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From the Departments of
Received for publication, January 10, 2002, and in revised form, March 12, 2002
Adeno-associated virus (AAV) is a promising
vector for gene transfer in cystic fibrosis. AAV4 and AAV5 both bind to
the apical surface of differentiated human airway epithelia, but only
AAV5 infects. Both AAV4 and AAV5 require 2,3-linked sialic acid for binding. However, AAV5 interacts with sialic acid on
N-linked carbohydrates, whereas AAV4 interacts with sialic
acid on O-linked carbohydrates. Because mucin is decorated
with O-linked carbohydrates, we hypothesized that mucin
binds AAV4 and inhibits gene transfer. To evaluate the effect of
secreted mucin, we studied mucin binding and gene transfer to COS cells
and the basolateral membrane of well differentiated human airway
epithelia. AAV4 bound mucin more efficiently than AAV5, and
mucin inhibited gene transfer with AAV4. Moreover,
O-glycosidase-pretreated mucin did not block gene transfer
with AAV4. Similar to secreted mucin, the transmembrane mucin MUC1
inhibited gene transfer with AAV4 but not AAV5. MUC1 inhibited AAV4 by
blocking internalization of the virus. Thus, O-linked
carbohydrates of mucin are potent inhibitors of AAV4. Furthermore,
whereas mucin plays an important role in innate host defense, its
activity is specific; some vectors or pathogens are more resistant to
its effects.
Previous work implicates mucin as a key component of the innate
host defense system against pathogens (1-5). In particular, mucin acts
as a general physical barrier that when coupled with ciliary action
rapidly clears inhaled particles out of the lung (4). In addition,
mucin might act as a specific defense. That is, the molecular
components of mucin could potentially act as a soluble receptor system.
This system might be important in the removal of specific pathogens
(e.g. viruses that interact with carbohydrate structures in
mucin). Mucin binds both bacteria (e.g. Hemophilus
influenzae and Moraxella catarrhalis) and
viruses (e.g. rotavirus and influenza) often via sialic acid
(3, 6-9). Interestingly, several of these organisms use sialic acid as
a cellular receptor (6, 10-13). This raises the question of what
controls the balance between pathogen binding to cellular receptors
leading to infection and binding to mucin leading to clearance. More
specifically, could the binding specificity of the pathogen control
this balance? We took advantage of our recent findings with
adeno-associated viruses to address this question.
Recombinant adeno-associated viruses
(AAV)1 hold promise for gene
transfer to several tissues including the airway (14-20). AAV2 was the
first primate AAV to be cloned and has been studied extensively (21).
This vector was recently shown to mediate Factor IX gene transfer to
the muscle of humans, making hemophilia one of the first human genetic
diseases to be partially corrected by gene transfer (20). AAV2 has also
been investigated for gene transfer of the cystic fibrosis
transmembrane conductance regulator cDNA to airway epithelia
in cystic fibrosis in vitro and in vivo (15, 16,
22-25). However, because AAV2 is inefficient, other serotypes have
been investigated for targeting the apical surface of airway epithelia.
Both AAV4 and AAV5 bind the apical surface of human airway epithelia
more efficiently than AAV2; however, only AAV5 infects (26, 27). Hence,
why does AAV4 bind but not infect? Surprisingly, both AAV4 and AAV5
require 2,3-linked sialic acid for binding and infection (28, 29).
However, AAV4 requires sialic acid present in O-linked
oligosaccharides, whereas AAV5 requires sialic acid in
N-linked oligosaccharides. Because mucin contains
primarily O-linked oligosaccharides, we tested the
hypothesis that mucin binds and inhibits gene transfer with AAV4, not AAV5.
Cells and Culture--
COS-7 cells were cultured on 96-well
plates (Corning Costar, Corning, NY) in Eagle's minimal essential
media (EMEM, Sigma) supplemented with 10% fetal calf serum
(Sigma), 1% nonessential amino acids, 100 units/ml penicillin, and 100 µg/ml streptomycin.
Airway epithelial cells obtained from trachea and bronchi of lungs
removed for organ donation were isolated by enzyme digestion and seeded
at 5 × 105 cells/cm2 onto collagen-coated
0.6-cm2 area Millicell polycarbonate filters (Millipore)
(30, 31). Cells were maintained at 37 °C in a humidified atmosphere
of 5% CO2 and air. 24 h after plating, mucosal medium
was removed, and cells were allowed to grow at the air-liquid interface
(30-32). Culture media consisted of a 1:1 mixture of
Dulbecco's modified Eagle's medium/Ham's F-12 medium, 5% Ultraser G
(Biosepra SA, Cergy-Saint-Christophe, France), 100 units/ml penicillin,
100 µg/ml streptomycin, 1% nonessential amino acids, and 0.12 unit/ml insulin. Epithelia were allowed to reach confluence and develop a transepithelial electrical resistance and a ciliated apical surface
(31, 33).
Adeno-associated Viruses--
Recombinant AAV4 and AAV5 were
produced as described previously (34). AAV4/ Mucin Binding Assay--
The binding of AAV4/ Mucin Competition and MUC1 Expression--
Mucin competition was
carried out by pretreating virus with mucin for 30 min at 20 °C.
Virus alone or virus plus mucin was added to cells in equal volumes of
EMEM for 1 h at 37 °C. Cells were rinsed twice with EMEM and
incubated at 37 °C. In COS cells, 2000 particles/cell were
pretreated with mucin (concentrations up to 1 mg/ml), and cells were
assayed for gene transfer 3 days later. In cells expressing MUC1 (see
below), virus was treated with 0.01 mg/ml mucin. In human airway
epithelia, 2000 particles/cell were pretreated with 0.1 mg/ml mucin and
added to the basolateral membrane of epithelia. Epithelia were assayed
2 weeks later.
O-Linked carbohydrate was removed from mucin by treating a 2 mg/ml solution with 0.1 unit/ml O-glycosidase at pH 5.0 for
24 h at 37 °C. Deglycosylated mucin was purified with column
chromatography using boronic acid conjugated to Sepharose beads
(Pierce). The recovery was determined by absorbance at 280 nm, and
equal concentrations of protein were used to test competition of
glycosylated mucin versus deglycosylated mucin.
Human MUC1 containing 22 tandem repeats or truncated MUC1 containing
only 2 repeats (MUC1 Electron Microscopy and Immunocytochemistry--
Mucus in airway
epithelial cultures was evaluated by scanning electron microscopy.
Traditional aqueous steps were avoided (39, 40). Cell cultures were
gently immersed in 1% osmium tetroxide dissolved in 3 M
perfluorocarbon (PFC-Fluorinert FC®-72) for 2 h and rinsed with
perfluorocarbon. Samples were placed in 50:50
ethanol:hexamethyldisilazane, washed twice in 100%
hexamethyldisilazane, and air-dried. Filters were sputter-coated with
gold/palladium and imaged in an Hitachi S-4000.
MUC1 expression was evaluated by immunocytochemistry. Cells were rinsed
with phosphate-buffered saline and then fixed with 4% paraformaldehyde
for 20 min at 20 °C. Unless otherwise noted, SuperBlock (Pierce) was
used to wash and dilute reagents. Cells were washed twice for 10 min,
and mouse anti-MUC1 monoclonal antibody (1:50, Serotec, Raleigh, NC)
was added for 1 h at 37 °C, rinsed twice for 10 min, and
incubated with donkey Gene Transfer Assays--
Gene transfer was measured as
described previously (26). We measured Cell Binding and Internalization Assays--
The binding and
internalization of AAV4/ Data Analysis--
Statistical significance was determined with
a Student's t test. The values of p < 0.05 were considered significant. Competition binding curves with mucin were
analyzed to obtain the approximate EC50 for inhibition. The
curves were fit as a two-site competition using nonlinear regression
(Prism, GraphPad software).
AAV4 Binds Mucin More Efficiently than AAV5--
Using a dot blot
assay, we studied in vitro binding of AAV4 and AAV5 to
purified mucin that contains O-linked carbohydrate only
(37). Starting with equal amounts of AAV4 and AAV5, we observed
significant binding with AAV4, which was dependent on the dose of mucin
(Fig. 1A). In contrast, AAV5
bound poorly even with large amounts of mucin present. To further
understand these interactions, we quantified binding (Fig.
1B). An analysis of AAV4 revealed a saturating binding
curve, suggesting that the interaction between AAV4 and mucin is
specific. However, with AAV5, the binding seemed to increase in direct
proportion to mucin, suggesting that the interaction with AAV5 and
mucin is primarily nonspecific. Hence, mucin binds AAV4 more
efficiently than AAV5.
Soluble Mucin Inhibits Gene Transfer with AAV4 Greater than
AAV5--
To determine whether mucin inhibits AAV4 or AAV5, we studied
gene transfer to COS cells with these viruses. AAV4 and AAV5 infected
COS cells with similar levels of gene transfer (Fig. 2A). However, increasing
amounts of mucin inhibited AAV4 significantly more than AAV5. More to
the point, mucin was a more "effective" inhibitor of AAV4 than
AAV5. The maximum inhibition resulted in a 10-fold decrease in gene
transfer with AAV4 as compared with a 2-fold decrease with AAV5. In
addition, mucin was a more "potent" inhibitor of AAV4 than AAV5.
The concentration required to half-maximally inhibit AAV4 was ~50
times lower than the concentration required to half-maximally inhibit
AAV5. Hence, mucin inhibits infection with AAV4 more efficiently than
AAV5.
Because AAV4 interacts with O-linked carbohydrates, we
predicted that the O-linked carbohydrates of mucin are
required to inhibit AAV4. The exact nature of the carbohydrate is not
known; hence, we tested this prediction by removing the
O-linked carbohydrate from mucin and studied its ability to
block infection with AAV4. At 0.01 mg/ml mucin, deglycosylated mucin no
longer inhibited AAV4 infection (Fig. 2B). Thus,
O-linked carbohydrates in mucin are directly responsible for
this inhibition.
Mucin Inhibits AAV4 Infection of Human Airway Epithelia but Not
AAV5--
To study the effect of mucin on gene transfer to airway
epithelia, we took advantage of the fact that mucin is selectively expressed and secreted through the apical membrane (Fig.
3A) (4). Therefore, we studied
the ability of AAV4 and AAV5 to infect these differentiated cultures
from the basolateral surface. In contrast to apical infection, both
AAV4 and AAV5 infected airway epithelia from the basolateral surface
and with similar efficiency (Fig. 3B) (26). Therefore, some
factor at the apical surface blocks AAV4 but not AAV5. If this factor
is mucin, then the addition of mucin to the basolateral surface should
also limit basolateral infection with AAV4. The infection in the
presence of 0.1 mg/ml mucin blocked basolateral gene transfer with AAV4
but not AAV5. Hence, the polarity of mucin correlates with the polarity
of infection with AAV4, suggesting that mucin inhibits apical infection
with AAV4.
Transmembrane Mucins Inhibit AAV4 but Not AAV5 Infection--
In
addition to secreted mucins, airway epithelia also present
transmembrane mucins on the apical membrane (41). To test the
hypothesis that transmembrane mucins also inhibit infection with AAV4
and not AAV5, we expressed MUC1 (containing either 22 tandem repeats or
2 tandem repeats) in COS cells and studied gene transfer with these
viruses. Approximately 70% of cells were transfected (data not shown).
We confirmed MUC1 expression by immunocytochemistry. MUC1 is present on
the surface of cells expressing MUC1 with 22 tandem repeats but not on
the surface of control cells (Fig. 4, A and B). The expression of MUC1 containing 22 tandem repeats significantly decreased infection with AAV4 (Fig.
4C). MUC1
These observations raise the question as to whether MUC1 and soluble
mucin together have synergistic or additive effects. Thus, we studied
AAV4-mediated gene transfer to truncated MUC1-expressing cells in the
presence of submaximal concentrations of soluble mucin (0.01 mg/ml).
Together, soluble mucin and MUC1 Transmembrane Mucin Inhibits Internalization of AAV4--
To
understand how MUC1 inhibits gene transfer with AAV4, we studied the
binding and entry of AAV4 in MUC1-expressing cells. The total binding
of AAV4 was not affected by MUC1 expression (Fig.
5, A and B).
However, the cells expressing full-length MUC1 internalized less AAV4
after a 15-min pulse than the controls or cells expressing truncated
MUC1, and this inhibition was more obvious after 3 h (Fig.
5C). Hence, MUC1 blocks AAV4 by inhibiting internalization,
and the effect is dependent upon the number of mucin tandem repeats.
Interestingly, human MUC1 typically has between 47 and 80 tandem
repeats. This finding plus the fact that not every cell expressed MUC1
suggests that our results may underestimate the impact of transmembrane
mucins on gene transfer with AAV4.
Secreted and transmembrane mucins inhibit gene transfer with AAV4
more effectively and potently than AAV5. Moreover, AAV5 infects airway
epithelia from the apical membrane in the presence of endogenous
mucin/mucus (26). Because both AAV4 and AAV5 require 2,3-linked sialic
acid to infect cells but differ with respect to other aspects of
the carbohydrate (i.e. O-linked
versus N-linked), we conclude mucin has a
specific binding function. This finding is relevant both for the
development of airway and intestine-targeted vectors and for
understanding innate host defenses against invading microorganisms.
Implications for Gene Transfer--
Rational development of gene
transfer vectors requires an understanding of the steps required and
barriers that prevent efficient delivery of genes. Recent work has
focused on elucidating the barriers that prevent gene transfer from the
apical membrane of airway epithelia. For instance, AAV5 is better than
AAV2, because there are more apical receptors for AAV5. However, other
barriers that precede receptor binding may also be important. For
example, mucin seems to have activity against several candidate gene
transfer vectors including adenovirus (41). In addition, previous work showed that mucin can be used to purify AAV5 (42). Given that AAV5
binds N-linked carbohydrates, these two points raise the question of whether AAV5 binds mucin specifically and whether mucin
affects AAV5 function in vivo. We observed that mucin
inhibits AAV4 greater than AAV5, and AAV5 infects differentiated airway epithelia even in the presence of endogenous mucin/mucus both in
vitro and in vivo as described above and previously
(26). Hence, mucin specifically blocks vectors that interact with
O-linked carbohydrates such as AAV4, and its impact on other
vectors (i.e. AAV5) may not be therapeutically significant.
These observations should aid in our understanding, development, and
use of gene transfer vectors.
Implications for Innate Host Defense and Viral
Pathogenesis--
Whereas mucin clearly plays a role in innate host
defense, we do not understand the exact nature of its role. Mucin can
inhibit pathogens that interact with O-linked carbohydrate
(one example is rotavirus (13)). To circumvent this barrier, rotavirus
evolved specific enzymatic activity that allows the virus to digest its way through the mucin layer (43). In addition to this complex mechanism, our work suggests a different and perhaps simpler
evolutionary mechanism for evading the mucin barrier. More
specifically, recognizing N-linked carbohydrate as opposed
to O-linked carbohydrate seems a significant step forward
with respect to the ability of AAV to infect airway epithelia. In
addition to its importance for this gene transfer vector, we speculate
that this mechanism generally may be more applicable to pathogen
evolution, possibly accounting for variability in virulence of viruses
such as influenza.
We thank Michael Seiler, Janice Launspach,
Tom Moninger, Phil Karp, Pary Weber, Tamara Nesselhauf, Beverly
Handelman, Theresa Mayhew, and Rosanna Smith for excellent assistance.
We also thank Drs. Michael Welsh, Judith St. George, and Michael
Apicella for discussions and comments. We especially appreciate the
help of ISOPO and IIAM for the human lungs. We appreciate the support of the University of Iowa Gene Transfer Vector Core and the In Vitro Cell Models Core.
*
This work was supported in part by the Center for Gene
Therapy, NIDDK, National Institutes of Health Grant T30DK54759, the Cystic Fibrosis Foundation, and the Roy J. Carver Charitable
Trust.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.
**
To whom correspondence may be addressed: NIH 10/IN113, 10 Center
Dr., MSC 1190, Bethesda, MD 20902. Tel.: 301-496-4279; Fax: 301-402-1228; E-mail: Jchiorini@dir.nidcr.nih.gov.
Published, JBC Papers in Press, March 29, 2002, DOI 10.1074/jbc.M200292200
The abbreviations used are:
AAV, adeno-associated virus;
EMEM, Eagle's minimal essential media;
MUC
Secreted and Transmembrane Mucins Inhibit Gene Transfer with AAV4
More Efficiently than AAV5*
§,
**, and
Internal Medicine and
§ Physiology and Biophysics, University of Iowa College of
Medicine, Iowa City, Iowa 52242, the ¶ Department of Medicine,
University of Pittsburgh, Pittsburgh, Pennsylvania 15261, and the
Gene Therapeutics Branch, NIDCR, National Institutes of Health,
Bethesda, Maryland 20892
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-galactosidase and
AAV5/-galactosidase were prepared by triple plasmid cotransfection
of COS cells using calcium phosphate cotransfection (Invitrogen). Cells
were harvested and pelleted 72 h post-transfection, resuspended in
tissue dissociation buffer (140 mM NaCl, 5 mM
KCl, 0.7 mM K2HPO4, 25 mM Tris/HCl, pH 7.4), and stored at 
70 °C. Samples
were thawed at 37 °C, treated with benzonase (Sigma) at 20 units/ml
and sodium deoxycholate at 0.5% for 1 h, and homogenized (20 strokes in a Wheaton B homogenizer). CsCl was added to 1.4 g/cm3, and the homogenate was centrifuged (SW 40 rotor at
38,000 rpm) for 65 h at 20 °C. Gradient fractions with a
refractive index of 1.371-1.373 were pooled. Viruses were titered by
Southern blot and transmission electron microscopy. Titers ranged
between 1 × 1012 and 1 × 1013
particles/ml. The ratio of infectious units to particles is the same for AAV4 and AAV5 in COS cells (35, 36).
-galactosidase
and AAV5/-galactosidase to mucin was measured using a dot blot
assay. Bovine submandibular gland mucin (Sigma) contains a major
glycoprotein (82% glycosylated) and a minor glycoprotein (65%
glycosylated). Both proteins are glycosylated with O-linked
carbohydrate only, and nearly all sites contain sialic acid (37). Mucin
was adsorbed onto 96-well enzyme-linked immunosorbent assay plates
(Corning Costar) for 1 h at 37 °C in 5-fold dilutions starting
from 1 mg/ml. Plates were washed three times with phosphate-buffered
saline and then blocked overnight with 5% bovine serum albumin at
4 °C. AAV4 and AAV5 were added at 1 × 1010
particles/ml in EMEM for 2 h at 37 °C. Plates were rinsed three times with EMEM, and bound virus was quantified. Samples were treated
with trypsin-EDTA for 2 h at 37 °C, subjected to three freeze/thaw cycles, and blotted onto a nylon membrane (Ambion). AAV
viral DNA was detected by hybridizing with a 32P-labeled
-galactosidase cDNA probe. Unhybridized probe was washed twice
with 2× SSC and 0.1% SDS at 20 °C for 15 min, once with 0.5× SSC
and 0.1% SDS at 55 °C for 1 h, and once with 0.5× SSC and
0.1% SDS at 65 °C for 30 min. Dot blots were developed and quantitated using a PhosphorImager (Molecular Dynamics) (26, 38).
29) in pcDNA3 was expressed in COS cells
using a LipofectAMINE transfection as directed (Invitrogen). MUC1
expression and AAV gene transfer were studied 24 h later.
-mouse IgG conjugated with fluorescein
isothiocyanate fluorophore (1:500, Jackson ImmunoResearch Laboratories
Inc., West Grove, PA) for 1 h at 37 °C. Cells were rinsed twice with phosphate-buffered saline for 10 min and mounted using Vectashield containing 4',6-diamidino-2-phenylindole (Vector Laboratories Inc., Burlingame, CA). Cell staining was evaluated by
indirect immunofluorescence microscopy.
-galactosidase activity using
a commercially available method (Galacto-Light, Tropix Inc., Bedford,
MA). After rinsing with phosphate-buffered saline, cells were lysed by
incubation with 120 µl of buffer (25 mM Tris phosphate,
pH 7.8, 2 mM dithiothreitol, 2 mM
1,2-diaminocyclohexane-N,N,N',N'-tetraacetic
acid, 10% glycerol, and 1% Triton X-100) for 15 min. Light emission
was quantified in a luminometer (Analytical Luminescence Laboratory,
San Diego, CA).
-galactosidase to COS cells were measured
using a dot blot assay (26, 38). Experiments were carried out by
binding AAV4 at 2 × 109 particles/ml for 60 min at
4 °C. To remove unbound virus, cells were rinsed three times with
EMEM and either harvested to determine binding or incubated at 37 °C
to allow internalization. Following 15-min or 3-h incubations, cells
were treated with trypsin-EDTA for 30 min at 20 °C to remove AAV not
internalized. Cells were pelleted, rinsed three times with EMEM, and
then harvested. Samples were subjected to three freeze/thaw cycles,
blotted, and probed as described above.
RESULTS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
View larger version (37K):
[in a new window]
Fig. 1.
Binding of AAV4 and AAV5 to mucin.
A, dot blot of AAV4 and AAV5 binding to mucin. Mucin
concentration increases in 5-fold increments from left to
right. B, quantitation of mucin binding with AAV4
( 
) and AAV5 (
). Data are the mean binding ± S.E.
(n = 3).
View larger version (22K):
[in a new window]
Fig. 2.
Effect of mucin on AAV4- and AAV5-mediated
gene transfer to COS cells. A, dose response of
mucin competition with AAV4 ( ) and AAV5 (). B,
competition of AAV4 with mucin versus mucin lacking
O-linked carbohydrate. Data are the mean gene transfer ± S.E. (n = 3-9). LU, light units;
asterisk, p < 0.05.
View larger version (72K):
[in a new window]
Fig. 3.
Effect of mucin on AAV4- and AAV5-mediated
gene transfer to airway epithelia. A, scanning electron
micrograph of well differentiated human airway epithelia indicating
mucus (M), cilia (C), columnar epithelial cells
(E), and basal cells (B) growing on a filter
support (F). B, gene transfer with AAV4 and AAV5
from the basolateral membrane of human airway epithelia. Data are the
mean gene transfer ± S.E. (n = 6). LU,
light units; asterisk, p < 0.05.
29 showed a trend toward decreased infection
with AAV4, but this difference was not statistically significant. In
contrast to AAV4, AAV5 infection was not inhibited by recombinant MUC1
expression. Hence, the transmembrane mucin MUC1 inhibits only AAV4, and
the effect is dependent upon the number of mucin tandem repeats.
View larger version (40K):
[in a new window]
Fig. 4.
Effect of transmembrane mucin (MUC1) on AAV4-
and AAV5-mediated gene transfer to COS cells. MUC1
immunocytochemistry in control COS cells (A) or cells
expressing full-length MUC1 (MUC1 22r)
(B) is shown.
4',6-Diamidino-2-phenylindole-stained nuclei are
blue, and MUC1 staining is green. C,
gene transfer to MUC1-expressing cells with AAV4 and AAV5.
D, gene transfer to MUC1 29-expressing cells in the
presence of soluble mucin. Data are the mean gene transfer ± S.E.
(n = 3-6). LU, light units;
asterisk, p < 0.05.
29 inhibited gene transfer greater
than either mucin alone, and this effect was additive (Fig.
4D). Moreover, soluble mucin reconstituted inhibition with
the truncated MUC1, further supporting its role as a soluble receptor system.
View larger version (30K):
[in a new window]
Fig. 5.
Mechanism of AAV4 inhibition with
transmembrane mucin, MUC1. A, dot blot of bound or
internalized AAV4 in control COS cells, cells expressing truncated
MUC1 29, or cells expressing full-length MUC1 (MUC1
22r). Quantitation of bound (B) and internalized
AAV4 (C) is shown. Data are the mean bound or internalized
AAV4 ± S.E. (n = 3). Std, standard;
asterisk, p < 0.05.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence may be addressed: University of Iowa
College of Medicine, 500 EMRB, Iowa City, IA 52242. Tel.: 319-353-5511; Fax: 319-335-7623; E-mail: joseph-zabner@uiowa.edu.
ABBREVIATIONS
29, truncated MUC1 containing only 2 repeats.
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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