|
|
|
|||||||
|
|||||||||
J. Biol. Chem., Vol. 277, Issue 9, 7170-7177, March 1, 2002
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
From the
Received for publication, August 29, 2001, and in revised form, December 18, 2001
In vitro, pancreatic triglyceride
lipase requires colipase to restore activity in the presence of
inhibitors, like bile acids. Presumably, colipase performs the same
function in vivo, but little data supports that notion.
Other studies suggest that colipase or its proform, procolipase, may
have additional functions in appetite regulation or in fat digestion
during the newborn period when pancreatic triglyceride lipase is not
expressed. To identify the physiological role of procolipase, we
created a mouse model of procolipase deficiency. The
Clps Obesity has become a major health problem in developed nations (1,
2). Increased body weight causes or exacerbates type 2 diabetes
mellitus, cardiovascular disease, and obstructive sleep apnea and
increases mortality. Although obesity probably has many causes, changes
in body weight must be modulated by balancing energy intake and energy
expenditure. In recent years, investigators have identified many
regulators of appetite and fat storage (3, 4). Some of these have
become targets for the development of drugs to treat obesity over the
long term (5). Still, there is a need to identify the regulators of
metabolic pathways where pharmacological intervention can effectively
and safely help those who have clinical obesity.
Pancreatic colipase has properties that make it a feasible target for
therapy against obesity. It may have roles in dietary fat absorption
and in the regulation of voluntary fat intake. Pancreatic colipase is a
low molecular weight, amphipathic protein with no known catalytic
activity (6). Yet, it may be essential for the efficient digestion of
dietary fats. Many components commonly found in intestinal chyme,
including bile salts, phospholipids, and dietary proteins, inhibit
pancreatic triglyceride lipase
(PTL)1 the enzyme largely
responsible for digesting dietary fats (7). In vitro,
colipase restores activity to PTL in the presence of inhibitors.
Consequently, many have presumed that efficient dietary fat digestion
in animals depends on the function of colipase as well as on the
catalytic activity of lipases (8).
A large body of evidence has accumulated to show that a peptide derived
from newly secreted colipase may act as a feedback signal to inhibit
dietary fat intake. Two observations demonstrate that the pancreas
secretes colipase as a proform, procolipase. First, two forms of
colipase have been isolated. They differ by the presence of an
amino-terminal pentapeptide in one form that is absent in the other
form. Second, the sequence from the cDNA encoding human colipase
predicts the NH2-terminal pentapeptide (9-11). In
vitro, limited trypsin digestion cleaves the pentapeptide from
procolipase to produce colipase suggesting that a similar conversion
takes place in the duodenum (12). During studies of the cleaved
pentapeptide, Erlanson-Albertsson (13) noticed that the peptide caused
weight loss when injected into rabbits. Several groups expanded this
observation to demonstrate that the pentapeptide, now named
enterostatin, decreases voluntary dietary fat intake in a variety of
animal species (13, 14). Importantly, animals given enterostatin lose
weight over time.
To address the physiological roles of procolipase, we created mice with
a targeted null allele for the gene encoding procolipase and examined
the effects of procolipase deficiency on survival, growth, and dietary
fat absorption. Procolipase-deficient mice had decreased postnatal
survival and weight gain, steatorrhea on high fat diets, and reduced
body weight even in the absence of steatorrhea. These results show that
procolipase functions in dietary fat digestion and in body weight regulation.
Targeting Construct and Generation of Mice with Null Allele for
Procolipase--
All manipulations of DNA were done by standard
methods (15). We isolated a 17-kb genomic clone from a murine 129Sv
genomic library using a full-length cDNA encoding rat
procolipase as a probe. DNA blot of restriction digests and nucleotide
sequence analysis showed that the clone contained 3 exons that encoded the entire mRNA for procolipase, 12 kb of 5'-flanking region and 1 kb of 3'-flanking region. To facilitate cloning into the targeting vector, we subcloned a 2.5-kb XbaI fragment, which contains
exons 2 and 3, into pGEM-7z and subcloned a 2.0-kb NcoI
fragment from the 5'-flanking region into pGEM-5z. The NcoI
pGEM-5z was digested with SalI and SphI, the
5'-arm was isolated by agarose gel electrophoresis and subcloned into
pBluescript. The XbaI pGEM-9z was digested with
SphI and blunt-ended with T4 polynucleotide polymerase. The product was digested with EcoRI, the 3'-arm isolated and
cloned into the EcoRI and SmaI site of 5'-arm
pBluescript. Finally, a PGK neo cassette was isolated from
pNTK after digestion with EcoRI and HindIII and
was ligated into the corresponding sites in the targeting vector
construct (Fig. 1A). The
presence of each fragment and the orientation of the 5'- and 3'-arms
was confirmed by restriction digest and by dideoxynucleotide sequence
analysis. The resulting vector was linearized and introduced into RW-4
and TC1 embryonic stem (ES) cells by electroporation as previously
described (16). We screened for targeted ES cells by DNA blot of
genomic DNA isolated from G418-resistant clones and digested with
EcoRI. The blot was hybridized to a probe derived from a
XbaI-EcoRI fragment in the 3'-flanking region of
the genomic clone and labeled by the random primer method. Positive
clones were identified for both ES cell lines. One clone from each ES
cell line was selected for blastocyst injections. Chimeric mice
resulted from each injection. The chimeras were bred to Black Swiss
mice and the offspring were screened for the targeted allele by a
polymerase chain reaction with three primers: colipase upstream,
5'-CTTTAAAGGCTCTCTCCCTCACTTGGC-3' (primer 1, Fig. 1A);
colipase downstream, 5'-TCAGGTGGAGTTCGGAGCTGTTCTCC-3' (primer 2 Fig.
1A); and neo 5'-ATCGCCTTCTTGACGAGTTC-3'(primer 3, Fig. 1A). These primers amplify a 310-bp band for the wild type allele and a 600-bp band for the null allele (Fig. 1B).
The genotype of positive offspring was confirmed by DNA blot of genomic DNA as above (Fig. 1C). Germline transmission occurred with
chimeras of both ES cell lines. Initially, mice derived from both ES
cell lines were screened and found to have identical characteristics. The data presented in this paper was generated from mice resulting from
the TC1 ES cells. The mice were of a mixed 129 × Black Swiss background.
RNA and Protein Methods--
We isolated total RNA from
pancreas, stomach, and duodenum of adult animals as described
previously (17). Twenty micrograms of total RNA was separated on
denaturing agarose gel electrophoresis and transferred to
HyBond-N+ membranes according to the manufacturers
instructions (Amersham Biosciences Inc.). A probe derived from the
entire rat colipase cDNA was labeled by the random primer method
and hybridized to the membrane with Ultrahyb (Ambion). After
hybridization, the membrane was exposed in a PhosphorImager cassette
and the bands detected with a Molecular Dynamics PhosphorImager.
To make protein extracts, the pancreas was removed from an adult mouse
and immediately homogenized in 0.5% digitonin and 10 mM
sodium phosphate, pH 6.0, containing 1 MiniComplete tablet per 10 ml
(Roche Molecular Biochemicals). The homogenate was centrifuged at
14,000 × g for 10 min at 4 °C. The supernatant was
removed and divided into aliquots. One was stored at Animal Diets--
The standard chow was PicoLabTM
5053 and contained 11.9% of the energy as fat, 23.6% as protein, and
64.5% as carbohydrate. The high fat diet was from
Bio-ServeTM and contained 56.7% of energy as fat, 15.5%
as protein, and 27.8% as carbohydrate. The fat was derived from lard
and corn oil in both diets. Ad libitum access to food and
water was allowed. The mice were adapted to either diet for at least 1 week before samples were collected. Nursing mothers were feed standard
5053 chow. Where indicated the nursing mothers were also given a
vitamin supplement (Critter Vites, Mardel Labs, Glendale Heights, IL) that contains both water-soluble and fat-soluble vitamins. The vitamins
were added to water bottles at a concentration of 1 g/liter and
replaced daily (21). The diet containing enterostatin was prepared as
described earlier (22).
Food Intake--
For measurement of food consumption, age- and
gender-matched animals of each genotype were housed individually in a
cage with wire screen floors and no bedding. They were fed the test
diet for 1 week prior to starting the experiment. Preweighed food was placed in Pyrex food cup attached to the cage floor with spring clips.
The food was weighed daily for 1 week with careful accounting of any
spillage and was replaced with a weighed portion of fresh food. The
results were recorded as grams of food consumed per gram of mouse weight.
Body Composition and Temperature--
Mice were anesthetized
with 100 mg/kg ketamine and 10 mg/kg zylaxine and scanned three times
using a Lunar PIXImus densitometer connected to a computer as
previously described (23). Heads were excluded from all analyses. Body
temperature was measured at ambient room temperature with a rectal thermistor.
Fecal Fat Analysis--
Adult mice were placed in a cage with a
metabolic screen. They were given water but no food during a 4-h
collection of feces. The collected stool was dried to a constant weight
and the fats were extracted as described (24). To obtain stool from
suckling animals, the perineum of 12-day-old mice was gently stroked
with a cotton swab to stimulate defecation. Stool was collected and processed as described for the adults.
Analysis of Lipid Classes--
Extracted fecal fats from 100 mg
of dried feces were dissolved in 1 ml of chloroform and 10 µl of each
sample was spotted onto a Silica G TLC plate. A standard mixture
containing 10 µg each of monoolien, 1,2-diolein, 1,2-diolein, and
triolein was also spotted. The plate was developed and stained as
described (25, 26).
Serum Chemistries--
Before bleeding mice were fasted for
5 h. Blood was obtained from the retro-orbital venous plexus with
a heparinized capillary tube. A core laboratory of the Nutrition
Research Unit Center measured serum levels of triglycerides,
cholesterol, glucose, and insulin.
Statistical Analysis--
The data were analyzed by Student's
t test or the Mann-Whitney Rank Sum test and by
Kruskal-Wallis One Way analysis of Variance on Ranks followed by
Dunn's method for pairwise multiple comparisons with the significance
value for multiple comparisons set at 0.05. The SigmaStat statistical
package was used for all calculations. The survival curves were
analyzed by the Kaplein-Meier method. A log-rank test was used to
compare the survival rates between the groups.
Procolipase-deficient Mice--
We confirmed the presence of a
null allele for procolipase by RNA blot and immunoblot analysis.
Because procolipase is present in the rodent pancreas, stomach, and
intestine, we performed RNA blot analysis on total RNA that was
isolated from these tissues (27, 28). Riboprobes for
procolipase-detected mRNA encoding procolipase in the pancreas,
stomach, and small intestine of the Clps+/+ and
Clps+/ Decreased Survival of Clps
We began investigating the mechanism behind the early neonatal deaths
by determining if vitamin deficiency contributed to the death of the
Clps Growth of Newborn Pups--
We next examined the rate of weight
gain in the suckling animals to ascertain if procolipase deficiency
affected growth. The Clps Growth after Weaning--
Based on in vitro studies, we
predicted that the Clps Absorption of Dietary Fats--
To determine whether procolipase
deficiency affects dietary fat absorption, we measured the amount of
fat in the feces of suckling pups and of adult mice. The stools of the
12-day-old Clps
We next identified the lipid classes by thin layer chromatography. The
extracted lipids were separated in a two-solvent, one-dimensional system and quantitatively stained with cupric acetate/phosphoric acid.
The patterns were similar for the adult and suckling mice. On the 12%
fat diet only fatty acids and variable, small amounts of a species
migrating with cholesterol esters were detected in the feces from all
genotypes indicating efficient digestion of dietary triglycerides
(data not shown.) On the 56% fat diet, diglycerides and triglycerides
comprised a much greater proportion of the lipids in the feces of the
Clps Food Intake--
The preserved rate of weight gain of the
Clps Body Composition--
We kept 5 female mice of each genotype on
the high fat diet for a period of 3 months and performed body
composition analysis by dual-energy x-ray absorptiometry. At this age,
the Clps+/+ mice weighed 31.0 ± 0.29, the
Clps+/
The Clps Metabolism--
To test whether procolipase deficiency altered
metabolism, we measured the daytime rectal temperature and serum
chemistries of Clps+/+ and
Clps Enterostatin Replacement--
The effects observed in the
Clps To determine the physiological function of procolipase
in animals, we ablated the gene encoding procolipase thereby creating mice deficient in both enterostatin and colipase. Examination of these
mice revealed several phenotypes. The Clps Procolipase in Dietary Fat Digestion--
Our data indicate that
procolipase has a central role in the balance between energy intake and
energy expenditure. It can potentially influence energy balance in
several ways. First, the presence of steatorrhea and undigested and
partially digested fecal fats indicates that procolipase has a critical
role in dietary triglyceride digestion, energy assimilation, in both
adults and newborns when fat is the main source of nutrient, as occurs
during high fat feeds or during breastfeeding (29). In adults, colipase must act as an obligatory cofactor for PTL during intestinal fat digestion. In newborns, procolipase is also required for fat digestion, but the mechanism is less clear. Although procolipase is expressed at
adult levels in this age group, PTL is not expressed until near weaning
and procolipase must have other functions in the newborn that are
independent of PTL (24).
One possibility is that colipase stimulates the activity of another
lipase in the newborn. Our earlier work suggests that procolipase may
interact with a homologue of PTL, pancreatic lipase-related protein 2 (PLRP2). PLRP2 is critical for efficient fat digestion in newborns
(24). Even though bile salts do not inhibit PLRP2 from rats, mice, or
humans, colipase does stimulate in vitro activity 1.5-4-fold depending on the substrate (30, 31). Colipase may function
to increase PLRP2 activity in newborn mice or it may interact with
another lipase. Alternatively, enterostatin and not colipase may be
required in newborns. The Clps Serum Chemistries--
We determined the effect of procolipase
deficiency on serum levels of cholesterol, triglycerides, glucose, and
insulin in animals fed either the low or high fat diets. The insulin
and glucose levels did not differ by genotype, but the glucose levels were affected by diet in the Clps+/+ mice. The
higher serum glucose level on the high fat diet suggests that the
Clps+/+ mice are developing insulin resistance.
Presumably, the Clps
Changes were also observed in serum lipids both with diet
and with genotype. As expected the cholesterol and triglyceride levels
increased with high fat diet in the Clps+/+
mice. The Clps Procolipase in Body Weight Regulation--
Another way procolipase
may influence energy balance is through regulation of the set point for
body weight (33). We base this speculation on the findings that the
Clps
Available data suggest that the deficiency of enterostatin rather than
of colipase would account for the altered body weight regulation in the
Clps
We began to address the mechanism for the reduced set point in the
Clps Survival of Clps
It remains possible that the effect of procolipase deficiency on
postnatal survival is from a lack of enterostatin, which may influence
the feeding behavior of newborns. Suckling is a complex behavior
dependent on nipple location, nipple grasping, milk ingestion, and
nipple release. Although feeding behavior and appetite are probably
regulated in newborns, the mechanisms are not understood. Many of the
pathways of appetite regulation being described in adults may not apply
to newborns whose central nervous system is still developing (4). No
studies have addressed the role of enterostatin in this process.
Newborn mice produce enterostatin and it could potentially contribute
to appetite regulation in this age group and in adults.
Conclusion--
In this report, we describe mice with a deficiency
in pancreatic procolipase. Over the first months of life, the
Clps *
This work was supported by National Institutes of Health
Grants DK53100, DK52574, and DK56341.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
Current address: 2200 Berquist Dr., Suite 1, Lackland AFB, TX 78236.
Published, JBC Papers in Press, December 20, 2001, DOI 10.1074/jbc.M108328200
The abbreviations used are:
PTL, pancreatic
triglyceride lipase;
ES, embryonic stem;
PLRP2, pancreatic
lipase-related protein 2.
Decreased Postnatal Survival and Altered Body Weight Regulation
in Procolipase-deficient Mice*
,§,,, and
Departments of Pediatrics and Molecular
Biology and Pharmacology, Washington University School of Medicine and
St. Louis Children's Hospital, St. Louis, Missouri 63110 and the
¶ Department of Cell and Molecular Biology, Lund University,
Biomedical Center, B11, S-221 84 Lund, Sweden
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
/ mice appeared normal at birth, but
unexpectedly 60% died within the first 2 weeks of life. The survivors
had fat malabsorption as newborns and as adults, but only when fed a
high fat diet. On a low fat diet, the Clps/
mice did not have steatorrhea. The Clps/
pups had impaired weight gain and weighed 30% less than
Clps+/+ or Clps+/
littermates. After weaning, the Clps/ mice
had normal rate of weight gain, but they maintained a reduced body
weight compared with normal littermates even on a low fat diet. Despite
the reduced body weight, the Clps/ mice had
a normal body temperature. To maintain their weight gain in the
presence of steatorrhea, the Clps/ mice had
hyperphagia on a high fat diet. Clps/ mice
had normal intake on a low fat diet. We conclude that, in addition to
its critical role in fat digestion, procolipase has essential functions
in postnatal development and in regulating body weight set point.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
View larger version (39K):
[in a new window]
Fig. 1.
Strategy for creating colipase-deficient
mice. Panel A, the schematic representation of the allele
that encodes procolipase, the targeting vector, and the mutant
procolipase allele is shown. The gene encoding mouse procolipase
contains only 3 exons distributed over about 3 kb. To make the
targeting vector exon 1 and a portion of intron 1 were replaced with a
neo cassette. The substitution also introduced a new
EcoRI site downstream of the neo cassette. The
positions of the relevant restriction sites are given as a single
letters. N, NcoI; X, XbaI;
E, EcoRI. The location of the PCR primers are
represented by the arrows labeled 1,
2, and 3. A line under the mutant allele
identifies the location of the probe for DNA blots. Panel B,
a representative agarose gel of the PCR products from a screen of tail
DNA. Arrows show the location of the knockout allele band
(KO) and the wild type allele band (WT). 100-bp
makers are shown. The brightest band is the 500-bp standard.
Panel C, a DNA blot of tail DNA is shown. The blot was
probed with the XbaI/EcoRI fragment from the
3'-end of the gene after the DNA was digested with
EcoRI.
80 °C until
processed and the other heated for 15 min at 65 °C to inactivate
endogenous lipases. The protein content of the extracts was determined
by the BCA method (Pierce). Twenty micrograms of protein was separated by SDS-PAGE and immunoblot for PTL and colipase was done as previously described (18). The heat-inactivated samples were assayed for the
presence of colipase as described (19). Recombinant human PTL was used
in these assays (20).
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
mice (Fig.
2A). In contrast, we detected
no mRNA encoding procolipase in the samples from
Clps/ mice. Similarly, an anti-procolipase
antibody identified a single, broad band with the same mobility as
human procolipase in the samples from the
Clps+/+ and the Clps+/
mice, but did not detect procolipase in extracts from
Clps/ mice (Fig. 2B). We also
measured colipase function in pancreatic extracts that we heated to
inactivate endogenous lipase activity. In the presence of added PTL and
taurodeoxycholate, Clps+/+ extracts had
153,000 ± 13,000 units/mg protein and the
Clps+/ extracts had 86,000 ± 5500 units/mg protein (56%). No activity was present in the extract from
the Clps/ pancreas. The results of mRNA,
protein, and function analyses confirm that we created
procolipase-deficient mice.
View larger version (19K):
[in a new window]
Fig. 2.
RNA blot and protein blot analysis of
Clps / mice. Panel A, RNA
blots of total RNA (20 µg) probed with rat colipase cDNA. The
signal from the small intestine was much lower than the signal from
pancreas and stomach and a longer exposure was required. Panel
B, an immunoblot of extracts from the pancreas of mice of each
genotype is shown. S indicates the lane with the human
procolipase standard.
/ Pups--
Out of 29 litters and 250 live births, the distribution of genotypes from
Clps+/ parents was 28%
Clps+/+, 46% Clps+/,
and 26% Clps/. Of these mice, only 102 male
mice (51%) and 98 female mice (49%) survived to weaning. When we
examined the genotype ratios of the surviving mice it was clear that
the Clps/ mice had a survival disadvantage
(Fig. 3). The survival curves revealed
that only 40% of the Clps/ pups lived until
weaning whereas more than 90% of the Clps+/+
and Clps+/ pups survived. The majority of the
Clps/ pups died between birth and 11 days
and death was independent of the litter size. None of the pups had
obvious deformities or malformations of major organs. All of the pups
had milk in their stomachs in the first day of life indicating that
they had started to feed. Similar death rates were seen in
Clps/ pups derived from the other,
independent ES clone (data not shown).
View larger version (12K):
[in a new window]
Fig. 3.
Decreased survival for
Cslp / mice.
Pups from
Clps+//Clps+/ matings
were monitored frequently and deaths recorded and tissue obtained for
genomic DNA isolation. The results are plotted as the cumulative
survival at each of the indicated time points. Nursing mothers were
maintained on the standard chow diet. Some mothers were supplemented
with vitamins from the time of mating through weaning. 69 Clps+/+ pups, 115 Clps+/ pups, 66 Clps/ pups, and 17 Clps/ Vit pups were included in the
analysis. Vit indicates vitamin supplemented. The
differences between the Clps/ mice and the
other two genotypes were significant (p = 0.001).
/ mice as reported in pups with
cholesterol 7
-hydroxylase deficiency (21). To prevent vitamin
deficiencies, we supplemented the mother's diet with vitamins from the
time she was mated until the pups were weaned. After the pups were born
we monitored their weight gain and survival. Vitamin supplementation
did not change the survival rate of the
Clps/ pups (Fig. 3) nor did it change their
rate of weight gain (data not shown). The results argue against vitamin
deficiencies as a mechanism for the early death of
Clps/ pups.
/ pups (0.33 g/days) gained weight at a significantly slower rate than the
Clps+/ and Clps+/+
pups, which were indistinguishable from each other (0.50 and 0.51 g/days) (Fig. 4A). By 20 days,
the Clps/ mice weighed 30% less than the
Clps+/ and Clps+/+
mice. The decreased weight in the Clps/ pups
was apparent in the first day of life (Fig. 4B). When we compared the weights of the surviving Clps/
pups to those of the Clps/ mice that
eventually died, we found that they had identical weights at birth, but
the non-survivors gained almost no weight over the next 4 days (Fig.
4B).
View larger version (15K):
[in a new window]
Fig. 4.
Growth of suckling mice. Pups from
Clps+/ /Clps+/
matings were weighed at varying intervals. Panel A, the
weight curves for each genotype are shown. A total of 64 Clps+/+, 108 Clps+/,
and 29 Clps/ pups were weighed. The data
points represent the mean ± 1 S.D. The differences among the
curves were tested by Kruskal-Wallis one-way analysis of variance on
ranks followed by Dunn's method for pairwise multiple comparisons.
There was no difference between the Clps+/+ and
Clps+/ pups. The
Clps/ pups were significantly smaller than
the other two genotypes (p = <0.001). Panel
B, the weights of 1- and 4-day pups are plotted for all 3 genotypes and for the Clps/ pups that did
not survive. A total of 42 Clps+/+, 75 Clps+/, 13 Clps/
surviving and 25 Clps/ non-surviving pups
were weighed at 1 and 4 days Clps+/+, 45 Clps+/, 13 Clps/
surviving, and 25 Clps/ non-surviving pups
were weighed at day 4. The data points represent the mean ± 1 S.D. There is no significant difference between the
Clps+/+ and Clps+/ pups
at either age. a, p = 0.001 compared with
Clps+/+ and Clps+/ pups
at 1 day. b, p = <0.001 compared with
Clps+/+ and Clps+/ pups
at 4 days. c, p = <0.001 compared with
Clps/ survivors.
/ adult mice would
have steatorrhea and not gain weight as well as the other genotypes.
Accordingly, we continued to record the weights of the mice after
weaning. Because other lipases could partially compensate for the lack
of PTL activity induced by procolipase deficiency, we weaned the mice
to one of two diets containing either 12 or 57% of energy as fat.
Presumably, the high fat diet would overwhelm any compensatory changes
in the levels of other lipases. The slower rate of weight gain seen in
the Clps/ pups resolved after weaning and
the Clps/ mice had a rate of weight gain
identical to that of the Clps+/+ and
Clps+/ mice. As a result, the
Clps/ mice remained smaller than the
Clps+/+ and Clps+/ mice
(p < 0.05) (Fig. 5). At
the end of the period, the Clps/ mice were
still 20-30% smaller than the wild type and heterozygous mice.
Although the Clps/ mice could maintain a
normal rate of weight gain, they never recovered from the poor weight
gain seen during the suckling period.
View larger version (34K):
[in a new window]
Fig. 5.
Growth after weaning. The
mice were weaned to a diet containing either 12% (panels on
the left) fat or 56% (panels on the
right) fat as energy. The mice were weighed at intervals and
the weights plotted versus time. The data points represent
the mean ± 1 S.D. Males (the two upper panels) and
females (the two bottom panels) were plotted separately. The
numbers of mice for each genotype were as follows. 12% fat males:
Clps+/+, 19; Clps+/ ,
35; Clps/, 8; 12% fat females:
Clps+/+, 18; Clps+/,
26; Clps/, 9; 56% fat males:
Clps+/+, 11; Clps+/,
12; Clps/, 12; 56% fat females:
Clps+/+, 10; Clps±, 15;
Clps/, 5. The Clps+/+
and Clps+/ mice were not significantly
different in any of the groups. The Clps/
mice were significantly different from the other genotypes in all of
the groups when the data was analyzed by Kruskal-Wallis one-way
analysis of variance on ranks followed by Dunn's method for pairwise
multiple comparisons. 12% fat males (p = 0.008), 56%
fat males (p = <0.001), 12% fat females
(p = <0.001), 56% fat females (p = <0.001).
/ mice were looser and more
yellow than the stools of the Clps+/+ and
Clps+/ mice. Fat analysis revealed that fat
contributes 26% of the weight in the feces from
Clps/ mice whereas the
Clps+/+ mice had 3.6% (p = <0.001) and the Clps+/ had 4.4%
(p = <0.001). The feces from adult mice on the low fat diet had the same appearance and contained 3% fat regardless of the
genotype (Fig. 5). In contrast, Clps/ mice
on the high fat diet had yellow stools and fat comprised about 23% of
the fecal dry weight in Clps/ mice compared
with 4.9% for Clps+/+ mice (p = <0.001) and to 5.5% for Clps+/ mice
(p = <0.001).
/ mice, whereas fatty acids predominated
in the feces of the Clps+/+ and
Clps+/ mice (Fig.
6B). Additionally, the feces
of the Clps/ mice contained prominent bands
comigrating with cholesterol and cholesterol ester standards. Because
the diet contains little cholesterol ester, we determined where retinyl
palmitate migrates in the solvent system and found that it co-migrates
with cholesterol ester. Thus, the fastest migrating band in the
Clps/ mice may be retinyl esters or other
lipid species that partition with the di- and triglycerides.
View larger version (19K):
[in a new window]
Fig. 6.
Fecal fat analysis. Panel A, fecal
fat was determined in adult mice on the 12% or 56% fat diet and in
suckling mice as described under "Materials and Methods." There
were no differences in the fecal fat values between male and females
mice and their results were pooled. The weight of fecal fat was
expressed as a percent of dry stool weight and plotted for each
genotype. The data points represent the mean ± 1 S.D. The number
of animals in each group was as follows. Low fat:
Clps+/+, 10; Clps+/ ,
10; Clps/, 10; high fat:
Clps+/+, 10; Clps±, 10;
Clps/, 10; suckling:
Clps+/+, 5; Clps+/, 5;
Clps/, 5. a, p = <0.001 compared with Clps+/+ and
Clps+/ mice by t test.
b, p = <0.001 compared with
Clps+/+ and Clps+/ mice
by t test. Panel B, the fecal fats were separated
into lipid classes by thin layer chromatography as described under
"Materials and Methods." Equal amounts of
[3H]triolein, which was added to each sample prior to the
extraction, were applied for each sample. The position of the lipid
standards is given on the right of the panel. MG,
monoacylglycerol; FA, fatty acids; Ch,
cholesterol; 1,2-DG, 1,2-diacylglyerol; 1,3-DG,
1,3-diacylglycerol; TG, triglycerides; ChE,
cholesterol esters.
/ mice in the face of steatorrhea
suggested that they compensated for the energy loss by eating more. To
determine whether the Clps/ mice have
hyperphagia, we directly measured food intake of each genotype. The
mice were adapted to either the low or high fat diets for 3 weeks and
to the metabolic cages for 3 days before starting the experiment.
Eight-week-old male mice were monitored for 1 week. The
Clps/ mice weighed significantly less than
the Clps+/+ and
Clps+/ mice, 19.6 ± 3.0 versus 28.0 ± 3.2 g and 30.2 ± 2.4 g,
respectively. On the low fat diet, the mice consumed similar amounts of
food (Fig. 7A). On the high
fat diet, the Clps/ mice consumed more food
over the 1-week period, 19.1 ± 2.4 g compared with 14.9 ± 1.6 g for the Clps+/+ mice and 13.0 ± 2.0 g for the Clps+/ mice
(p = 0.012 for Clps/
versus Clps+/+ and p = 0.002 versus Clps+/). When the
food intake was normalized for body weight, differences between the
Clps/ mice and the other two genotypes
became even more apparent (Fig. 7B). Based on body weight,
the Clps/ mice ate almost twice the high fat
diet eaten by their Clps+/+ and
Clps+/ counterparts.
View larger version (10K):
[in a new window]
Fig. 7.
Food intake over 1 week. Five 8-week-old
male mice of each genotype were individually housed in cages with
metabolic screens and feeding cups. The food was weighed and replaced
daily. The results were expressed as grams of food consumed during the
experiment per gram of mouse weight. The mean ± 1 S.D. were
plotted. A, food intake on a low fat diet is plotted. No
differences among the genotypes were found. B, food intake
on a high fat diet is plotted. The difference between the
Clps+/+ and the Clps+/
mice was not significant. a, p = <0.001
compared with Clps+/+ and
Clps+/ mice by t test.
mice weighed 30.9 ± 0.30, and the
Clps/ mice weighed 23.5 ± 1.1, 25%
reduced from normal weight (p = <0.001). The
Clps/ mice had significantly decreased body
fat as a percentage of the sum of lean body and fat mass compared with
the other two genotypes (p = 0.014). The percent body
fat of the Clps/ mice was 21.7 ± 2.6 and the values for Clps+/+ and
Clps+/ mice were 33.4 ± 3.1 and
30.0 ± 2.1, respectively. There was no difference in grams of
lean body mass among the genotypes.
/ mice showed other changes after
several weeks on the high fat diet. Their fur became sparse and oily.
Tufts of fur were easily plucked from the coat by pulling on the fur.
The upper face became devoid of hair and skin excoriations were
present. These lesions presumably occurred from rubbing the area while grooming. No obvious eye changes were seen as reported in the cholesterol 7-hydroxylase-deficient mice. None of these changes were
observed in Clps/ mice on the 12% fat diet.
/ mice fed either the low or high fat
diet (Table I). The body temperature did
not vary between the two genotypes regardless of the diet. We did note
differences in serum chemistries on both diets. The
Clps/ mice had higher cholesterol levels and
lower triglyceride levels than did the Clps+/+
mice. The cholesterol levels increased for both genotypes on the high
fat diet, but the triglyceride level increased only for the
Clps+/+ mice. The amount of fat in the diet did
not affect the serum triglyceride levels in the
Clps/ mice. Serum glucose differed
significantly in the Clps+/+ mice based on the
diet, but the levels did not differ between the two genotypes on either
diet. The insulin levels did not differ for any comparison.
Body temperature and serum measurements in Clps+/+ and
Clps/ mice
/ mice could result from enterostatin or
colipase deficiency or both. To test the role of enterostatin in adult
mice, we feed male mice a low fat diet supplemented with enterostatin
and monitored their weight gain and food intake over a 3-week period.
At the start of the experiment the Clps+/+ mice
weighed 28.6 ± 1.7 g and the
Clps/ mice weighed 24.5 ± 1.2 g
(p = <0.001). The Clps+/+ mice fed the
diet without enterostatin gained 0.166 ± 0.04 g/day whereas those
fed the diet with enterostatin gained 0.168 ± 0.03 g/day. The
gain was similar in the Clps/ mice,
0.150 ± 0.05 g/day without enterostatin and 0.138 ± 0.03 g/day with enterostatin (p = 0.122 compared with
Clps+/+ mice). Similarly, there was no difference in the
amount of food consumed. The Clps+/+ mice ate 77.4 ± 8.3 g total or 22.2 ± 7.0 g/g weight gained without enterostatin and consumed 78.9 ± 4.6 g or 23.2 ± 7.5 g/g weight gained with enterostatin. In comparison, the
Clps/ mice ate 76.6 ± 2.9 g or
24.6 ± 3.5 g/g weight gained without enterostatin and 78.3 ± 6.2 g or 24.0 ± 4.8 g/g weight gained with enterostatin.
These values showed no statistical differences.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
/
mice have steatorrhea that begins in pups before PTL is expressed. They
have decreased weight gain as newborns, but preserved rate of weight
gain as adults even when fed a high fat diet. Over the observation
period, the Clps/ adults never recovered the
weight from the poor weight gain as newborns and maintained their
weight at a reduced percentage of normal weight. Finally, procolipase
deficiency causes a survival disadvantage and 60% of
Clps/ pups died before weaning.
/ pups began
nursing as evidenced by the presence of milk in their stomachs, but
this study did not address the efficacy of their feeding. It remains
possible that Clps/ pups do not nurse as
often or as efficiently as littermates. Either situation would result
in decreased intake.
/ mice have not reached
this state because they have lower body fat on the high fat diet.
/ mice had lower serum
triglyceride levels on both diets compared with the
Clps+/+ mice. The low triglyceride levels on the
high fat diet are consistent with the observed steatorrhea in the
Clps/ mice. The decreased triglycerides on
the low fat diet may indicate that the procolipase-deficient mice do
have mild dietary fat malabsorption or, alternatively, they may have
altered metabolism of triglycerides because they do not have detectable
steatorrhea. Unexpectedly, the Clps/ mice
had higher serum cholesterol levels on a low fat diet than did the
Clps+/+ mice. Because serum cholesterol is
predominantly in high density lipoprotein particles, this finding
raises the possibility that procolipase deficiency alters the lipid
dynamics in a way that increases high density lipoprotein (32). One
mechanism could be by altering the turnover rates of apolipoproteins.
/ mice maintained a lower body weight,
normal food intake, and a normal rate of growth during low fat feeding
when steatorrhea was not present and that the
Clps/ mice had a normal body temperature.
The normal body temperature suggests that the total daily resting
energy expenditure for the Clps/ mice is
indistinguishable from that of the wild type mice relative to body
weight. If the body weight was lowered from the regulated level, the
resting metabolic rate and the body temperature should be lower than
expected (34). The data suggest that the
Clps/ mice display normal levels of energy
flux at a reduced body weight, which is indicative of a reduced set point.
/ mice. Enterostatin has effects on the
hypothalamus, which plays a primary role in setting the regulated level
of body energy (33). Hypothalamic mechanisms have been experimentally
manipulated to adjust the set point for body weight. For instance,
lesions of the lateral hypothalamus in rats produce a syndrome that
includes regulating their body weight at a reduced set point (33).
After the lesion, the animals initially develop anorexia and lose
weight. Shortly afterward the lesioned rats increase food intake and
weight gain, but settle at a weight that is reduced from normal.
Following a similar period of poor weight gain, the
Clps/ mice regulate their body weight at a
reduced set point. The reduced percentage of normal weight was also
observed during high fat feeding in the
Clps/ mice. To maintain the reduced set
point, the Clps/ mice on the high fat diet
compensated for the calories lost in the feces with a significant
hyperphagia whereas Clps/ mice on the low
fat diet had normal food intake.
/ mice and measured weight gain and food
intake in adult mice fed a diet supplemented with enterostatin. We
limited our study to a low fat diet to eliminate the potential
confounding effects of steatorrhea. Even though the results suggest
that enterostatin does not play an important role in mediating weight
gain or food intake in this paradigm, we cannot eliminate the
possibility that enterostatin may have a critical function in
determining the set point at an earlier age. We have begun studies with
enterostatin-deficient, colipase-sufficient mice to distinguish between
effects of enterostatin and colipase on weight gain.
/ Pups--
Finally,
our data show that procolipase is critical for normal postnatal
development. Clps/ pups had decreased weight
gain and decreased survival. Although the
Clps/ non-survivors had near normal birth
weights, they had little weight gain by 4 days or thereafter. The
explanation for the poor weight gain in non-survivors was not fully
addressed in this study, but there are several potential explanations.
Lack of feeding initiation is unlikely to cause the poor growth and
death because the non-survivors begin to nurse. Even so, decreased
intake remains a plausible explanation for the newborn deaths. Fat
malabsorption alone should not cause early death. PLRP2-deficient mice
have fecal fats about 2-fold higher than do the
Clps/ mice and the PLRP2 pups have normal
survival rates (24). Vitamin supplementation failed to reverse the
death of the Clps/ pups making it unlikely
that vitamin deficiency alone contributes to the mortality of
Clps/ pups as reported in another model of
intestinal fat malabsorption, cholesterol 7-hydroxylase-deficient
mice (21, 35)
/ mice have decreased weight gain,
steatorrhea, and decreased postnatal survival. Our results definitively
demonstrate a role for procolipase in dietary fat digestion, with and
without PTL. Additionally, procolipase may have other functions that
belie its name. The phenotype of the procolipase-deficient mice
implicates procolipase in body weight regulation and in neonatal
development. These roles are likely independent of the association
between procolipase and PTL. The procolipase-deficient mice provide a
model to test the multiple, potential functions of procolipase.
FOOTNOTES
To whom correspondence should be addressed: Washington
University School of Medicine, 660 South Euclid Ave., Campus Box 8208, St. Louis, MO 63110. Tel.: 314-286-2857; Fax: 314-286-2894; E-mail: Lowe@kids.wustl.edu.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
1.
Rosenbaum, M.,
Leibel, R. L.,
and Hirsch, J.
(1997)
N. Engl. J. Med
337,
396-407 2.
Kopelman, P. G.
(2000)
Nature
404,
635-643[Medline]
[Order article via Infotrieve]
3.
Schwartz, M. W.,
Woods, S. C.,
Porte, D., Jr.,
Seeley, R. J.,
and Baskin, D. G.
(2000)
Nature
404,
661-671[Medline]
[Order article via Infotrieve]
4.
Bray, G.,
and York, D. A.
(2001)
in
Handbook of Physiology: The Endocrine Pancreas and Regulation of Metabolism
(Goodman, H. M., ed)
, pp. 1015-1056, Oxford University Press, Oxford, United Kingdom
5.
Bray, G. A.,
and Tartaglia, L. A.
(2000)
Nature
404,
672-677[Medline]
[Order article via Infotrieve]
6.
Borgstrom, B.,
and Erlanson-Albertsson, C.
(1984)
in
Pancreatic Colipase
(Borgstrom, B.
, and Brockman, H. L., eds), 1st Ed.
, pp. 152-183, Elsevier, Amsterdam
7.
Verger, R.
(1984)
in
Pancreatic Lipase
(Borgstrom, B.
, and Brockman, H. L., eds), 1st Ed.
, pp. 84-150, Elsevier, Amsterdam
8.
Lowe, M. E.
(1994)
Gastroenterology
107,
1524-1536[Medline]
[Order article via Infotrieve]
9.
Sternby, B.,
and Borgstrom, B.
(1984)
Biochim. Biophys. Acta
786,
109-112[CrossRef][Medline]
[Order article via Infotrieve]
10.
Borgstrom, B.,
Wieloch, T.,
and Erlanson-Albertsson, C.
(1979)
FEBS Lett.
108,
407-410[CrossRef][Medline]
[Order article via Infotrieve]
11.
Lowe, M. E.,
Rosenblum, J. L.,
McEwen, P.,
and Strauss, A. W.
(1990)
Biochemistry
29,
823-828[CrossRef][Medline]
[Order article via Infotrieve]
12.
Wieloch, T.,
Borgstrom, B.,
Pieroni, G.,
Pattus, F.,
and Verger, R.
(1981)
FEBS Lett.
128,
217-220[CrossRef][Medline]
[Order article via Infotrieve]
13.
Erlanson-Albertsson, C.
(1992)
Nutr. Rev.
50,
307-310[Medline]
[Order article via Infotrieve]
14.
York, D. A.,
Lin, L.,
Smith, B. K.,
and Chen, J.
(2000)
in
Neural and Metabloic Control of Macronutrient Intake
(Berthoud, H-R.
, and Seeley, R. J., eds)
, pp. 301-314, CRC Press, New York
15.
Sambrook, J.,
Fritsch, E. F.,
and Maniatis, T.
(1989)
Molecular Cloning, A Laboratory Manual
, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
16.
Muglia, L. J.,
Jenkins, N. A.,
Gilbert, D. J.,
Copeland, N. G.,
and Majzoub, J. A.
(1994)
J. Clin. Invest.
93,
2066-2072
17.
Kullman, J.,
Gisi, C.,
and Lowe, M. E.
(1996)
Am. J. Physiol.
270,
G746-G751 18.
Lowe, M. E.
(1992)
J. Biol. Chem.
267,
17069-17073 19.
Lowe, M. E.
(1998)
in
Methods in Molecular Biology: Lipase and Phospholipase Protocols
(Doolittle, M. H.
, and Reue, K., eds)
, pp. 59-70, Humana Press Inc., Totowa, NJ
20.
Yang, Y.,
and Lowe, M.
(1998)
Protein Exp. Purif.
13,
36-40[CrossRef][Medline]
[Order article via Infotrieve]
21.
Ishibashi, S.,
Schwarz, M.,
Frykman, P.,
Herz, J.,
and Russell, D.
(1996)
J. Biol. Chem.
271,
18017-18023 22.
Rippe, C.,
Berger, K.,
Boiers, C.,
Ricquier, D.,
and Erlanson-Albertsson, C.
(2000)
Am. J. Physiol. Endocrinol. Metab.
279,
E293-E300 23.
Nagy, T. R.,
and Clair, A. L.
(2000)
Obes. Res.
8,
392-398[Medline]
[Order article via Infotrieve]
24.
Lowe, M.,
Kaplan, M. H.,
Jackson-Grusby, L.,
D'Agostino, D.,
and Grusby, M.
(1998)
J. Biol. Chem.
273,
31215-31221 25.
Bitman, J.,
and Wood, D. L.
(1981)
J. Liquid Chromatogr.
4,
1023-1034
26.
Bitman, J.,
Wood, D. L.,
and Ruth, J. M.
(1981)
J. Liquid Chromatogr.
4,
1007-1021
27.
Hooper, L. V.,
Wong, M. H.,
Thelin, A.,
Hansson, L.,
Falk, P. G.,
and Gordon, J. I.
(2001)
Science
291,
881-884 28.
Winzell, S. M.,
Lowe, M. E.,
and Erlanson-Albertsson, C.
(1998)
Gastroenterology
115,
1-8[CrossRef]
29.
Hildebrand, H.,
Borgstrom, B.,
Bekassy, A.,
Erlanson-Albertsson, C.,
and Helin, A.
(1982)
Gut
23,
243-246 30.
Jennens, M. L.,
and Lowe, M. E.
(1995)
J. Lipid Res.
36,
2374-2381[Abstract]
31.
Giller, T.,
Buchwald, P.,
Blum-Kaelin, D.,
and Hunziker, W.
(1992)
J. Biol. Chem.
267,
16509-16516 32.
Coleman, T.,
Seip, R. L.,
Gimble, J. M.,
Lee, D.,
Maeda, N.,
and Semenkovich, C. F.
(1995)
J. Biol. Chem.
270,
12518-12525 33.
Keesey, R. E.,
and Hirvonen, M. D.
(1977)
J. Nutr.
127,
1875 34.
Severinsen, T.,
and Munch, I. C.
(1999)
Acta Physiol. Scand.
165,
299-305[CrossRef][Medline]
[Order article via Infotrieve]
35.
Schwarz, M.,
Lund, E. G.,
Setchell, K. D. R.,
Kayden, H. J.,
Zerwekh, J. E.,
Bjorkhem, I.,
Herz, J.,
and Russell, D. W.
(1996)
J. Biol. Chem.
271,
18024-18031
Copyright © 2002 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
 |
|
  J. Iqbal and M. M. Hussain Intestinal lipid absorption Am J Physiol Endocrinol Metab, June 1, 2009; 296(6): E1183 - E1194. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 W. Pang, C. Li, Y. Zhao, S. Wang, W. Dong, P. Jiang, and J. Zhang The Environmental Light Influences the Circulatory Levels of Retinoic Acid and Associates with Hepatic Lipid Metabolism Endocrinology, December 1, 2008; 149(12): 6336 - 6342. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 R. Miller and M. E. Lowe Carboxyl Ester Lipase from Either Mother's Milk or the Pancreas Is Required for Efficient Dietary Triglyceride Digestion in Suckling Mice J. Nutr., May 1, 2008; 138(5): 927 - 930. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 S. D'Silva, X. Xiao, and M. E. Lowe A polymorphism in the gene encoding procolipase produces a colipase, Arg92Cys, with decreased function against long-chain triglycerides J. Lipid Res., November 1, 2007; 48(11): 2478 - 2484. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 D. Gilham, E. D. Labonte, J. C. Rojas, R. J. Jandacek, P. N. Howles, and D. Y. Hui Carboxyl Ester Lipase Deficiency Exacerbates Dietary Lipid Absorption Abnormalities and Resistance to Diet-induced Obesity in Pancreatic Triglyceride Lipase Knockout Mice J. Biol. Chem., August 24, 2007; 282(34): 24642 - 24649. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
D. D'Agostino and M. E. Lowe Pancreatic Lipase-related Protein 2 Is the Major Colipase-Dependent Pancreatic Lipase in Suckling Mice J. Nutr., January 1, 2004; 134(1): 132 - 134. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
K. W. Huggins, L. M. Camarota, P. N. Howles, and D. Y. Hui Pancreatic Triglyceride Lipase Deficiency Minimally Affects Dietary Fat Absorption but Dramatically Decreases Dietary Cholesterol Absorption in Mice J. Biol. Chem., October 31, 2003; 278(44): 42899 - 42905. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 B. K. Smith Richards, B. N. Belton, A. C. Poole, J. J. Mancuso, G. A. Churchill, R. Li, J. Volaufova, A. Zuberi, and B. York QTL analysis of self-selected macronutrient diet intake: fat, carbohydrate, and total kilocalories Physiol Genomics, December 3, 2002; 11(3): 205 - 217. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
M. E. Lowe The triglyceride lipases of the pancreas J. Lipid Res., December 1, 2002; 43(12): 2007 - 2016. [Abstract] [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
| All ASBMB Journals | Molecular and Cellular Proteomics |
| Journal of Lipid Research | ASBMB Today |