory these
measurements can be combined with CO2 emission rates to estimate
the percentage CO2 in the expired air.
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;
Wigglesworth, 1931), and our
high-resolution x-ray images have not revealed any evidence of valving or
compartmentation in the tracheal system of Pterostichus stygicus.
Direct confirmation that tracheal compression drives air through the spiracles
will require measurement of airflow through the spiracles, or the
contributions of convection and diffusion could be quantified by manipulating
the density of the air in the flow-through system by replacing N2
with SF6 or helium.
Observations of collapsible tracheae in insects
It has long been recognized that insect tracheal structures (including both
tracheal tubes and air sacs) are capable of being compressed. In fact as far
back as 1931, Wigglesworth noted that it was generally accepted that
respiratory movements such as abdominal and thoracic pumping function to
alternately compress and dilate the tracheal system
(Wigglesworth, 1931). However,
the mechanical problem with this idea is that taenidal rings, which are
thickenings in the tracheal wall, can be viewed as morphological
specializations that prevent rather than promote collapse. Given the ubiquity
of taenidia in insect tracheae, the current prevailing view is that most
tracheae act as rigid conduits rather than flexible bellows-like structures.
Collapse, then, is seen as an exception, occurring only in places with reduced
taendia, thinner walls or non-circular tubes. Of the latter, Krogh used the
term `respiration tracheae' or `ventilation tracheae' to describe special
distensible tracheae that feature an oval rather than a round cross-sectional
shape (Krogh, 1920b;
Krogh, 1941); such tracheae
were implicated by Miller to be involved in convective airflow in large,
flying, cerambycid beetles (Miller,
1966b). However, these ideas of compressibility rely largely on
anatomical inference (e.g. Kerry and Mill,
1987; Komai,
1998), and very few studies have described compressions in living
animals, largely due to methodological limitations.
Because so few direct in vivo observations of collapsible tracheae
have been made, it is difficult to assess in what ways the rhythmic tracheal
compression seen here and in other species relates to known gas exchange
mechanisms. Prior to synchrotron imaging, the only way to directly view
activity in the tracheal system was in translucent animals using visible
light. Dunavan observed what appear to be similar compression cycles in fly
larvae (Erstalis arbustorum) after starving them of oxygen
(Dunavan, 1929). Upon
reintroduction to air, the larvae were seen (via microscope) to
rapidly `flatten' and then to reinflate the two main tracheal trunks, with
about 2 s between cycles. Compression events were not quantified, precluding
comparison of duration or frequency. However, reinflation was described as
taking place more slowly than collapse, perhaps similar to that in
Pterostichus stygicus, in which reinflation was about twice as slow
as compression. In another example, Herford viewed what was termed `tracheal
pulsation' in the thorax, abdomen and legs of several species of flea
(Herford, 1938). In a tracheal
pulsation, the main tracheal tubes were seen to collapse slowly over the
course of about 30 s, and then rapidly reinflate, with 5–80 s between
compressions; the tubes straightened along their length during collapse as
well. In contrast to the so-called `ventilation tracheae' of Krogh, these
tracheae were round in resting cross-section, not oval. Additionally, the
pulsations ceased entirely when the legs were cut open, such that the tracheae
became permanently connected to the atmosphere. In both the fly larvae and the
fleas, it is not understood what produced the compression cycles, but the
mechanism is probably quite different between Pterostichus stygicus
(and fly larvae) and fleas. Their slow tracheal collapse, rapid reinflation
and cessation of cycles with opening to the environment point to passive
suction ventilation (PSV) as the mechanism
(Buck, 1962). If true, the
fleas' tracheae collapsed as oxygen was depleted in a sealed system (with
spiracles closed), and reinflated rapidly when spiracles opened. These
tracheal dynamics are the inverse of those in the larvae and beetles, which
showed rapid collapse and slower reinflation. Indeed, we reject the hypothesis
that PSV produced tracheal compressions in Pterostichus stygicus
because CO2 traces indicated that spiracles were open at the start
of most compressions.
Tracheal compressions in Pterostichus stygicus were similar in
nature to those described in the carabid beetle Platynus decentis
(Westneat et al., 2003), but
differences in compression characteristics are evident. In contrast to
Pterostichus stygicus, compressions in Platynus decentis
were dynamically symmetrical, with collapse and reinflation taking place at
the same rate; also, there was no static compression phase in which the tubes
were held deflated in place. Compressions in Platynus decentis were
shorter in duration (0.7 vs 1.8 s) and occurred more frequently (42
vs 16 min–1). These differences may be related to
body size, metabolism or other physiological factors. Alternatively (or in
addition), they may reflect differences in x-ray effects on the animals:
improvements in our imaging system have resulted in the ability to use a lower
beam intensity to achieve the same or higher quality imagery than used
previously (Socha et al.,
2007), and Platynus decentis may have been under greater
irradiative duress than Pterostichus stygicus.
Anatomical mechanism of tracheal compression
Two general mechanisms may have produced rhythmic tracheal compressions in
Pterostichus stygicus. The first is collapse by direct mechanical
impingement of the tube; this deformation could hypothetically be effected by
the muscle width increase that occurs during normal isovolumetric shortening
(Kier and Smith, 1985;
Komai, 1998). However, this
hypothesis seems unlikely given the synchronous collapse of tracheal tubes
throughout the body and the fact that insect tracheae are amuscular
(Whitten, 1972). The second
possible mechanism is collapse by differential pressure across the tracheal
wall. This pressure difference could arise from decreased intra-tracheal
pressure, increased hemolymph pressure or some combination of both. Miller
(1966b) experimentally
determined that large secondary tracheae (diameter 300 µm) excised
from the cerambycid beetle Petrognatha gigas collapsed under a
pressure difference of 0.7–2.4 kPa. Comparable hemolymph pressure
changes have been recorded in the hemocoel of live animals, including 0.5 kPa
in lepidopteran and coleopteran pupae (e.g.
Sláma, 2000;
Sláma and Neven, 2001)
and 1–2 kPa in adult desert locusts
(Krolikowski and Harrison,
1996; Weis-Fogh,
1967), suggesting that hemolymph pressure changes are capable of
producing the observed tracheal compressions in Pterostichus
stygicus. Given the synchronicity of collapse, we suggest that global
pressure change is the primary mechanism of tracheal compression in
Pterostichus stygicus and other carabid beetles that display this
behavior. However, a puzzling question remains: if hemolymph pressure is the
cause, why do some tracheal tubes not collapse? One possibility is that
variation in tracheal tube mechanical properties underlies differences in
local tube compressibility.
Cyclic changes in coelomic hemolymph pressure with frequencies similar to
the tracheal compressions observed here have been recorded in multiple species
(Coquillaud et al., 1990;
Sláma, 1989;
Sláma, 2000;
Sláma, 1984;
Sláma and Neven, 2001).
Sláma has termed these coelomic pulsations `extracardiac' to
distinguish them from those produced by contractions of the dorsal heart
vessel, which give rise to pressure changes roughly two orders of magnitude
smaller (Sláma, 2000).
Extracardiac hemolymph pulsations have been associated with external gas
exchange and have been suggested to play a major role in insect respiration
(Sláma, 1999). Further
studies will be required to determine whether the CO2 and pressure
pulsations documented by Sláma and colleagues are identical to the
tracheal compression-linked CO2 pulsed in Pterostichus
stygicus. However, the patterns are so similar that this seems quite
likely, further supporting the hypothesis that tracheal compression is a
mechanism for enhancing trans-spiracular gas exchange in many insects. If so,
the system may work mechanically via the following sequence,
hypothesized by Sláma
(Sláma, 1994): (1)
muscular contraction of abdominal segments; (2) decrease in body volume; (3)
increase in pressure and movement of hemolymph in the hemocoel; and (4)
compression of the main tracheal trunks, resulting in mechanical (convective)
expulsion of intratracheal gas through the open spiracles. Our study provides
positive evidence for the last component (compression of tubes and expulsion
of gas), but we have yet to test the other aspects of this model. To this end,
we are currently exploring the relationship between external body movements,
internal pressure changes, tracheal collapse and gas exchange in
Pterostichus stygicus and other species.
Physiological function of tracheal compression
Are the tracheal compressions observed here necessary for adequate gas
exchange in beetles and other insects? Classic respiration studies
(Krogh, 1920a;
Weis-Fogh, 1964) have shown
that diffusion alone should deliver sufficient oxygen to support resting
metabolic rate in insects. Is it possible for diffusion to suffice to deliver
oxygen from the mesothoracic spiracles to the head via the four main
tracheal trunks? We consider the simplest case: we model the four tracheae as
one conduit with summed area, the head alone consumes oxygen (i.e. there is no
metabolic loss of oxygen along the length of the tube), and spiracles are open
to atmospheric oxygen. The rate of oxygen delivery to the head
(m/t) is then given by Fick's equation:
 | (2) |
If diffusion can sustain adequate gas exchange, why do tracheal
compressions occur? One possibility is that the increase in gas exchange
associated with the tracheal compressions functions to keep oxygen partial
pressures high at the tissues for sudden fast movement; in grasshoppers, a
significant portion of the oxygen consumed during seconds of jumping comes
from internal tracheal stores (Harrison et
al., 1991). Convection may promote equalization of oxygen and
carbon dioxide levels throughout the insect, aiding metabolic and
acid–base regulation. Another possibility, as argued by Kestler
(Kestler, 1985), is that small
insects may employ convective gas exchange where diffusion alone would be
sufficient in order to minimize water loss through the spiracles.
Conclusion
This study illustrates the power of visualizing the internal dynamics of
living insects. We would not have looked for high-frequency CO2
bursts in Pterostichus stygicus without the discovery of rhythmic
compressions in related taxa. Historically, most studies of gas exchange in
insects that use flow-through respirometry have employed low flow speeds,
which are well suited for determining broad-scale exchange patterns with high
concentration precision, but, with poor temporal resolution, are ill-suited
for characterizing short-duration events (see
Fig. 4C)
(Gray and Bradley, 2006). We
suggest that some, if not many, of these previously studied taxa may show
evidence of cyclic convective gas exchange when studied with higher flow
speeds and when tracheal dynamics are revealed with synchrotron x-rays.
Species that have been shown to use body movements or other high-frequency
ventilatory signatures (e.g. Kuusik et
al., 2001; Miller,
1971; Tartes et al.,
1999) are particularly favorable for investigation. For example,
the recently discovered correlation of cyclic gas exchange with proboscis
extension movements in Drosophila
(Lehmann and Heymann, 2005)
may be mechanistically explained by expansion of air sacs in the head, which
can be readily visualized with x-rays
(Westneat et al., 2008).
Bursts of convectively expelled CO2 via tracheal
compression can occur during the F- and O- phases of discontinuous gas
exchange cycles (Chown et al.,
2006; Lighton,
1991; Lighton,
1996), and these may be associated with tracheal compressions.
Considering the large diversity of recognized external gas exchange patterns
in insects (Marais et al.,
2005), it seems likely that internal compressions are used in ways
other than that seen here in Pterostichus stygicus amongst the
tremendous diversity of unexplored taxa.
|
Acknowledgments |
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Footnotes |
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References |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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