Báo cáo khoa học: Mapping of the 45M1 epitope to the C-terminal cysteine-rich part of the human MUC5AC mucin potx

We demonstrate for the first time that the widely used mAb 45M1, as well as 2-12M1 and 166M1, are true antibodies against MUC5AC, with epitopes located in the C-terminal cysteine-rich par

cysteine-rich part of the human MUC5AC mucin

Martin E Lidell1, Jacques Bara2and Gunnar C Hansson1

1 Department of Medical Biochemistry, Go¨teborg University, Sweden

2 U-673 INSERM, Hoˆpital Saint-Antoine, Paris, France

Mucins are large glycoproteins found on mucosal

sur-faces throughout the body They are divided into

mem-brane-bound and secreted mucins, and the latter group

can be further subdivided into gel-forming and

non-gel-forming mucins [1] The non-gel-forming mucins

consti-tute the main structural component of the mucous layer

protecting the underlying epithelial surfaces against the

often harsh environment present in the lumen So far,

five gel-forming mucins (MUC2, MUC5B, MUC5AC,

MUC6, and MUC19) have been described, and their

expression appears to be tissue-specific [2–7] In the

normal situation, MUC5AC is primarily expressed in

the airways and stomach, and it constitutes a major

component of the respiratory and gastric mucus

The gastric M1 antigen was originally defined by

several polyclonal antibodies, and it was reported that

this antigen is expressed early during human colonic

carcinogenesis [8,9] In the normal gastrointestinal

tract, M1 is present in the columnar mucous cells of

the surface epithelium of gastric mucosa, but not in the colon [10] However, M1 is found in the goblet cells of fetal colon [11] and in colorectal adenomas [8,9] and adenocarcinomas [10,12] M1 has also been shown to be expressed in human pancreatic ductal adenocarcinomas [13] Twelve hybridoma cell lines secreting mAbs against M1 have been isolated after screening of their supernatants for strong immunoreac-tivity on colon adenomas and their lack of reacimmunoreac-tivity

in normal colon, as observed with the polyclonal anti-bodies against M1 Two of the mAbs, 2-11M1 and 9-13M1, have been shown to recognize epitopes present

in the N-terminal cysteine-rich part of MUC5AC [14] One mAb, 1-13M1, recognizes an epitope found in the second and fourth CysD domains of MUC5AC [14] Another five mAbs, 19M1, 21M1, 463M, 589M, and 62M1, recognize epitopes mapped to the C-terminal cysteine-rich part of MUC5AC [15,16] The epitopes for the last four mAbs, 2-12M1, 58M1, 166M1, and

Keywords

antibody; 45M1; monoclonal; MUC5AC;

mucin

Correspondence

G C Hansson, Department of Medical

Biochemistry, Institute of Biomedicine,

Go¨teborg University, Box 440,

405 30 Gothenburg, Sweden

Fax: +46 31 416108

Tel: +46 31 7863488

E-mail: gunnar.hansson@medkem.gu.se

(Received 25 October 2007, accepted

28 November 2007)

doi:10.1111/j.1742-4658.2007.06215.x

Mucins are large glycoproteins protecting mucosal surfaces throughout the body Their expressions are tissue-specific, but in disease states such as cys-tic fibrosis, inflammation and cancer, this specificity can be disturbed MUC5AC is normally expressed in the mucous cells of the epithelia lining the stomach and the trachea, where it constitutes a major component of the gastric and respiratory mucus A number of mAbs have been raised against the gastric M1 antigen, an early marker for colonic carcinogenesis Several of these mAbs recognize epitopes present on MUC5AC, suggesting that MUC5AC is the antigen However, some of the mAbs raised against the gastric M1 antigen are widely used as antibodies against MUC5AC, despite the fact that their specificity for MUC5AC has not been clearly shown In this study, we have tested the reactivity of the latter antibodies against a recombinantly expressed C-terminal cysteine-rich part of human MUC5AC We demonstrate for the first time that the widely used mAb 45M1, as well as 2-12M1 and 166M1, are true antibodies against MUC5AC, with epitopes located in the C-terminal cysteine-rich part of the mucin

Abbreviation

GDPH, Gly-Asp-Pro-His; goat-a-mouse-AP, goat anti-(mouse IgG) coupled to alkaline phosphatase.

45M1, have not been deciphered so far, although they

have been tested against recombinantly expressed

por-tions of MUC5AC Despite this, 45M1 has been widely

used as a mAb against MUC5AC [17–19], and is even

sold as such The 2-12M1 mAb is also sold as a

mAb against MUC5AC, although its specificity for

MUC5AC has not been fully established

In this study, we have tested the reactivities of the

11 mAbs towards the complete C-terminal cysteine-rich

part of human MUC5AC The results presented here

show that 2-12M1, 166M1 and 45M1 really are mAbs

against MUC5AC and that their epitopes are located

in the C-terminal cysteine-rich part of this mucin

Results and Discussion

The recombinant C-terminal cysteine-rich part

of human MUC5AC

In this study, the reactivities of the mAbs against M1

were tested against the C-terminal cysteine-rich part of

human MUC5AC This part was expressed in CHO-K1

cells as fusion proteins containing a myc-tag followed by

either the 1041 C-terminal amino acids

(M-MUC5AC-CH-long) [20] or 959 C-terminal amino acids

(M-MUC5AC-CH-short) of human MUC5AC and a

His-tag (Fig 1) The murine Ig j-chain signal sequence

was used to direct the protein synthesis into the

secre-tory pathway L31 [21], the cDNA clone used in

previ-ous studies aimed at mapping the epitopes of the mAbs

against M1 to the C-terminal part of MUC5AC [15,16],

does not encode the complete C-terminal cysteine-rich

part of human MUC5AC It lacks a sequence in the

5¢-end that corresponds to the major part of the last

CysD domain found in MUC5AC The missing sequence

is present in the NP3a clone reported by Meerzaman

et al [22] The L31 and NP3a clones were used as

templates when constructing the plasmids encoding

M-MUC5AC-CH-long and M-MUC5AC-CH-short;

the former contains the complete C-terminal

cysteine-rich part, and the latter the sequence corresponding to

the L31 clone with an extra nine amino acids added to

its N-terminus (Fig 1) When expressed in CHO-K1

cells, M-MUC5AC-CH-long forms disulfide-linked

dimers in the endoplasmic reticulum and is partially

cleaved at a Gly-Asp-Pro-His (GDPH) sequence located

in the von Willebrand D4 domain during its transport

through the secretory pathway [20] After cleavage, the

fragments are still held together by disulfide bonds

Reduction of these releases a C-terminal fragment

(C2-H) that can be detected with a mAb against His5,

and an N-terminal fragment (M-C1) that can be

detected with a mAb against myc Both the dimer and

the monomer can be detected with either the mAb against myc or the mAb against His5 The recombinant MUC5AC C-terminus and its cleavage products were used to map the epitopes recognized by the mAbs against M1

Immunoreactivity of mAbs against M1 towards a recombinant MUC5AC C-terminal cysteine-rich part

To test the reactivity of the mAbs against M1 towards the human MUC5AC C-terminal cysteine-rich

Fig 1 The recombinant C-terminal cysteine-rich part of human MUC5AC A schematic picture of the recombinant C-terminal cyste-ine-rich part of human MUC5AC is given in the upper part of the figure The GDPH-cleavage site as well as the epitopes for the mAbs against myc (amyc) and His5 (aHis5) are indicated M-C1, N-terminal cleavage fragment; C2-H, C-terminal cleavage fragment The lower part of the figure shows an alignment of the N-terminal MUC5AC sequences of long and M-MUC5AC-CH-short and the corresponding sequences of human, rat and mouse MUC5AC Long, M-MUC5AC-CH long; Short, M-MUC5AC-CH short; Mouse, mouse MUC5AC (AJ511871) [29]; Rat, rat MUC5AC (U83139) [30] ELO9 (AJ001402) [25], L31 (Z48314) [21], NP3a (U06711) [22]; GeneBank ⁄ EMBL Databank accession numbers are given in parentheses after each clone.

part, cell lysate from CHO-K1 cells expressing

M-MUC5AC-CH-long was separated by SDS⁄ PAGE

under both nonreducing and reducing conditions, and

the proteins were blotted to membranes that were

probed with the different antibodies (Fig 2) The

results after SDS⁄ PAGE under nonreducing

condi-tions (Fig 2A) confirm previous results showing that

19M1, 21M1, 463M, 589M and 62M1 react with the

C-terminal cysteine-rich part of MUC5AC [15,16]

The 1-13M1 and 2-11M1 mAbs do not react with the

recombinant MUC5AC C-terminus This is in

agree-ment with previous work showing that these

anti-bodies recognize epitopes in the N-terminal part of

MUC5AC [14] A triplet of reduction-sensitive bands centered around 150 kDa is detected by 1-13M1 These bands are also seen in nontransfected CHO-K1 cells, indicating that the bands are nonspecific (data not shown) More interestingly, 2-12M1, 45M1 and 166M1 react with the recombinant MUC5AC C-termi-nus The epitopes of these antibodies have not been deciphered previously, although they have been ana-lyzed against the expression product of the L31 clone [16] One possibility would therefore be that the epitopes of these antibodies are located within the

91 amino acids missing in the L31-encoded sequence The 58M1 epitope does not seem to be located in the C-terminal cysteine-rich part of MUC5AC, as no staining of the recombinant protein is seen The dimeric protein is stained by all the reacting anti-bodies The monomeric protein is also stained, although more weakly, with all these antibodies (longer exposure times, not shown)

The results after SDS⁄ PAGE under reducing condi-tions (Fig 2B) show that, whereas the epitopes of 2-12M1, 45M1, 463M and 589M are reduction-sensi-tive, those of 19M1 and 21M1 are not This is in agreement with previous results [23] In addition, the present results show that the 166M1 and 62M1 epi-topes appear to be insensitive to reduction The fact that the recombinant MUC5AC is cleaved during its biosynthesis allows us to delimit the region where the reduction-insensitive epitopes are located As the M-C1 fragment is detected by 19M1 and 21M1, their epitopes must be N-terminal to the GDPH-cleavage site in the von Willebrand D4 domain of MUC5AC This is in agreement with the previously identified region between the last CysD domain and the von Willebrand D4 domain of MUC5AC [16] The 62M1 mAb reacts with the C2-H fragment, indicating that its epitope is located C-terminally to the GDPH-cleavage site This is also in agreement with previous studies, in which the epitope has been located to the C-terminal part of MUC5AC harboring the von Wille-brand C domain and cysteine-knot domain [16] In the case of 166M1, a very faint band corresponding to the C2-H fragment was detected, indicating that this mAb also detects a C-terminal epitope (the band is more clearly visualized in Fig 3D, where the blot was devel-oped for a longer time) Table 1 summarizes the reac-tivities of the antibodies towards both reduced and nonreduced M-MUC5AC-CH-long In conclusion, our results confirm that 19M1, 21M1, 463M, 589M and 62M1 are antibodies against MUC5AC, and that their epitopes are found in the C-terminal cysteine-rich part More importantly, we find that the previously unmapped antibodies 2-12M1, 45M1 and 166M1 also

A

B

Fig 2 Western blot analysis of the recombinant MUC5AC

C-termi-nus using mAbs against M1 Cell lysates of CHO-K1 cells stably

expressing a recombinant MUC5AC C-terminal cysteine-rich part

(M-MUC5AC-CH-long) were separated by SDS ⁄ PAGE [3–

10% (w ⁄ v) gradient gel] under nonreducing (A) and reducing (B)

conditions After western blotting, the membranes were probed

with mAbs against myc, His 5 or M1 The lane numbers and the

mAb used for detection are indicated in the lower part of the

figure Dimer, dimeric M-MUC5AC-CH; Monomer, monomeric

M-MUC5AC-CH; M-5AC-CH, reduced M-MUC5AC-CH; C2-H,

C-ter-minal cleavage fragment; M-C1, N-terC-ter-minal cleavage fragment The

position of the very faint band that is detected by 166M1 and that

corresponds to the C2-H cleavage fragment is indicated by an

asterisk in (B) Positions of molecular mass standards are indicated

on the right-hand side.

are antibodies against MUC5AC, with epitopes located

in the MUC5AC C-terminal cysteine-rich part

Further localization of the epitopes of 45M1,

2-12 M1 and 166M1

In order to further locate the epitopes of the hitherto

unmapped 45M1, 2-12M1 and 166M1, these mAbs

were screened against M-MUC5AC-CH-long and

M-MUC5AC-CH-short The 45M1 mAb is sold by

several companies as a specific mAb against

MUC5AC, and has been used as such in a number of

studies [17–19] The specificity of 45M1 for MUC5AC

has never been clearly demonstrated As our results

indicated that 45M1 reacted with a recombinant

pro-tein harboring the complete C-terminal cyspro-teine-rich

part of MUC5AC, but not with a protein

correspond-ing to the L31 clone, we hypothesized that the

91 amino acids located N-terminally to the latter were

important for the antibody reactivity This hypothesis was tested by using 45M1 for detection after SDS⁄ PAGE and western blotting of cell lysates from

Table 1 Immunoreactivities of mAbs against M1 towards the MUC5AC C-terminal cysteine-rich part Staining intensity was esti-mated from ) to +++.

mAbs

A

B

C

D

Fig 3 Western blot analysis of the recombinant MUC5AC C-termi-nus using 45M1, 166M1 and 2-12M1 (A) Cell lysates of CHO-K1 cells and CHO-K1 cells transiently transfected with pSM-MUC5AC-CH-short were subjected to affinity purification using Dynabeads Talon beads The purified proteins and cell lysates from CHO-K1 cells stably expressing M-MUC5AC-CH-long were analyzed by SDS ⁄ PAGE (3–10% gradient gels) under nonreducing conditions After western blotting, the membranes were probed with either 45M1, 463M or mAb against myc (amyc) (B) Immunoprecipitations using Dynabeads coated with either 45M1 or 463M were per-formed from cell lysates of CHO-K1 cells, CHO-K1 cells transiently transfected with pSM-MUC5AC-CH-short, and CHO-K1 cells stably expressing M-MUC5AC-CH-long The precipitates were analyzed by SDS ⁄ PAGE (3–10% gradient gels) under reducing conditions, and the proteins were blotted onto a membrane that was probed with the mAb against myc (C) Cell lysates of CHO-K1 cells and CHO-K1 cells transiently transfected with pSM-MUC5AC-CH-short were subjected to affinity purification using Dynabeads Talon beads The purified proteins and cell lysates from CHO-K1 cells stably express-ing M-MUC5AC-CH-long were analyzed by SDS ⁄ PAGE (3–10% gra-dient gels) under nonreducing conditions After western blotting, the membranes were probed with 2-12M1 (D) Cell lysates from CHO-K1 cells and CHO-K1 cells stably expressing M-MUC5AC-CH-long were separated by SDS ⁄ PAGE (3–10% gel) under both reduc-ing and nonreducreduc-ing conditions, and the proteins were blotted and subjected to detection by 166M1 AP, affinity purified;

R, reduced samples; NR, nonreduced samples; IB, mAb used for detection; Dimer, dimeric M-MUC5AC-CH; Monomer, monomeric M-MUC5AC-CH; M-5AC-CH, reduced M-MUC5AC-CH; C2-H, C-ter-minal cleavage fragment The weak band corresponding to the C2-H cleavage fragment is indicated by an asterisk in (D) Positions

of molecular mass standards are indicated on the right-hand side.

CHO-K1 cells permanently expressing

M-MUC5AC-CH-long and of M-MUC5AC-CH-short affinity

purified from cell lysates of CHO-K1 cells transfected

with the pSM-MUC5AC-CH-short plasmid The

SDS⁄ PAGE separation was performed under

nonre-ducing conditions, as the previous results indicated

that the 45M1 epitope was reduction-sensitive The

result clearly showed that the 91 amino acids

N-termi-nal to the L31 expression product are crucial for 45M1

reactivity, as only M-MUC5AC-CH-long was detected

(Fig 3A) That similar amounts of M-MUC5AC-short

and M-MUC5AC-long were loaded is shown by the

reactivity of the mAb against myc One reason for the

requirement of the N-terminal 91 amino acids could

be that these are necessary for the correct folding of

the protein, and that the lack of them leads to a

misfolded protein The 463M mAb has a

reduction-sensitive epitope, indicating that a correctly folded

pro-tein is necessary for its reactivity The 463M epitope

has previously been mapped to the von Willebrand

D4 domain of MUC5AC [16] The result after using

the 463M mAb for detection in the western blot

indi-cates that M-MUC5AC-CH-short is correctly folded

at least as far N-terminally as the von Willebrand

D4 domain, as the reactivity of the mAb towards this

protein is as strong as that against

M-MUC5AC-CH-long To rule out the possibility that the lack of

reac-tivity of 45M1 against M-MUC5AC-CH-short was

due to the denaturating conditions during SDS⁄ PAGE,

this mAb as well as 463M was used for

immunoprecip-itations from cell lysates of cells expressing either

M-MUC5AC-CH-short or M-MUC5AC-CH-long

prior to SDS⁄ PAGE and western blotting (Fig 3B)

The results after probing the membrane with the mAb

against myc are consistent with those of the

previ-ous experiments, as M-MUC5AC-CH-long but not

M-MUC5AC-CH-short was precipitated by 45M1,

whereas both forms were precipitated by 463M Hence,

the results imply that the 45M1 epitope is not

destroyed during SDS⁄ PAGE, but rather that the

epi-tope is located in the part missing in

M-MUC5AC-CH-short Although one cannot exclude the possibility

that the lack of the N-terminal 91 amino acids leads to

an incorrectly folded protein N-terminally to the

von Willebrand D4 domain, it is more likely that the

epitope for 45M1 is located within this sequence

Moreover, this 91 amino acid sequence contains a part

of the last CysD domain preceded by a 13 amino acid

sequence that shows little homology with the

corre-sponding rat and mouse sequences In contrast, the

fragment of the CysD domain, especially the sequence

between amino acids 18 and 52 (in the MUC5AC

sequence of M-MUC5AC-CH-long), shows strong

homology between the rat, mouse and human proteins (Fig 1) As 45M1 reacts strongly with the mucin from both rat, mouse and human [24], our results suggest that the 45M1 epitope is associated with such a sequence alone or that it is discontinuous and built up

of parts found in both this sequence and more C-ter-minal ones

The 2-12M1 mAb is also sold as a mAb specific against MUC5AC, although its specificity has not been clearly demonstrated The 2-12M1 epitope has been reported to be reduction-sensitive [12], an observation also supported by our results (Fig 2B) The 2-12M1 mAb has previously been tested against COS-7 cells transfected with an L31-containing expression plasmid, but no reactivity against the expression product could

be detected [16] However, our initial results showed that 2-12M1 reacted with M-MUC5AC-CH-long (Fig 2A), suggesting that the 91 amino acids that are absent in the L31 expression product could be neces-sary to build the 2-12M1 epitope The 2-12M1 mAb was tested on western blots, like 45M1, after separa-tion of the samples by SDS⁄ PAGE under nonreduc-ing conditions (Fig 3C) The result shows that 2-12M1 reacted with both M-MUC5AC-long and M-MUC5AC-short In M-MUC5AC-CH-short, an additional nine amino acids have been added N-termi-nally to the L31 expression product One possibility is, therefore, that the epitope is located within these nine amino acids The results definitely show that 2-12M1

is a mAb against MUC5AC and that its epitope is located in the C-terminal cysteine-rich part

Our results indicated that 166M1 detected an epitope located C-terminally to the GDPH-cleavage site, as a very faint band corresponding to the C2-H fragment was detected when probing western blots of cell lysates from CHO-K1 cells expressing M-MUC5AC-CH-long with this mAb (Fig 2B) To rule out the possibility that the band was nonspecific, cell lysates from both CHO-K1 cells and CHO-CHO-K1 cells expressing M-MUC5AC-CH-long were separated by SDS⁄ PAGE under reducing and nonreducing conditions, and the proteins were blotted to a membrane, which was probed with 166M1 (Fig 3D) The results clearly show that 166M1 detects both nonreduced and reduced protein and that the epitope is located within the C-terminal cleavage fragment, as a specific band corresponding to the C2-H fragment was detected in the reduced sample

Testing 45M1, 2-12M1 and 166M1 for cross-reactivity with MUC2

The gel-forming mucins share common domain struc-tures and show a high degree of sequence homology,

especially with regard to the positions of their cysteines

[1] In many cases, these mucins also present an

over-lapping expression profile Hence, it is important to

determine, when a particular antibody against mucin is

used, whether it shows cross-reactivity towards other

mucins Among the gel-forming mucins, the MUC5AC

C-terminus shows the highest similarities with the

MUC2 C-terminus To analyze potential

cross-reacti-vity, 45M1, 2-12M1 and 166M1 were tested against

the C-terminal cysteine-rich domain of human MUC2

(Fig 4) Cell lysates from CHO-K1 cells expressing

either M-MUC5AC-CH-long or a recombinant MUC2

C-terminal cysteine-rich domain were separated by

SDS⁄ PAGE and blotted onto a membrane The 45M1,

2-12 M1 and 166M1 mAbs as well as the mAb against myc were then used for detection Only the mAb against myc detected the recombinant MUC2 C-termi-nal cysteine-rich domain, indicating that the mAbs against MUC5AC do not cross-react with MUC2 Hence, although human MUC5AC and MUC2 are highly similar, 45M1, 2-12 M1 and 166M1 seem to be specific for MUC5AC

Conclusions and future aspects This study shows that the widely used 45M1 as well as 2-12M1 and 166M1 are true mAbs against MUC5AC, with their epitopes located in the C-terminal cysteine-rich part of the protein Fig 5 shows a more detailed map of the epitopes for the mAbs, where 45M1 recog-nizes an epitope located in the N-terminal region of the C-terminal cysteine-rich part of MUC5AC, pre-sumably in the last CysD domain of the mucin The epitope of 2-12M1 is located in the sequence corre-sponding to the expression product of the L31 clone, whereas the epitope for 166M1 is located C-terminally

to the GDPH-cleavage site of MUC5AC The mAbs against M1 were selected, by screening the superna-tants of hybridomas using immunohistology, as having immunoreactivity against the mucus of goblet cells of colon adenomas and a lack of reactivity against the mucus of goblet cells of normal colon [12,16,23] It is noteworthy that among the 12 different mAbs isolated

by this technique, 11 recognized the product of one unique gene: MUC5AC The fact that the mAbs against M1 are mapped to different parts of MUC5AC

Fig 4 Testing the cross-reactivity of 45M1, 166M1 and 2-12M1

towards the C-terminal cysteine-rich domain of human MUC2 Cell

lysates from CHO-K1 cells and CHO-K1 cells stably expressing

either M-MUC5AC-CH-long or the corresponding C-terminal

cyste-ine-rich domain of human MUC2 were separated by SDS ⁄ PAGE

(3–10% gel) under nonreducing conditions After western blotting,

the mAb against myc (amyc), 45M1, 166M1 or 2-12M1 was used

for detection IB, mAb used for detection The positions of the

dimeric forms of the recombinant MUC5AC and MUC2 proteins

are indicated on the left Positions of molecular mass standards are

indicated on the right-hand side.

Fig 5 Mapping of the 45M1, 166M1 and 2-12M1 epitopes on the C-terminal cysteine-rich part of human MUC5AC The upper part of the figure shows a schematic representation of full-length human MUC5AC with its domains The C-terminal region of the protein is expanded, and its domains and GDPH-cleavage site are indicated In the lower part of the figure, the mapped regions for the 45M1, 166M1 and 2-12M1 epitopes are shown.

makes them potentially valuable tools for future

stud-ies of this protein By use of 62M1 and the knowledge

that it reacts with an epitope mapped to the von

Wille-brand C domain and cysteine-knot domain of

MUC5AC, it could be shown in a previous study that

wild-type MUC5AC is partially cleaved at its GDPH

sequence [20] This is an example showing that the use

of a well-defined mAb against M1 allows studies aimed

at deciphering cleavage patterns of the full-length

mucin The present study maps the epitopes of three

previously unmapped mAbs against M1 to different

parts of the C-terminal cysteine-rich part of human

MUC5AC The results showing that the widely used

45M1 is a true mAb against MUC5AC are of

particu-lar importance, as they verify the more than 80

previ-ous publications in which 45M1 has been used as a

mAb against MUC5AC

Experimental procedures

mAbs against human gastric mucin

Twelve mAbs against the peptide core of gastric mucins,

called mAbs against M1, were used in this study: 1-13M1,

2-11M1, 2-12M1, 9-13M1, 58M1 [12], 19M1, 21M1, 45M1

[23], 463M, 589M and 62M1 [16], and 166M1 The

hybrid-oma secreting 166M1 was raised from the cell fusion used

when isolating the hybridoma secreting 62M1 [16] In short,

a mouse was immunized with gastric mucin isolated from

an OLe(a)b+) individual and purified using successive

chromatography steps on Sepharose 6B and 2B The

super-natants of the hybridomas were screened, and the clones

were selected by their strong reaction against the gastric

surface epithelium and colon adenomas and their lack of

immununoreactivity on normal colon

The mAb against myc was obtained from spent culture

media of the 1-9E10.2 hybridoma (ATCC CRL-1729)

Other antibodies used were: mAb against His5 (Qiagen,

Valencia, CA, USA) and goat anti-(mouse IgG) coupled to

alkaline phosphatase (goat-a-mouse-AP) (Southern Biotech,

Birmingham, AL, USA)

Construction of MUC5AC vectors

The cDNA clone L31 [21], encoding almost the complete

C-terminal cysteine-rich part of human MUC5AC (lacks

the N-terminal 91 amino acids of this part), inserted into a

pBluescript vector, was used as template for the

amplifica-tion of the MUC5AC sequence With use of the primer

pair 5¢-TATTCTAGAG AAGAGGGCCT GGTGTGCCGG

AACCAGGACC AGCAGGGACC CTTCAAG-3¢ (GH262)

and 5¢-ACGCGCTAGC TCAATGATGA TGATGATGGT

GCATGGGGGA CACTGGGACG CC-3¢ (GH263), the

MUC5AC-encoding sequence could be amplified by PCR

The primer GH262 introduced an XbaI site in the 5¢-end of the PCR product It also added a nucleotide stretch coding for the amino acid sequence SREEGLVCR This sequence

is found N-terminally of the MUC5AC sequence encoded

by the L31 sequence [22,25] The primer GH263 introduced

a His-tag and an NheI site in the 3¢-end of the PCR product The PCR product was ligated into the XbaI site of the previ-ously described pSM vector [26] This vector is based on the pEGFP-C1 vector (Clontech, Palo Alto, CA, USA), where the green fluorescent protein sequence has been replaced with

a murine Ig j-chain signal sequence from pSec Tag A (Invitrogen, Carlsbad, CA, USA) followed by a myc-tag (EQKLISEEDL) The resulting vector, pSM-MUC5AC-CH-short, was used for transfection of CHO-K1 cells

A vector encoding the complete C-terminal cysteine-rich part, pSM-MUC5AC-CH-long, has been described before [20] In short, NP3a [22], a cDNA clone corresponding to the 3¢-end of human MUC5AC inserted into a pBluescript vector, was used as a template for PCR With use of the primer pair 5¢-GCTTCTAGAC ACGAGAAGAC AACCC ACTCC C-3¢ (GH287) and 5¢-GCGAGGTCTC TGTGG CGGTA TATGGTG-3¢ (GH288), the 5¢-part missing in the L31 clone could be amplified GH287 introduced an XbaI site in the 5¢-end of the PCR product, and the amplified product could then be ligated into the pSM-MUC5AC-CH-short vector by its XbaI–BamHI sites

Recombinant expression and tissue culture The pSM-MUC5AC-CH-short plasmid, encoding an

Ig j-chain signal sequence followed by a myc-tag, the last

959 amino acids of the human MUC5AC C-terminal cyste-ine-rich part and a His-tag, was transfected into CHO-K1 cells (ATCC CCL-61) using Lipofectamine 2000 (Invitro-gen) Twenty-four hours after transfection, cell lysates were prepared

A CHO-K1 cell line stably expressing M-MUC5AC-CH-long, the protein encoded by pSM-MUC5AC-CH-M-MUC5AC-CH-long, has been described previously [20] This protein encodes an

Ig j-chain signal sequence followed by a myc-tag, the com-plete human MUC5AC C-terminal cysteine-rich part (1041 amino acids), and a His-tag

A CHO-K1 cell line expressing the last 981 amino acids

of human MUC2 (corresponding to the complete C-termi-nal cysteine-rich part) fused to an Ig j-chain sigC-termi-nal sequence, a myc-tag and green fluorescent protein at its N-terminus has been described previously [26]

The CHO-K1 cells were cultured as described previously for LS174T [27], with the addition of 250 lgÆmL)1G418 to the cells stably expressing recombinant proteins

Preparation of cell lysates The cell culture medium was removed, and the cells were washed twice with NaCl⁄ Pi The cells were lysed in lysis

buffer [50 mm Tris⁄ HCl, pH 7.9, 50 mm NaCl, 1% (v ⁄ v)

Triton X-100] containing protease inhibitors [2· Complete

(Roche, Indianapolis, IN, USA)] and 5 mm

N-ethylmalei-mide After sonication (intensity 15) three times for 2 s

(MSE Soniprep 100 sonifier), the cell debris was removed

by centrifugation (16 000 g for 10 min at 4C)

Affinity purification of recombinant MUC5AC

C-terminus from cell lysates

Cell lysates from CHO-K1 cells and CHO-K1 cells

tran-siently transfected with the pSM-MUC5AC-CH-short

plas-mid were incubated with Dynabeads Talon beads (Dynal,

Oslo, Norway) for 2 h at 4C The beads were washed

twice with lysis buffer before the proteins were eluted in

20 mm sodium phosphate (pH 7.4), 0.5 m NaCl, and 0.2 m

imidazole

Immunoprecipitation

Fifty microliters of Dynabeads M-450 (Dynal) were washed

three times with NaCl⁄ Pi, 0.1% BSA, and 0.1% sodium

azide, and incubated on a shaker for 1 h at room

tempera-ture with 30 lL of hybridoma supernatant The beads were

washed twice with lysis buffer before cell lysate was added

(1 mg of total protein) After incubation overnight at 4C,

the beads were washed three times with lysis buffer before

the proteins were released into the sample buffer with

200 mm dithiothreitol at 95C for 5 min

SDS⁄ PAGE

The cell lysates were mixed with Laemmli sample buffer

with or without 200 mm dithiothreitol and incubated for

5 min at 95C [28] The samples were analyzed by

discon-tinuous SDS⁄ PAGE, using 3–10% gradient gels with

3% stacking gels The molecular marker used was the

Pre-cision Protein Standard (Bio-Rad, Hercules, CA, USA)

Western blotting and immunodetection

The proteins were transferred to poly(vinylidene difluoride)

membranes (Immobilon-PSQ, 0.20 lm; Millipore) in a

Transfer-Blot SD-Dry Transfer Cell (Bio-Rad) at

2.5 mAÆcm)2 for 1 h The transfer buffer used contained

48 mm Tris, 39 mm glycine, 1.3 mm SDS, and 10% (v⁄ v)

methanol After blotting, the membranes were placed in

blocking solution and incubated overnight at 4C NaCl ⁄ Pi

containing 5% (w⁄ v) milk powder and 0.1% (v ⁄ v) Tween-20

was used as blocking solution when using the mAb against

myc and the mAbs against M1 for detection

BSA (2%, w⁄ v) in 10 mm Tris ⁄ HCl, 100 mm NaCl and

0.1% (v⁄ v) Tween-20 (pH 7.5) was used as blocking solution

when the mAb against His5 was used for detection After

blocking, the membranes were incubated with either mAb against myc (1 lgÆmL)1), mAb against His5 (100 ngÆmL)1)

or the mAbs against M1 (1 : 1000) in blocking solution for

2 h at room temperature The membranes were washed

3· 5 min with NaCl ⁄ Pi containing 0.1% (v⁄ v) Tween-20 and incubated with goat-a-mouse-AP (1 : 1000) in blocking solution for 1.5 h at room temperature After another NaCl⁄ Pi containing 0.1% (v ⁄ v) Tween-20 wash (3 · 5 min), the membranes were developed with Nitro Blue tetrazolium⁄ 5-bromo-4-chloroindol-2-yl phosphate (Promega, Madison,

WI, USA)

Acknowledgements

We are indebted to Drs Francisco Real and Mary Rose for partial cDNA clones The work was sup-ported by the Swedish Heart and Lung Foundation, Swedish Research Council (No 7461), IngaBritt and Arne Lundberg’s Foundation, and the Swedish Foun-dation for Strategic Research-Mucosa, Immunity and Vaccine Center (MIVAC)

References

1 Perez-Vilar J & Hill RL (1999) The structure and assem-bly of secreted mucins J Biol Chem 274, 31751–31754

2 Gum J Jr, Hicks J, Toribara N, Siddiki B & Kim Y (1994) Molecular cloning of human intestinal mucin (MUC2) cDNA Identification of the amino terminus and overall sequence similarity to prepro-von Wille-brand factor J Biol Chem 269, 2440–2446

3 Desseyn J-L, Buisine M-P, Porchet N, Aubert J-P & Laine A (1998) Genomic organization of the human mucin gene MUC5B J Biol Chem 273, 30157–30164

4 Li D, Gallup M, Fan N, Szymkowski DE & Basbaum

CB (1998) Cloning of the amino-terminal and 5¢-flank-ing region of the human MUC5AC mucin gene and transcriptional up-regulation by bacterial exoproducts

J Biol Chem 273, 6812–6820

5 Toribara N, Roberton A, Ho S, Kuo W, Gum E, Hicks J, Gum J Jr, Byrd J, Siddiki B & Kim Y (1993) Human gastric mucin Identification of a unique species by expression cloning J Biol Chem 268, 5879– 5885

6 Bobek L, Tsai H, Biesbrock A & Levine M (1993) Molecular cloning, sequence, and specificity of expres-sion of the gene encoding the low molecular weight human salivary mucin (MUC7) J Biol Chem 268, 20563–20569

7 Chen Y, Zhao YH, Kalaslavadi TB, Hamati E, Nehrke

K, Le AD, Ann DK & Wu R (2004) Genome-wide search and identification of a novel gel-forming mucin MUC19⁄ Muc19 in glandular tissues Am J Respir Cell Mol Biol 30, 155–165

8 Bara J, Languille O, Gendron MC, Daher N, Martin E

& Burtin P (1983) Immunohistological study of

pre-cancerous mucus modification in human distal colonic

polyps Cancer Res 43, 3885–3891

9 Bara J, Andre J, Gautier R & Burtin P (1984)

Abnor-mal pattern of mucus-associated M1 antigens in

histo-logically normal mucosa adjacent to colonic

adenocarcinomas Cancer Res 44, 4040–4045

10 Bara J, Loisillier F & Burtin P (1980) Antigens of

gas-tric and intestinal mucous cells in human colonic

tumours Br J Cancer 41, 209–221

11 Bara J & Burtin P (1980) Mucus-associated

gastrointes-tinal antigens in transitional mucosa adjacent to human

colonic adenocarcinomas: their ‘fetal-type’ association

Eur J Cancer 16, 1303–1310

12 Bara J, Gautier R, Daher N, Zaghouani H & Decaens

C (1986) Monoclonal antibodies against oncofetal

mucin M1 antigens associated with precancerous

colo-nic mucosae Cancer Res 46, 3983–3989

13 Sessa F, Bonato M, Frigerio B, Capella C, Solcia E,

Prat M, Bara J & Samloff IM (1990) Ductal cancers

of the pancreas frequently express markers of

gastro-intestinal epithelial cells Gastroenterology 98, 1655–

1665

14 Nollet S, Escande F, Buisine MP, Forgue-Lafitte ME,

Kirkham P, Okada Y & Bara J (2004) Mapping of

SOMU1 and M1 epitopes on the apomucin encoded by

the 5¢ end of the MUC5AC gene Hybrid Hybridomics

23, 93–99

15 Bara J, Chastre E, Mahiou J, Singh RL, Forgue-Lafitte

ME, Hollande E & Godeau F (1998) Gastric

M1 mucin, an early oncofetal marker of colon

carcino-genesis, is encoded by the MUC5AC gene Int J Cancer

75, 767–773

16 Nollet S, Forgue-Lafitte ME, Kirkham P & Bara J

(2002) Mapping of two new epitopes on the apomucin

encoded by MUC5AC gene: expression in normal GI

tract and colon tumors Int J Cancer 99, 336–343

17 Kocer B, Soran A, Kiyak G, Erdogan S, Eroglu A,

Bozkurt B, Solak C & Cengiz O (2004) Prognostic

significance of mucin expression in gastric carcinoma

Dig Dis Sci 49, 954–964

18 Mitsuhashi A, Yamazawa K, Nagai Y, Tanaka N,

Mat-sui H & Sekiya S (2004) Correlation between MUC5AC

expression and the prognosis of patients with

adenocar-cinoma of the uterine cervix Ann Surg Oncol 11, 40–44

19 Wang JY, Chang CT, Hsieh JS, Lee LW, Huang TJ,

Chai CY & Lin SR (2003) Role of MUC1 and

MUC5AC expressions as prognostic indicators in

gas-tric carcinomas J Surg Oncol 83, 253–260

20 Lidell ME & Hansson GC (2006) Cleavage in the GDPH sequence of the C-terminal cysteine-rich part of the human MUC5AC mucin Biochem J 399, 121–129

21 Lesuffleur T, Roche F, Hill AS, Lacasa M, Fox M, Swallow DM, Zweibaum A & Real FX (1995) Charac-terization of a mucin cDNA clone isolated from HT-29 mucus-secreting cells J Biol Chem 270, 13665–13673

22 Meerzaman D, Charles P, Daskal E, Polymeropoulos

M, Martin B & Rose M (1994) Cloning and analysis of cDNA encoding a major airway glycoprotein, human tracheobronchial mucin (MUC5) J Biol Chem 269, 12932–12939

23 Bara J, Gautier R, Mouradian P, Decaens C & Daher

N (1991) Oncofetal mucin M1 epitope family: charac-terization and expression during colonic carcinogenesis Int J Cancer 47, 304–310

24 Maes G, Fleuren GJ, Bara J & Nap M (1988) The dis-tribution of mucins, carcinoembryonic antigen, and mucus-associated antigens in endocervical and endome-trial adenocarcinomas Int J Gynecol Pathol 7, 112–122

25 Buisine MP, Desseyn JL, Porchet N, Degand P, Laine

A & Aubert JP (1998) Genomic organization of the 3¢-region of the human MUC5AC mucin gene:

additional evidence for a common ancestral gene for the 11p15.5 mucin gene family Biochem J 332, 729–738

26 Lidell ME, Johansson ME, Morgelin M, Asker N, Gum JR Jr, Kim YS & Hansson GC (2003) The recom-binant C-terminus of the human MUC2 mucin forms dimers in Chinese-hamster ovary cells and heterodimers with full-length MUC2 in LS 174T cells Biochem J 372, 335–345

27 Asker N, Baeckstrom D, Axelsson MA, Carlstedt I & Hansson GC (1995) The human MUC2 mucin apopro-tein appears to dimerize before O-glycosylation and shares epitopes with the ‘insoluble’ mucin of rat small intestine Biochem J 308, 873–880

28 Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4 Nature 227, 680–685

29 Escande F, Porchet N, Bernigaud A, Petitprez D, Aubert JP & Buisine MP (2004) The mouse secreted gel-forming mucin gene cluster Biochim Biophys Acta

1676, 240–250

30 Inatomi T, Tisdale AS, Zhan Q, Spurr-Michaud S & Gipson IK (1997) Cloning of rat Muc5AC mucin gene: comparison of its structure and tissue distribution to that of human and mouse homologues Biochem Biophys Res Commun 236, 789–797