First published online June 11, 2007
Journal of Experimental Biology 210, 2033-2045 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.000976
Physiological and morphological responses to feeding in broad-nosed caiman (Caiman latirostris)
J. Matthias Starck1,*,
Ariovaldo P. Cruz-Neto2 and
Augusto Shinya Abe2,3
1 Department of Biology, University of Munich (LMU),
Munich, Germany
2 Department of Zoology, State University of São Paulo, Rio Claro,
Brazil
3 CAUNESP, State University of São Paulo, Rio Claro,
Brazil
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Fig. 1. Anatomy and ultrasonography of broad nosed caiman. (A) Chequerboard pattern
of ventral scales and marks for application of the ultrasound scanner head (B)
Partial situs of the body cavity. Black bars in A and B indicate scanner head
position resulting in the images in C, D and E; (C) duodenum and liver (D).
(C–E) Ultrasound anatomy of the duodenum (C), distal small intestine
(D), and liver and gall bladder (E). Ultrasound anatomy of the liver and gall
bladder. Abbreviations: ab, adipose tissue body; dd, duodenum; gb, gall
bladder; L, liver; m, ventral muscles; si, distal small intestine; sto,
stomach. The scanner head was positioned on the ventral scales of the caiman,
thus in the ultrasonographs (C–E) ventral is at the top and dorsal is at
the bottom. Green lines in C–E indicate the morphometric measurements.
Scale bars, 1 cm (C–E).
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Fig. 2. Changes in the thickness of the mucosa in the duodenum as measured by
ultrasonography. Black symbols with negative error bars represent values from
caimans that were first feed then fasted, white symbols with positive error
bars are values from caimans fasted for 3 months then feed a single meal.
Values are least square means ± s.e.m. derived from RM ANCOVA; for raw
data see Table 1. Arrows
indicate feeding events for each experimental group.
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Fig. 3. Changes in the thickness of the mucosa in the distal small intestine as
measured by ultrasonography. Black symbols with negative error bars represent
values from caimans that were first feed then fasted, white symbols with
positive error bars are values from caimans fasted for 3 months then feed a
single meal. Values are least square means ± s.e.m. derived from RM
ANCOVA; for raw data see Table
1. Arrows indicate feeding events for each experimental group.
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Fig. 4. Changes of the size of the liver as measured by ultrasonography. Black
symbols with negative error bars represent values from caimans that were first
feed then fasted, white symbols with positive error bars are values from
caimans fasted for 3 months then feed a single meal. Values are least square
means ± s.e.m. derived from RM ANCOVA; for raw data see
Table 1. Arrows indicate
feeding events for each experimental group.
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Fig. 5. Light microscopy and transmission electron microscopy of the duodenal
mucosa epithelium of digesting caimans. Enterocytes are filled with lipid
droplets and arranged as a single layered high prismatic epithelium. (A) Low
power light micrograph of a villus showing the typical arrangement of lipid
filled enterocytes with a well developed brush border and a large capillary in
the connective tissue core of the villus. (B) High power light micrograph of
the mucosa epithelium. Note the dense layer of lyphocytes and a large mast
cell below the epithelium. (C) High power light micrograph of the tip of a
villus with necrotic cells. Necrotic cells are enlarged as compared with
healthy enterocytes and show different degrees of lysis of the cell membranes
as well as the nuclei. (D) Low power transmission electron micrograph. Note
the dense distribution of mitochondria and lipid droplets. (E) High power
transmission electron micrograph of the brush border with pinocytotic pits at
the basis of microvilli (arrows). bb, brush border; c, capillary; eec,
enteroendocrine cell; iel, intraepithelial lymphocyte; l, lymphocytes; la,
lacteal; lp, lipid droplet; m, mitochondria; mc, mast cell; mv, microvilli; n,
nucleus of enterocytes; ne, necrotic enterocytes.
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Fig. 6. Light microscopy and transmission electron microscopy of the duodenal
mucosa epithelium of fasting caimans. The enterocytes are narrow, contain no
lipid droplets, and are arranged as a pseudostratified epithelium. The brush
border is barely visible. The connective tissue cores of the villi are broader
and more condensed than in digesting caimans. (A) Low power light micrograph,
showing the arrangement of arrangement of the enterocytes as typical
pseudostratified epithelium. Note the aggregation of lymphocytes at the base
of the middle villus. (B) High power light micrograph of the mucosa epithelium
(same magnification as Fig.
5B). (C) Transmission electron micrograph of the mucosa epithelium
with enterocytes and one enteroendocrine cell, the lumen of the gut contains
an accumulation of cellular debris. (D) Segment of the cell membrane of two
adjoining enterocytes showing folds of spare membrane (arrows). (E) Microvilli
of an enterocyte exfoliating membrane vesicles from the tip of the microvilli.
(F) Bifurcating microvilli. (G) Microvilli of the brush border disintegration,
i.e. swollen tips and formation of membrane vesicles. bb, brush border; cd,
cellular debris in lumen of gut; eec, enteroendocrine cell; gc, goblet cell;
iel, intraepithelial lymphocyte; l, lymphocytes; m, mitochondria; mc, mast
cell; mv, microvilli; mvs, membrane vesicles; n, nucleus of enterocytes; smc,
smooth muscle cell.
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Fig. 7. Changes in the absorptive surface of the duodenum (circles) and the small
intestine (squares) in feeding (filled symbols) and fasting (open symbols)
caimans. Values are means ± s.d. from N=5 animals. Differences
between the feeding and fasting condition are highly significant (see text for
details of statistics).
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Fig. 8. Light micrographs of the liver of feeding and fasting caimans. (A) Low
power micrograph of the liver of a feeding caiman. (B) High power micrograph
of the liver tubules of a feeding caiman. (C) Low power micrograph of the
liver of a fasting caiman. (D) High power micrograph of the liver tubules of a
fasting caiman. bc, bile canaliculus; bd, bile duct; h, hepatocytes; ha,
branch of the hepatic artery; k, Kupffer cell; pv, branch of the portal vein;
s, sinusoid.
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© The Company of Biologists Ltd 2007
O2 derived from
data in A. Values are means ± s.d. from all measurement intervals per
day for eight individuals. Different letters denote significant difference
according to Tukey's HSD post-hoc test for comparisons of multiple
means; 
<0.05. The grey shaded area under the curve represents SDA;
the vertical bar indicates interruption of the continuous measurements for
feeding.