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First published online July 20, 2007
Journal of Experimental Biology 210, 2754-2764 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.006114
Mechanistic bases for differences in passive absorption
1 Department of Wildlife Ecology, University of Wisconsin-Madison, Madison,
WI 53706, USA
2 School of Veterinary and Biomedical Sciences, Murdoch University, Murdoch,
WA 6150, Australia
* Author for correspondence (e-mail: wkarasov{at}wisc.edu)
Accepted 15 May 2007
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Summary |
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Key words: paracellular nutrient absorption, tight junction, solvent drag, gut morphology
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Introduction |
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TOPSummaryIntroductionMaterial and methodsResultsDiscussionReferences |
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). Water-soluble molecules, like glucose, are not permeable in
the lipid bilayer, thus this membrane is a limiting factor for the absorption
of hydrophilic molecules. Unless they are taken up by specialized transporters
and moved transcellularly, medium to large hydrophilic molecules presumably
permeate across the small intestinal mucosal epithelium primarily through the
paracellular pathway (Powell,
1987).
Notwithstanding the qualitative similarities between mammalian and avian
species in paracellular absorption, researchers have sometimes noted
differences in the magnitude of paracellular absorption among mammals
(Bijlsma et al., 1995;
Delahunty and Hollander, 1987;
He et al., 1998;
Pappenheimer, 1990) or between
mammals and birds (Chediack et al.,
2003). Concerning the latter comparison, although many of the
studies on birds provide evidence of much higher paracellular absorption
(Afik et al., 1997;
Caviedes-Vidal and Karasov,
1996; Karasov and Cork,
1994) than observed in mammalian species (cf.
Bijlsma et al., 1995;
Delahunty and Hollander, 1987;
Pappenheimer, 1990), studies
have not employed uniform methodologies, and the mechanistic bases behind
apparent species differences are poorly understood. Also, if body size
influences reliance on paracellular absorption
(Pappenheimer, 1998), then
this factor should be taken into account. Here, in a series of experiments
with similarly sized (300–500 g) pigeons and laboratory rats, we find
apparently higher paracellular absorption in pigeons, and test a number of
mechanistic bases for this difference.
We used standard methods from pharmacokinetics to measure the
whole-organism fractional absorption of L-arabinose
(Mr=150.1) and L-rhamnose
(Mr=164.2), non-metabolized hydrophilic carbohydrate
probes that lack affinity for intestinal mediated uptake mechanisms. These
probes are commonly used in tests of passive (non-carrier-mediated) intestinal
permeability (reviewed in Travis and
Menzies, 1992). Based on previous studies in mammals and small
birds (see above), we hypothesized that pigeons would absorb both probes to a
greater extent than rats, and we predicted that both species would absorb
L-arabinose (smaller molecular size) more than
L-rhamnose, consistent with the sieving characteristic of the tight
junction (reviewed by Chediack et al.,
2003).
To ensure that higher absorption in the pigeon was not due to mediated
uptake of presumed paracellular probes, we tested whether uptake of tracer
amounts of the probes by everted intestinal sleeves in vitro were
inhibited by high concentrations of either the carbohydrate probes themselves
or D-glucose. Because greater absorption can occur simply due to
longer contact time with the gut epithelium
(Lennernas, 1995) as well as
differential gastric evacuation rates, we used isolated perfused intestinal
loops to test whether differences in absorption of these same probes are
maintained at the level of the tissue perfused at the same rate. We also
predicted that clearance of L-arabinose from perfusion solutions
would be greater than L-rhamnose in both species, comparable to our
predictions in whole animal experiments.
Pappenheimer and Reiss's revised version of the Kedem–Katchalsky
equation (Kedem and Katchalsky,
1958; Pappenheimer and Reiss,
1987) of clearance of a probe through porous epithelia predicts
that a greater solvent flow rate and/or a larger tight junction effective pore
size may explain higher clearance in pigeons vs rats. Tight
junctional proteins (Schneeberger and
Lynch, 2004) that form a sieve with larger effective apertures
would allow greater clearance, and thus more extensive paracellular
absorption, of both small and large probes. The clearance of carbohydrate
probes in rats becomes very low for molecules larger than the disaccharide
lactulose, of Mr=342 and molecular radius ca. 0.49 nm
(Hamilton et al., 1987).
Therefore, also using isolated perfused loops of intestine, we compared both
pigeons and rats for clearance of large molecular mass probes (cellobiose:
Mr=342.3; raffinose: Mr=594.5). If
pigeons have more extensive paracellular transport because of increased
solvent flow, then one might expect greater net water flux under physiological
conditions (isosmotic perfusion solutions). Consequently, we also measured net
water flux under conditions in which carbohydrate probe absorption was higher
in pigeons than in rats, also using isolated intestinal loops.
Because higher absorption at the level of either the whole animal or per unit length of intestine could occur due to increased nominal surface area (the area of a smooth bore tube), increased mucosal surface area (due to magnification by villi), or increased number of tight junctions, we compared intestinal morphometric measures in the two species.
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Material and methods |
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300 g) were purchased from a Wisconsin breeder (Earl
Ditsch Farm, Oregon, WI, USA). Pigeons had access to ad libitum water
and pelleted pigeon feed (Purina Pigeon Checkers, Purina Mills, Inc.,
Richmond, IN, USA). Pigeons were housed singly in cages under relatively
constant environmental conditions (20.9±0.1°C, relative humidity of
48.4±0.1%) on a diurnal light schedule of 15:20 h:8:40 h light:dark
(05:20 h–20:40 h light; 20:40 h–05:20 h dark). All animals were
acclimated to the laboratory for at least a week before they were used in
experiments. The University of Wisconsin College of Agricultural and Life
Sciences Animal Care and Use Committee approved all animal care and
experimental procedures for this study.
Test compounds
Carbohydrates were purchased from Sigma Chemicals (St Louis, MO, USA):
L-arabinose (Mr=150.1), L-rhamnose
(Mr=164.2), mannitol (Mr=182.2),
D-glucose (Mr=180.2), L-glucose
(Mr=180.2),
3-O-methyL-D-glucose
(Mr=194.2), lactulose (Mr=342.3),
cellobiose (Mr=342.3), raffinose
(Mr=594.5) and stachyose (Mr=666.6).
Radiolabeled chemicals were purchased from American Radiolabeled Chemicals
Inc. (ARC, St Louis, MO, USA) and NEN (PerkinElmer Life Sciences, Boston, MA,
USA).
Fractional absorption of probes measured in vivo
The night before a trial (during the animals' normal inactive period), food
was withheld. Prior to administration of the gavage solution containing test
molecules, rats and pigeons were gavaged twice (2.5 ml each for rats, 3.0 ml
each for pigeons) with an isosmotic solution (rats: 290 mmol
kg–1, pigeons: 350 mmol kg–1) containing 30
mmol l–1 NaCl, 10 mmol l–1
D-glucose and mannitol [either 280 mmol l–1 for
pigeons or 230 mmol l–1 for rats, to be isosmotic with avian
and mammalian plasma, respectively
(Charkoudian et al., 2005;
Goldstein and Zahedi, 1990)].
Animals were then gavaged with an isosmotic solution containing 30 mmol
l–1 NaCl, 40 mmol l–1
3-O-methyl-D-glucose, 40 mmol l–1
L-arabinose and 40 mmol l–1 L-rhamnose
at a dose of 1.0% body mass. Other inert probes (mannitol, lactulose,
raffinose and stachyose) and NaCl were included in the solution to balance
osmolality. Inclusion of Na+ also provides an essential ion for
Na+-coupled D-glucose absorption, although it is not
strictly necessary in this kind of whole-animal study because animals would
still absorb nearly all glucose even if the diet is low in Na+;
this is because additional Na+ is secreted into the intestinal
lumen together with bicarbonate and diffuses from blood
(Brody, 1999). In a separate
experimental trial, rats and pigeons were injected (0.6% body mass) with 2.5
mmol l–1 NaCl, 50 mmol l–1
3-O-methyl-D-glucose, 50 mmol l–1
L-arabinose and 50 mmol l–1 L-rhamnose.
The injection site was the pectoralis muscle in pigeons and the peritoneal
cavity in rats. Blood samples were collected at t=0 (background), 5,
10, 15, 20, 30, 45, 60, 90, 150 and 240 min post-injection or -gavage.
Syringes were weighed before and after dosing animals to determine the actual
dose administered. Osmotic pressures of solutions were measured (Wescor VAPRO
5520, Logan, UT, USA) prior to administration and averaged 320±7 mmol
kg–1 for rats and 365±3 mmol kg–1 for
pigeons to be isosmotic with mammalian and avian plasma, respectively
(Charkoudian et al., 2005;
Goldstein and Zahedi,
1990).
Pharmacokinetic calculations of absorption
The plasma concentrations C (ng probe mg–1
plasma) were plotted as a function of sample time t (min). The probe
amounts absorbed were calculated from the areas under the post-gavage and
post-injection plasma curves (AUC=area under the curve of plasma probe
concentration vs time). Fractional absorption (F) was
calculated as F=(AUC by gavage/dosegavage)/(AUC by
injection/doseinjection) (Ritschel, 2004). This method of
calculating F relies on no major assumptions about compartments or
kinetics. Using typical pharmacokinetic procedures (Ritschel, 2004) the AUC
from t=0 to t=x min (time of final blood sampling)
was calculated using the trapezoidal rule. The AUC from t=x
min to t=
was calculated by dividing Cx
(plasma concentration at time of final blood sampling) by
Kel. Kel is the rate constant
describing the probe loss from the systemic circulation by elimination. This
parameter was estimated by regressing the last two log-transformed plasma
concentrations C (ng probe mg–1 plasma) against
t (min) and calculating the slope. The time course was analyzed
assuming first order elimination. The peak concentration post-injection
reflects the effective pool size and the rate of distribution relative to the
rate of elimination. The injection data could be used to calculate the
effective pool size and rate of elimination, which indeed may differ between
the species. The AUC method to measure fractional absorption, however,
accounts for such differences.
Everted sleeve uptake experiments
We measured uptake of [14C]L-arabinose,
[3H]L-rhamnose, [3H]lactulose,
[3H]- or [14C]L-glucose and
[14C]D-glucose into the tissue across the brush-border
membrane as described elsewhere (Chang et
al., 2004; Karasov and
Diamond, 1983) and as previously applied in laboratory rats
(Green et al., 2005;
Karasov and Debnam, 1987) and
pigeons (Obst and Diamond,
1989). The first four radiolabeled solutes are thought to be
absorbed passively via the paracellular pathway, and thus their
uptake should not be inhibitable by either themselves or by unlabeled
D-glucose, whereas radiolabeled D-glucose uptake should
be inhibitable by unlabeled D-glucose (our positive control). Thus,
our goal in these experiments was not to measure passive absorption in this
preparation of isolated tissue (it is not suited for this measurement), but to
confirm that the first four solutes are not absorbed by an active or mediated
process. We routinely inspected adjacent tissue sections histologically for
signs of villus damage (Green et al.,
2005; Starck et al.,
2000). Briefly, 1 cm sleeves of everted tissue were preincubated
for 5 min in 40°C Ringer's solution and suspended for 4 min (in the case
of D-glucose uptake, 2 min) over a stir bar spinning rapidly in a
solution containing the labeled probe and either 100 mmol l–1
mannitol (the control), 100 mmol l–1 D-glucose or
100 mmol l–1 of the respective unlabeled probe. Incubation
solutions also contained (in mmol l–1) 100 NaCl, 4.7 KCL, 2.5
CaCl2, 1.2 KH2PO4, 1.2 MgSO4, and
20 NaHCO3 and made isosmotic (rats: 290 mmol kg–1;
pigeons: 350 mmol kg–1) with mannitol, and were oxygenated
with 95% O2 and 5% CO2. After incubation, issues were
blotted, removed from the rod, weighed, incubated in tissue solubilizer
(Soluene-350, Packard, Meriden, CT, USA), and counted in a scintillation
cocktail (ICN Ecolume with 5% acetic acid; Irvine, CA, USA). To correct for
non-absorbed solute in adherent mucosal fluid, we used tracer concentrations
of membrane-impermeable marker {1,2-[3H]polyethylene glycol (PEG),
Mr=4000}.
Recirculating intestinal perfusions
Animals were anesthetized with isoflorane (2–4.5%) and oxygen
(1–2 l min–1) delivered by an anesthesia machine
(Surgivet Anesco Isotec 4, Waukesha, WI, USA) and maintained at a constant
body temperature of 37–38°C using an electric heating pad and a
Deltaphase isothermal pad (Braintree Scientific, Inc., Braintree MA, USA). A
peritoneal incision was made and a 5 cm segment (pigeons) or an 18 cm segment
(rats) of intestine distal (1–2 cm) to the stomach was identified and
cannulated at proximal and distal ends with flexible plastic tubing. We
perfused the proximal region of the small intestine because isolating more
distal gut sections in pigeons would require additional invasive procedures
that would risk puncturing air sacs. A solution of 0.9% NaCl was flushed
through the segment to remove digesta. A prewarmed Ringer's solution (included
70 mmol l–1 Na+) containing 50 mmol
l–1 D-glucose, tracer amounts of
[14C]D-glucose and 1.5 mmol l–1 each of
L-arabinose, L-rhamnose, cellobiose and raffinose, was
constantly stirred and recirculated using a Manostat Carter 8/3 cassette pump
(Barnant Company, Barrington, IL, USA) through the intestinal loop for 3 h at
1 ml min–1 [methods based on Ma et al.
(Ma et al., 1991)]. We
included 50 mmol l–1 D-glucose in the perfusion
solution in order to more saturate Na+-D-glucose
transporters and maximize paracellular absorption
(Pappenheimer, 1993;
Pappenheimer and Reiss, 1987).
Osmotic pressures of solutions were measured (Wescor VAPRO 5520) prior to
administration and isosmotic solutions averaged 290±2 and 354±1
mmol kg–1 for rats and pigeons, respectively. The initial
perfusion volume was 30–40 ml and aliquots of 0.7 ml were taken at
time=0 and every 30 min and weighed. The incision site was covered with
moistened gauze and plastic wrap and was periodically moistened with warmed
saline solution (0.9%). The perfusate was weighed pre- and post-perfusion. Air
was pumped through the gut segment after the perfusion was complete until all
fluid returned to the perfusion reservoir (enclosed to eliminate evaporative
loss). The animal was euthanized with CO2, and the length of the
perfused segment was measured. After 2 h (when probe clearance was
calculated), there was no significant difference between final paracellular
probe concentrations between species (F1,31=0.28;
P=0.60). Mean final concentrations for L-arabinose,
L-rhamnose, cellobiose and raffinose (in mmol l–1)
were 1.1±0.2, 1.3±0.1, 1.4±0.04 and 1.6±0.2 for
pigeons, and 0.8±0.1, 1.4±0.1, 1.4±0.04 and
1.6±0.1 for rats. Pigeons had a significantly greater final
concentration of D-glucose than rats (in mmol l–1:
pigeons: 44.9±1.9; rats: 27.3±2.7; t5=11.9;
P<0.001). We did not check villus morphology in segments from
perfused animals, but the measured rates of D-glucose absorption
did not significantly decline over the course of our experiment (first hour
vs second hour within animals: t10=–2.0;
P=0.07).
Radionuclide activity in samples was measured by scintillation counting
(Wallac Winspectral 1414, PerkinElmer Life and Analytical Sciences, Inc,
Wellesley, MA, USA, using ICN Ecolume scintillation fluid, ICN, Irvine CA,
USA) and concentration of inert probes was measured using High Performance
Liquid Chromatography (HPLC; see below). Net water flux was determined by
subtracting the perfusate mass post-perfusion from mass pre-perfusion and was
normalized to length of intestine loop and total time of perfusion [net water
flux values are reported as µl min–1 cm–1
(see Krugliak et al., 1989;
Ma et al., 1991)]. Negative
values of net water flux indicate net water secretion, and positive values
indicate net water absorption. The perfusion reservoir was sealed to eliminate
evaporative loss, and no radioactivity was detected in the peritoneal cavity
of animals after perfusions (indicating no leakage of perfusate). Carbohydrate
probe absorption was measured as loss from the perfusate
min–1 perfusion cm–1 intestine, according to
the following equation:
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; Sadowski and
Meddings, 1993). D-glucose absorption is expressed as a
rate of absorption (nmol min–1 cm–1) because
it is absorbed by both active and passive processes.
Morphological measurements
Animals were euthanized with CO2, and their gastrointestinal
tract (distal to stomach) was removed. Total length of small intestine (cm)
was measured, as was the circumference (cm; 1–2 tissue sub-sections were
used for circumference measurements in each third of intestine). Nominal
surface area (cm2) was calculated as the sum of the products of the
lengths of the thirds multiplied by the average circumference for the third of
the intestine. Adjacent segments to those segments used for measurement of
circumference were fixed in 10% formalin, and 5 µm sections were cut on
glass slides and stained with Haematoxylin and Eosin (H&E). Measurements
of villus amplification ratio (increased area due to villi) were based on the
calculation in Kisielinski et al.
(Kisielinski et al., 2002).
Briefly, the villus length, villus width and crypt width of 25 villi per
animal were measured at 40x total magnification using ImageJ software
(Abramoff et al., 2004).
The number of enterocytes per unit length villus (10 villi per animal) was counted using light microscopy at 400x total magnification. The density was multiplied by the average area of a villus, the nominal surface area, and the villus amplification ratio to yield the total number of intestinal enterocytes in the small intestine.
Analyses
Plasma and perfusion sample analysis
Blood samples were centrifuged and plasma samples were loaded into
preweighed 1.5 ml microcentrifuge tubes equipped with 30K Nanosep filters
(Pall Corporation East Hills, NY, USA). Plasma was initially filtered with 50
µl dH2O (14 000 g for 30 min), followed by a
rinse step with an additional 100 µl dH2O (14 000
g for 140 min) to ensure high carbohydrate probe recovery.
Plasma samples were subsequently dried at 65°C and stored frozen at
–80°C until analysis.
Carbohydrate probes (L-arabinose, L-rhamnose and
cellobiose) in plasma and perfusion samples were derivatized for HPLC
fluorescence detection by reductive amination with anthranilic acid
(2-aminobenzoic acid), following published procedures
(Anumula, 1994;
Du and Anumula, 1998), with
minor modifications. Briefly, dried plasma samples were reconstituted with 50
µl dH2O or an aliquot of 50 µl of perfusion solution was
removed and mixed with 50 µl of anthranilic acid reagent solution. The
anthranilic acid reagent consisted of 30 mg ml–1 anthranilic
acid and 20 mg ml–1 sodium cyanoborohydride dissolved in a
previously prepared solution of 5% sodium acetate·3H2O and
2% boric acid in methanol. Samples were transferred to a screw-cap glass
autosampler vial and heated at 65°C for 3 h. After cooling to ambient
temperature, 300 µl of HPLC solvent A (see below) was added to vials, which
were mixed vigorously in order to expel the hydrogen gas evolved during the
derivatization reaction.
The carbohydrates in derivitized plasma samples were separated by HPLC
(Beckman-Coulter 508 Autosampler, System Gold 126 Solvent Module, 32 Karat
Software, v. 5.0, Build 1021, Beckman-Coulter, Fullerton, CA, USA). 20 µl
of derivitized plasma samples was injected on a C-18 reversed phase column
(Water Pico Tag; 150x3.9 mm; Waters Corporation, Milford, MA, USA)
maintained at 23°C (Alltech 530 column heater, Alltech Associates, Inc.,
Deerfield, IL, USA) using a 1-butylamine-phosphoric acid-tetrahydrofuran
mobile phase system at a flow rate of 1 ml min–1. Solvent A
consisted of 0.2% 1-butylamine, 0.5% phosphoric acid, and 1% tetrahydrofuran
(inhibited) in HPLC grade water [18.2 M
resistance produced in-house,
further filtered through a 0.45 µm hydrophilic polypropylene membrane
filter (GH Polypro, Pall Gelman Sciences, Ann Arbor, MI, USA), or purchased]
and solvent B consisted of equal parts solvent A and HPLC grade acetonitrile.
Table 1 describes the gradient
elution program used for the separation. Carbohydrate probes in plasma samples
were quantified by a fluorescence spectrophotometer with the following
settings: excitation wavelength 230 nm, slit width 10 nm; emission wavelength
425 nm, slit width 5 nm; sensitivity=1; `normal' setting for lamp mode,
photomultiplier gain and response time
[(Anumula, 1994); Perkin-Elmer
650-LC, PerkinElmer Life Sciences, Inc., Boston, MA, USA].
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Aliquots of perfusion samples were filtered using Pall Life Sciences Acrodisc LC 13 mm diameter syringe filters with 0.2 µm PVDF membranes (VWR International, Buffalo Grove, IL, USA). 10 µl of filtered perfusion samples was injected on a Prevail Carbohydrate ES column maintained at 23°C (Alltech 530 column heater, Alltech Associates, Inc., Deerfield, IL, USA). Cellobiose and raffinose were quantified by an Evaporative Light-Scattering Detector (Alltech ELSD 500). The mobile phase was 70% acetonitrile and 30% HPLC grade water (see above). Samples had an HPLC time program with a 0.5 min gradient down to 60% acetonitrile and 40% water and a 5 min equilibration back to the initial ratio of solvents. Clearance of cellobiose from the perfusion solution was the same regardless of detector (ELSD=1.82±1.38 µl min–1 cm–1; fluorescence spectrophotometer=2.81±0.43 µl min–1 cm–1; t10=0.81; P= 0.44). Clearance of cellobiose detected via the fluorescence spectrophotometer is reported in the Results.
Statistical analysis
Results are expressed as means ± s.e.m. Estimates of F were
arcsin-square-root transformed prior to statistical analyses. F
estimates greater than 1 were set to equal 1 (applicable only to
3-O-methyl-D-glucose). For some analyses, F and
clearance of probes were normalized to the square root of the molecular mass
of the probe to correct for differences in diffusivity
(Smulders and Wright, 1971).
For tissues incubated in various solutions, uptake values (µl
mg–1 min–1) were normalized to those for
adjacent tissues incubated in mannitol (the control) and one sample one-tailed
t-tests were conducted to determine if the normalized uptake was
significantly different from 1. Repeated-measures analysis of variance (R-M
ANOVA: Systat Version 10, Systat Software Inc., Point Richmond, CA, USA) was
used to test for differences in probe absorption and uptake, as well as net
water flux between rats and pigeons, and to test for the effect of probe size
on absorption.
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Results |
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90% of
elimination occurring over the course of the 4 h experiment
(Fig. 1). Fitting the
elimination data to a mono-exponential elimination model gave values of
r2>0.99 for L-rhamnose,
L-arabinose and 3-O-methyl-D-glucose in both
rats and pigeons, which supports our method of estimating the residual AUC
past 240 min using the apparent elimination rate constants
(Kel; see Materials and methods). The elimination rates in
the injection trials did not differ significantly from those in the gavage
trials (Table 2). Fractional
absorption was calculated for each carbohydrate by comparing AUCs from gavage
trials to those from injection trials
(Table 2). Pigeons absorbed
significantly more L-arabinose and L-rhamnose than rats,
and both rats and pigeons absorbed L-arabinose significantly more
than L-rhamnose. The difference between L-arabinose and
L-rhamnose was significant even after correction for their
different molecular masses (F1,10=29.3;
P<0.001). Absorption of 3-O-methyl-D-glucose
was nearly complete and did not differ significantly between pigeons and rats
(Table 2).
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Test for mediated uptake of probes
Because pigeons absorbed more L-arabinose and
L-rhamnose than rats in the previous experiments, we used
competitive inhibition tests to determine whether some absorption of these
solutes might be mediated in pigeons but not in rats. In positive control
experiments with both pigeons and rats, [14C]D-glucose
uptake by everted sleeves in vitro was significantly inhibited when
sleeves were incubated with 100 mmol l–1 D-glucose
compared with 100 mmol l–1 mannitol (the control) for both
rats and pigeons (for rats: t4=–55.1;
P<0.001; pigeons: t5=–24.3;
P<0.001). In contrast, the uptake of putative paracellular probes
was not significantly inhibited when tissues were incubated in the presence of
either 100 mmol l–1 D-glucose or the solutes
themselves (P>0.05), with two exceptions
(Fig. 2). In laboratory rats,
[3H]L-rhamnose was significantly inhibited by 100 mmol
l–1 D-glucose (t5=–14.7;
P<0.001), and in pigeons [3H]lactulose was
significantly inhibited by unlabeled lactulose
(t5=–3.0; P=0.016). There was no
significant difference in total D-glucose uptake between rats and
pigeons (F1,8=0.62; P=0.45;
Fig. 2).
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). There was no
significant difference between pigeons and rats in absorption of
D-glucose (respectively, 331±58 nmol min–1
cm–1 and 357±22 nmol min–1
cm–1; t5=–0.47;
P=0.66).
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Under conditions where pigeons had significantly greater clearance of small probes, rats had significant net water absorption (mean net water flux=1.50±0.27 µl h–1 cm–1 (t5=5.5; P=0.003) yet pigeons neither had net water absorption nor secretion (mean=–0.30±0.030 µl h–1 cm–1; t5=–1.0; P=0.37 for difference from zero). Rats had significantly greater net water absorption than pigeons (t10=–4.4; P=0.001).
Test for difference in gut morphometrics
Pigeons had significantly shorter small intestines than rats (pigeons:
60.3±2.9; rats: 89.1±4.06; t3=–14.7;
P=0.001). The average circumference along the length of the small
intestine was larger in the pigeon compared with the rat (pigeons:
1.16±0.06; rats: 1.05±0.01; t3=3.83;
P=0.03), but not enough to compensate for shorter length. Pigeons had
significantly less small intestine nominal surface area than rats (pigeons=
68.6±5.3 cm2; rats=93.1±3.7 cm2;
t8=–3.4; P=0.01), and the mucosal surface
enlargement factor was not significantly different between the species
(pigeon=8.93±0.87; rat= 7.45± 0.65; t8=1.2;
P=0.25). The number of small intestine enterocytes in pigeons and
rats were not significantly different from each other
(pigeons=1.5x108±2.1x107;
rats=1.6x108±8.4x106;
t8=–0.4; P=0.69), but pigeons had a
marginally greater density of enterocytes than rats (no. cells
mm–1; pigeons: 166±5.5; rats: 154±3.67;
t3=3.4; P=0.04).
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Discussion |
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TOPSummaryIntroductionMaterial and methodsResultsDiscussionReferences |
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Pigeons exceed rats in paracellular absorption at the whole-animal level
We hypothesized that pigeons would have greater absorption of inert
carbohydrate probes compared to laboratory rats, based on previous studies of
small birds (<200 g) that showed relatively efficient absorption
(56–90%) of water soluble carbohydrates whose absorption is thought to
be passive and not mediated, such as L-glucose
(Afik et al., 1997;
Caviedes-Vidal and Karasov,
1996; Karasov and Cork,
1994; Levey and Cipollini,
1996) and L-arabinose and L-rhamnose
(Chediak et al., 2003). Indeed, intact pigeons absorbed twice as much
L-arabinose and L-rhamnose as did intact laboratory
rats. Because these molecules presumably permeate across the small intestinal
mucosal epithelium primarily through the paracellular pathway
(Powell, 1987), and because
paracellular transport involves movement of compounds across the
size-selective tight junction inbetween intestinal epithelial cells
(Powell, 1987), we also
expected, and found, that the smaller probe (L-arabinose,
Mr=150) was absorbed more readily than the larger probe
(L-rhamnose, Mr=164) in both species.
The greater absorption of L-arabinose and L-rhamnose that we measured in the pigeon as compared to the rat was not simply a general artifact of some difference in our experimental procedure with the two species We also measured the absorption of 3-O-methyl-D-glucose, a non-metabolizable, actively transported analogue of D-glucose that is absorbed both transcellularly and paracellularly. Absorption of this compound was high (93%) and not significantly different between pigeons and rats.
Higher absorption of inert carbohydrate probes by pigeons was not due to mediated absorption
The absorption of the carbohydrate probes was higher in pigeons compared to
rats. If pigeons, but not rats, absorb the probes via active as well
as passive processes, this could explain why pigeons have more extensive
absorption of these carbohydrates than rats. In order to test this, we used
everted sleeves to measure whether the uptake of the carbohydrate probes could
be self-inhibited or inhibited by D-glucose. Lack of
self-inhibition despite inhibition by D-glucose can occur if the
transporters(s) (e.g. SGLT1, GLUT2) have higher affinity for
D-glucose than for the respective probe. Either result would
suggest that absorption of these probes is at least partially mediated. We
found that in pigeons, uptake of L-arabinose and
L-rhamnose was not competitively inhibited, but in rats,
L-rhamnose uptake was significantly reduced when 100 mmol
l–1 D-glucose was in the solution. Thus, we have
no evidence of mediated absorption of the probes that were absorbed more
extensively in intact pigeons or in perfusions of their intestines. If the rat
does exhibit some mediated absorption of L-rhamnose, then the
magnitude of the difference between rats and pigeons in the extent of
paracellular absorption of L-rhamnose would be underestimated.
Additionally, we found no significant difference in total
D-glucose uptake (active + passive) between rats and pigeons. Using
a similar technique, mediated uptake rates of D-glucose were
measured in pigeons (Obst and Diamond,
1989) and rats (Debnam et al.,
1988). Using sleeves from the jejunum in a solution with 50 mmol
l–1 D-glucose, mediated uptake rates in pigeon
tissues were 2 nmol mg–1 min–1 and in
rat tissues 375 nmol cm–1 min–1.
Assuming intestinal tissue is 95 mg cm–1
(Debnam et al., 1988), then
the rate of mediated absorption in the rat is about double that in the
pigeon.
Pigeons exceed rats in paracellular absorption at the tissue level
Conceivably, the higher paracellular absorption in intact pigeons compared
with rats is due to differences at the tissue level. It is also plausible that
there are no tissue-level differences in absorption but that digesta are
simply retained in contact with absorptive surfaces longer in the pigeon than
in the rat. Permeability of paracellular probes at the tissue level has not
been investigated in species with significant differences in paracellular
absorption based on whole animal experiments. In our study, segments of
perfused intestine indeed yielded comparable results to our experiments on
intact animals. Like our experiments on intact animals, pigeons had double the
clearance of L-arabinose and L-rhamnose than rats,
suggesting that species variations in paracellular absorption that we noted at
the whole animal level are not explained by gastrointestinal differences such
as differential gut handling or residence time. This is the first study that
we know of investigating differences in paracellular absorption in
vivo at the tissue level between species. Pigeons do not have more
extensive paracellular absorption than rats simply because there is more time
for probes to be absorbed across tight junctions
We were also able to confirm that the difference in paracellular absorption
between rats and pigeons in segments of intestine was not an experimental
artifact of measuring high absorption in pigeons generally. Absorption of
D-glucose was not significantly different between pigeons and rats.
Our values for D-glucose absorption in rats were also comparable to
other published values in rats perfused with a similar D-glucose
concentration (Meddings and Westergaard,
1989).
Effective pore size in tight junctions does not seem greater in pigeons compared with rats
Enhanced probe flux across porous epithelia might be explained by increased
effective pore size of the tight junction and/or increased paracellular
solvent flux. In order to investigate whether differences in paracellular
transport at the tissue level are due to species differences in the effective
pore size in tight junctions, we also perfused the intestine of rats and
pigeons with larger carbohydrate probes: cellobiose
(Mr=342.3) and raffinose (Mr=554.5).
Carbohydrate clearance declined with increasing Mr, but
absorption became immeasurably low for both species at the same probe
Mr, suggesting an equivalent molecular size cut-off for
pigeons and rats and thus a comparable tight junction aperture.
Can differences in water flux explain the differences in paracellular absorption?
We found no difference in clearance of large-sized probes between pigeons
and rats but a twofold difference in clearance of smaller probes
(L-arabinose and L-rhamnose), which is consistent with
higher solvent flow through the tight junctions in pigeons than in rats.
However, when the small intestine of pigeons and rats were perfused with an
isosmotic Ringer's solution containing 50 mmol l–1
D-glucose, rats, but not pigeons, had significant net water
absorption. Our values of net water absorption in rats are comparable to
fluxes measured in perfused rats in similar studies (e.g.
Fagerholm et al., 1999;
Sadowski and Meddings,
1993).
How could pigeons have comparable rates of D-glucose absorption
as rats yet with no net water absorption if the majority of
D-glucose absorption in pigeons is paracellular? Comparative
measures of net water flux do not provide a strong test of the hypothesis that
differences in solvent flux through the tight junction underlie differences in
paracellular solute absorption. We used net water flux as a proxy for
determining paracellular net fluid movement, but there is no known direct
method to determine the pathway of water movement in the small intestine, and
the molecular mechanisms and relative importance of paracellular and
transcellular fluid movement are unclear. It is thought that water moves
passively across the tight junction or the cell membrane due to osmotic
gradients created by solute absorption
(Masyuk et al., 2002), but
there is only indirect evidence and theories to support transcellular
(Loo et al., 1996;
Meinild et al., 1998;
Ramirez-Lorca et al., 1999;
Zeuthen et al., 2001;
Zeuthen et al., 1997) or
paracellular (Fromter and Diamond,
1972; Pappenheimer and Reiss,
1987; Powell,
1987) modes of fluid transport. In future studies, it would be
interesting to compare differential expression of aquaporin isoforms
(Ma and Verkman, 1999) between
rats and pigeons as well as differences in water flux via SGLT1
(Zeuthen et al., 1997) between
mammals and birds. Even if fluid transport occurs solely by the paracellular
pathway, our measurements of net water flux may not indicate that rats have
more extensive (paracellular) water absorption compared to pigeons. Measures
of net water flux are only a proxy for net fluid movement across epithelia and
can be confounded by other physiological processes such as differential ion
absorption/secretion and unidirectional fluid movement.
Higher paracellular absorption in pigeons is not due simply to greater surface area or more tight junctions
Could small intestine morphological differences between the two species
account for differences in paracellular absorption? Pigeons had significantly
less small intestine nominal surface area than rats, which is consistent with
broader comparisons that have been made between birds and non-flying mammals
(Lavin, 2007). The mucosal
surface enlargement factor was not significantly different between pigeons and
rat, and our value of average rat mucosal surface enlargement factor is
comparable to published values (e.g.
Fisher and Parsons, 1950). The
number of small intestine enterocytes (a proxy for the number of tight
junctions) also was not significantly different between rats and pigeons.
There was a trend for more absorptive surface per length of intestine in
pigeons compared with rats (based on enterocyte density), but uptake of
D-glucose was not significantly greater per unit length of
intestine, suggesting that enhanced absorption is not a consequence. While
pigeons had higher absorption of L-arabinose and
L-rhamnose at both the whole animal level and in perfused
intestinal segments, pigeons have less small intestine nominal surface area
and comparable villus amplification and number of tight junctions than rats,
suggesting that pigeons have higher tight junction permeability to
carbohydrate probes.
Functional significance of differences in paracellular absorption
We used our data on intestinal paracellular permeability and total
D-glucose absorption at 50 mmol l–1 to estimate
the proportion of D-glucose clearance that was paracellular in
pigeons and rats. We used the Renkin molecular sieving function
(Renkin, 1954) and our
clearance data on L-rhamnose to estimate paracellular permeability
for D-glucose, which has a larger Mr and
molecular radius than L-rhamnose. The Renkin function relates
relative flux to the molecular radii of solutes in relation to an effective
cylindrical pore radius of the tight junction. We used our values for
L-rhamnose clearance and physiologically reasonable values for the
effective pore size of the tight junction (minimum radius=7 Å; maximum
radius=14 Å) based on human small intestine, which has an estimated pore
radius of 8–13 Å (Fine et al.,
1995). We also corrected for differences in L-rhamnose
and D-glucose diffusivities in free solution using M
1/2r (Smulders and
Wright, 1971) and used estimated molecular radii of 3.6 Å
and 4.0 Å for L-rhamnose and D-glucose,
respectively (Fagerholm et al.,
1999; Hamilton et al.,
1987). We estimated the minimum (pore size=7 Å) and maximum
(pore size=14 Å) percentage of total D-glucose absorbed
paracellularly to be 8±2% and 11±3% in rats and 42±12%
and 59±16% in pigeons. Our method of estimating passive
D-glucose absorption using data on L-rhamnose, which has
a smaller molecular size is a more sophisticated way of correcting for
differences in molecular size between probes than simply using the square root
of the molecular mass. But even if we use that simpler approach, the
conclusions hold. These might be slight overestimates if the absolute rate of
mediated absorption is depressed due to anesthesia
(Uhing and Kimura, 1995), but
the estimate of the proportion of absorption that is paracellular in pigeons
is high and comparable to other measurements in intact avian species: >80%
in 120-g rainbow lorikeets [Trichoglossus haematodus
(Karasov and Cork, 1994)], and
>70% in 25-g house sparrows [Passer domesticus
(Chang and Karasov, 2004)].
Based on our measurements in anesthetized, perfused pigeons and rats, combined
with our findings in intact, whole animals, the extent of paracellular
absorption of small water soluble nutrients such as monosaccharides and amino
acids is likely high in the pigeon and at least double that of the rat.
Differences in paracellular permeability are not limited to between species,
but also within species [e.g. human diseased states
(Vogelsang et al., 1998);
human developmental stages (Beach et al.,
1982)].
Although it is tempting to use a mathematical approach (e.g. the Renkin
function or Pappenheimer's revised Kedem–Katchalsky model) to compare
distributions of pores for specific probe sizes between species or to
extrapolate probe clearances to get estimates for pore radii (and thus
molecular radii at which probe clearance would be 0), we would have to make
certain assumptions, for example that probe absorption is a consequence of
diffusion or solvent drag (not both) through a porous membrane. Yet Fine et
al. (1994) attributed passive
absorption to both solvent drag and diffusion (but see above for caveats
regarding the use of net water flux to study solvent drag). Furthermore, the
Renkin model assumes a single pore with a single pore size, but some authors
have suggested that there could be populations of more than one pore size or
type (He et al., 1998).
Differential pore sizes/types could be another mechanism explaining difference
between rats and pigeons.
Another nutritional significance of our findings concerns absorption of
water-soluble compounds such as toxins and naturally occurring secondary
chemicals in foods (Harborne,
1993). An interesting future study could compare permeability of a
toxin between these species. Our results suggest a rather similar effective
molecular size discrimination in pigeons and rats, with relatively little
absorption in either species of compounds larger than Mr
of about 350 Da and molecular radius 4.8 Å. Note, however, that based on
our measurements we cannot determine whether this arises because of features
of effective pore radius and/or solvent drag. Thus, whereas there does not
seem to be significant absorption for water-soluble solutes of
Mr>350 at the whole animal level and at the tissue
level, it is not clear whether comparable tight junction size discrimination
between species accounts for this finding.
Our data are unique in that they suggest that differences in absorption of water-soluble compounds such as L-arabinose and L-rhamnose that are observed in intact whole animals also occur at the level of the tissue. The lack of evidence for mediated absorption of either compound in the pigeon, and the pattern of size dependency in absorption that is consistent with molecular sieving, are also consistent with the idea that these compounds are absorbed by the paracellular route. The greater absorption in pigeons than in rats, is not explained by greater small intestine surface area or more tight junctions in the pigeon, and therefore implies greater paracellular permeability in the pigeon. But, until methods are developed to measure paracellular fluid flux directly, it remains uncertain whether the underlying mechanism(s) for the difference in paracellular absorption is enhanced fluid movement across the tight junction or greater tight junction effective pore size. Whatever the exact mechanism, the paracellular pathway of both species limits absorption to molecules in the size range of glucose and amino acids, and the pathway appears to account for the majority of D-glucose absorption in the pigeon, but less in the rat.
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