Journal of Histochemistry and Cytochemistry, Vol. 45, 1567-1582, Copyright © 1997 by The Histochemical Society, Inc.


ARTICLE

Production of a Monoclonal Antibody by In Vitro Immunization That Recognizes a Native Chondroitin Sulfate Epitope in the Embryonic Chick Limb and Heart

Anthony A. Capeharta, Matthew M. Wienecke1,a, Gregory T. Kittenb, Michael Solursh2,b, and Edward L. Kruga
a Department of Cell Biology and Anatomy, Medical University of South Carolina, Charleston, South Carolina
b Department of Biological Sciences, University of Iowa, Iowa City, Iowa

Correspondence to: Anthony A. Capehart, Dept. of Cell Biology and Anatomy, Medical U. of South Carolina, 171 Ashley Ave., Charleston, SC 29425.


  Summary
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

We report the production of a monoclonal antibody (d1C4) by in vitro immunization that has immunoreactivity with a native chondroitin sulfate epitope in embryonic chick limb and heart. Murine lymphocytes were stimulated by direct exposure to unfixed, unsolubilized precartilage mesenchymal aggregates in high-density micromass culture derived from Stage 22-23 chick limb buds. Specificity of d1C4 reactivity was demonstrated by sensitivity of immunohistochemical staining to pretreatment with chondroitinase ABC or AC, preferential immunoreactivity with chondroitin-6-sulfate glycosaminoglycan (CS-C GAG) in ELISA, and competition of immunohistochemical staining with CS-C GAG. Immunohistochemical analysis of the expression of the d1C4 epitope revealed a striking localization of immunoreactivity in the extracellular matrix (ECM) of precartilage aggregates of chick limb mesenchyme in high-density micromass culture by 16 hr and the prechondrogenic limb core at Stage 23 in vivo. Immunoreactivity in both cultured limb mesenchyme and the embryonic limb continued through differentiation of prechondrogenic condensations into cartilage tissue. In the developing chick heart, d1C4 staining was found throughout the ECM of atrioventricular cushion tissue by Stage 25, but was localized to mesenchyme adjacent to the myocardium in the outflow tract cushions. There was an abrupt demarcation between d1C4-reactive intracardiac mesenchyme and unreactive extracardiac mesenchyme of the dorsal mesocardium in the Stage 22 embryo. This study demonstrates the efficacy of in vitro immunization of lymphocytes for the production of MAbs to native ECM constituents, such as CS-GAGs. Immunohistochemical data utilizing d1C4 suggest that CS-GAGs bearing this epitope may be important in early morphogenetic events leading to cartilage differentiation in the limb and valvuloseptal morphogenesis in the heart. (J Histochem Cytochem 45:1567-1581, 1997)

Key Words: in vitro immunization, monoclonal antibodies, extracellular matrix, chondroitin sulfate, proteoglycan, chondrogenesis, limb development, heart development


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Proteoglycans (PGs) are integral constituents of the extracellular matrix (ECM) and are of critical importance during many morphological processes, including proliferation, migration, tissue remodeling, and differentiation. Many of the roles played by PGs during development are attributed to their associated glycosaminoglycan (GAG) moieties (Rouslahti 1988 ; Kjellen and Lindahl 1991 ). It is known that GAG chains can vary on a given PG core protein and that these variations may reflect spatial and temporal patterns in response to changing functional needs during tissue differentiation and maturation (Mark et al. 1989 ; Caterson et al. 1990 ; Sorrell et al. 1990 ; Fernandez-Teran et al. 1993 ). It has been our interest to explore the role of GAGs in critical morphogenetic events during embryonic limb and cardiac development, particularly the identification and characterization of GAGs involved in the processes of prechondrogenic mesenchymal condensation formation in the limb (Fell 1925 ) and in the transformation of cardiac endothelial cells into atrioventricular (AV) cushion tissue in the heart (Markwald et al. 1975 ).

To study the intricate processes involved in these critical morphological events, it is often advantageous to utilize immunological probes to native ECM components. Such reagents are useful in the evaluation of ECM interactions by avoiding artifactual alterations in the organization of the matrix caused by the enzymatic creation or unmasking of epitopes for immunohistochemical analyses. One problem with the identification of ECM components such as GAGs, however, has been the difficulty in producing antibodies to the native structure. This difficulty is due in large part to the poor immunogenicity of many ECM molecules, particularly carbohydrate sequences of GAG chains (Avnur and Geiger 1984 ; Rouslahti 1988 ; Sorrell et al. 1990 ). The use of in vitro immunization of mouse lymphocytes (Luben and Mohler 1980 ) offers a potential solution to this problem because the tolerance for conserved immunogens in vivo may be overridden by lymphocytes in culture (Reading 1982 ).

In this article we report the preparation of a monoclonal antibody (d1C4) by in vitro stimulation of isolated lymphocytes with cultured limb mesenchyme. Characterization of MAb d1C4 demonstrates that it preferentially recognizes a native epitope on GAG chains enriched in chondroitin-6-sulfate. Immunofluorescence microscopy localizes the d1C4 epitope in prechondrogenic aggregates of chick limb mesenchyme in vitro and in the prechondrogenic limb core and cardiac cushion tissue in vivo.


  Materials and Methods
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Cell Cultures
High-density micromass cultures were prepared using Stage 22-23 (Hamburger and Hamilton 1951 ) chick limb buds with a slight modification of the procedure described by Ahrens et al. 1977 . Briefly, limb buds were removed, washed in PBS, and incubated for 15 min at 37C in 0.1% trypsin-PBS. The enzymatic digestion was stopped by the addition of complete medium, i.e., Ham's F-12 (Gibco; Gaithersburg, MD) containing 10% fetal bovine serum (FBS; Hyclone Laboratories, Logan, UT) and 100 U/ml penicillin-100 µg/ml streptomycin (Gibco). The cell suspension was centrifuged and the pellet was suspended in complete medium and filtered through two layers of #10 Nitex. Cell number was adjusted to 2 x 107 cells/ml and 10-µl drops were plated in 35-mm tissue culture dishes (Falcon; Becton Dickinson Labware, Lincoln Park, NJ). Cultures were incubated for 1 hr at 37C in a humidified atmosphere of 95% air/5% CO2 and then flooded with 2 ml complete medium. Cultures were maintained up to 3 days with complete changes of medium daily. In selected experiments, micromass cultures were grown for 3 days in complete medium containing 2 mM p-nitro-phenyl-ß-D-xylopyranoside (Sigma Chemical; St Louis, MO) (Goetinck and Carlone 1988 ) to inhibit attachment of GAG chains to the core proteins of PGs.

Production of Monoclonal Antibodies In Vitro
Four 0.1-ml micromass cultures of chick limb mesenchyme (prepared as described above) were established in separate wells of a 24-well tissue culture plate (Corning; Ithaca, NY). After 24 hr of incubation, cultures were washed three times with sterile PBS and air-dried under laminar flow following the method of Gilbert et al. 1990 for the preparation of renal collecting duct epithelia for in vitro immunization.

Thymocyte conditioned medium was prepared by a modification of the method of van Ness et al. 1984 . Thymus glands from four 6-week female Balb/C mice were dissected aseptically, teased apart with 21-gauge needles, and washed with serum-free RPMI (SFRPMI; Gibco). Thymocytes were suspended in RPMI 1640 containing 40% heat-inactivated fetal calf serum (HIFCS; Gibco) and 4 mM glutamine, 2 mM sodium pyruvate, 100 µM ß-mercaptoethanol, and antibiotics (representing a 2 x supplemented medium stock) for subsequent in vitro immunization. Thymocytes were cultured in T25 flasks (Corning) for 3 days. Cells were removed by centrifugation and thymocyte conditioned medium was stored at -20C until use.

Macrophages were obtained from a nonimmunized 7-week female Balb/C mouse by peritoneal lavage with Hank's balanced saline solution (Campbell 1984 ). The same mouse was used to harvest splenocytes using standard procedures (Harlow and Lane 1988 ).

Each of four air-dried prechondrogenic micromass cultures of chick limb mesenchyme received 1 x 107 splenocytes and 1.8 x 104 peritoneal macrophages in 1 ml SFRPMI containing 30 µg/ml N-acetylmuramyl-L-alanyl-D-isoglutamine (MDP) as adjuvant (Calbiochem; San Diego, CA) (Boss 1986 ). Splenocytes were exposed to the micromass cultures in SFRPMI-MDP for 1.5 hr at 37C in a humidified atmosphere of 95% air/5% CO2 and then supplemented with an equal volume of thymocyte conditioned medium. Cultures were maintained for 6 days without further additions.

Stimulated splenocytes were harvested by centrifugation and fused with the myeloma cell line SP2/0 at a ratio of 3:1 with 50% polyethylene glycol (MW 1500; Boehringer Mannheim, Indianapolis, IN). After fusion, cells were seeded in a single 24-well tissue culture plate (Corning) at a density equivalent to 2 x 105 myeloma cells/ml (pre-fusion count) in RPMI containing 20% HIFCS and 150 µg/ml oxaloacetate, 50 µg/ml sodium pyruvate, 5 µg/ml insulin (modified from Harlow and Lane 1988 ), 100 µM hypoxanthine, 400 µM aminopterin, and 16 µM thymidine (HAT; Boehringer Mannheim). Hybridomas were screened on Day 10 by indirect immunofluorescence on frozen sections of Stage 24 wing buds. After HAT selection and weaning with medium containing HT, hybridomas were grown routinely in RPMI with 10% HIFCS. Selected hybridomas were subcloned twice by limiting dilution (Campbell 1984 ). All antibodies derived from this in vitro immunization protocol were of the IgM class.

Antibody Purification
Antibodies were purified from tissue culture supernatants using anti-mouse IgM-agarose (Sigma). Bound antibodies were eluted with 0.1 M glycine, pH 2.6, containing 150 mM NaCl. Fractions were neutralized immediately with 1 M Tris, pH 8, and the aliquots were dot-blotted onto nitrocellulose (Bio-Rad Laboratories; Hercules, CA) and stained with 0.1% amido black (Sigma) to detect protein. Fractions containing eluted antibodies were concentrated and exchanged into PBS using Centricon-10 ultrafiltration devices (Amicon; Beverly, MA). Protein content was determined using the Micro BCA protein assay kit (Pierce; Rockford, IL).

Immunohistochemistry
Micromass cultures of chick limb mesenchyme were fixed in 80% methanol-20% DMSO (Dent's fixative) at room temperature (RT) and processed for indirect immunofluorescence microscopy in the tissue culture dishes. Cultures were rehydrated in PBS and blocked for 30 min at RT with PBS containing 2% bovine serum albumin (BSA; Sigma) and 1% normal goat serum (NGS; Cappel Research Products, Durham, NC). Fixed specimens were incubated for 1 hr with 10 µg/ml d1C4 or undiluted tissue culture supernatants, washed three times with PBS, then incubated for 1 hr with a 1:100 dilution of fluorescein-conjugated goat anti-mouse IgM or IgG (Cappel) in BSA-PBS. For double labeling with rhodamine-conjugated peanut agglutinin (RhPNA; Vector Laboratories, Burlingame, CA), selected cultures that had been reacted with antibodies as described above were washed with PBS and incubated with 0.1 mg/ml RhPNA in PBS for 30 min. All specimens were washed four times with PBS and mounted in 10% PBS-90% glycerol containing 25 mg/ml 1,4-diazabicyclo(2,2,2)octane (DABCO; Sigma) (Johnson et al. 1982 ). In selected experiments, micromass cultures were fixed in ethanol containing 3% glacial acetic acid for 10 min, washed with 0.1 N HCl, and stained with 1% Alcian blue-0.1 N HCl (Lev and Spicer 1964 ) for 1 hr to reveal chondrogenic foci. Cell layers were destained with 0.1 N HCl, washed thoroughly with PBS, and processed for indirect immunofluorescence microscopy.

Chick embryos were fixed in 80% methanol-20% DMSO at -20C, embedded in paraffin, and sectioned at 5 µm. Alternatively, embryonic chick thoracic regions with attached hearts were cryopreserved by freeze-substitution into ethanol (Kitten et al. 1987 ), followed by embedding in paraffin. Deparaffinized sections were rehydrated to PBS, blocked with BSA-PBS containing 1% NGS, and processed as above with primary antibody incubations overnight at 4C in a humidified chamber and fluorescein-conjugated secondary antibody incubations for 2 hr at RT. Sections were washed four times with PBS after each antibody incubation and mounted in DABCO medium.

Controls for immunohistochemistry included omission of the primary antibody or use of an irrelevant IgM. Specificity of d1C4 immunoreactivity was also tested by inclusion of a 100-fold (w/w) excess of chondroitin sulfate Type A (CS-A, sturgeon notochord; Seikagaku America, Rockville, MD) or chondroitin sulfate type C GAGs (CS-C, shark cartilage; Sigma) with the primary antibody incubation. II6B3, an MAb to Type II collagen, was obtained through the Developmental Studies Hybridoma Bank maintained by the Department of Biological Sciences, University of Iowa. Specimens were examined with a Zeiss Axioskop equipped with epifluorescence optics and were photographed using Kodak TMAX 400 film.

Characterization of the d1C4 Epitope
Fixed micromass cultures were treated for 2 hr at 37C with either 0.1 U/ml chondroitinase ABC (Sigma) in 0.1 M Tris, pH 8, or 0.2 U/ml chondroitinase AC (Sigma) in PBS, pH 7.2, before immunostaining. For hyaluronidase digestion, micromass cultures and deparaffinized tissue sections were incubated for 30 min at RT in 0.1% testicular hyaluronidase (Sigma) in 50 mM sodium acetate, pH 6, with 0.9% NaCl, 1 mM phenylmethylsulfonylfluoride (PMSF), 1 µM leupeptin, 1 µM pepstatin A, and 1 mM EDTA before blocking and immunofluorescence staining. Periodate oxidation of fixed micromass cultures was performed using 10 mM periodic acid in 50 mM sodium acetate, pH 4.5, for 1 hr in the dark as described previously (Woodward et al. 1985 ). Cultures were washed with PBS and incubated in 50 mM sodium borohydride-PBS for 30 min. Control cultures were incubated in 50 mM sodium acetate alone followed by reduction with 50 mM sodium borohydride. Cell layers were washed thoroughly with PBS before the blocking and immunostaining steps.

Microtiter plates (Immulon 4; Dynatech Laboratories, Chantilly, VA) were treated with 1 µg/ml poly-L-lysine (MW >300,000; Sigma) in PBS overnight at 4C, washed four times with PBS, then incubated for 2 hr at RT with CS-A (sturgeon notochord; Seikagaku) or CS-C GAGs (shark cartilage; Sigma), either alone or at various ratios of CS-A:CS-C. In other experiments, poly-L-lysine-coated plates were treated as above with 60 µg/ml CS-C (shark cartilage; Sigma and Seikagaku), chondroitin (from CS-A; Seikagaku), heparan sulfate (bovine kidney; Seikagaku), keratan sulfate (bovine cornea; Seikagaku), or dermatan sulfate GAGs (hog skin; Seikagaku). Wells were washed three times with PBS and treated for 1 hr with 1% BSA-PBS. Plates were washed with PBS and incubated for 1 hr at RT with 5 µg/ml d1C4 IgM in BSA-PBS or an irrelevant monoclonal IgM. After four washes with PBS, plates were incubated with a 1:5000 dilution of alkaline phosphatase-conjugated goat anti-mouse IgM (Sigma) in BSA-PBS for 1 hr at RT. Wells were washed five times with PBS before visualization of bound antibodies with 1 mg/ml p-nitrophenyl phosphate (Sigma) in 10 mM diethanolamine, pH 9.5, containing 0.5 mM MgCl2. Absorbance was measured at 405 nm using a Bio-Tek Microplate Autoreader (Bio-Tek Instruments; Winooski, VT).


  Results
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Mouse lymphocytes were immunized in vitro with unfixed, air-dried micromass cultures of chick limb mesenchyme to produce MAbs reactive with native ECM molecules expressed during the critical process of cellular aggregation preceding overt limb chondrogenesis. At the time of screening, macroscopic hybridoma colonies were found in 83% of wells (20/24 wells), with 40% of these (8/20) yielding MAbs reactive by indirect immunofluorescence microscopy on frozen chick limb sections. Several antibodies recognized ECM components in both embryonic limb buds and high-density cultures of limb mesenchyme, one of which, d1C4, is the subject of this report.

The MAb d1C4 exhibited particularly strong immunoreactivity with mesenchymal condensations in 24-hr micromass cultures (Figure 1A). Digestion of micromass cultures or tissue sections by testicular hyaluronidase pretreatment in the presence of protease inhibitors before antibody staining abolished reactivity with d1C4 (data not shown). This result suggested that the antigen was either hyaluronic acid or a chondroitin sulfate GAG, because both are digested by testicular hyaluronidase. Pretreatment of 24-hr micromass cultures with either chondroitinase ABC or chondroitinase AC also revealed sensitivity of the d1C4 epitope (Figure 1B), suggesting that the antigen was a chondroitin sulfate. Periodate treatment of micromass cultures of limb mesenchyme to oxidize nonreducing termini of the GAG chains did not inhibit or diminish immunoreactivity (Figure 1C), which is consistent with an internal carbohydrate epitope.



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Figure 1. d1C4 immunoreactivity of mesenchymal condensations in micromass cultures of Stage 22-23 limb mesenchyme is sensitive to chondroitinase AC. Indirect immunofluorescence staining with d1C4 (A-C) and corresponding phase contrast images (D-F). (A) Localization of d1C4 immunoreactivity associated predominantly with the ECM of mesenchymal condensations. (B) d1C4 immunoreactivity was sensitive to pretreatment of cultures with 0.2 U/ml chondroitinase AC. (C) Treatment of cell layers with 50 mM periodate was ineffective in inhibiting d1C4 immunoreactivity. Arrows in D and F indicate representative cellular aggregates detected with d1C4 in A and C, respectively. Cultures were fixed after 24 hr. Bar = 100 µm.

To assess the type of chondroitin sulfate recognized by d1C4, reactivity with chondroitin-4-sulfate (CS-A; sturgeon notochord) and chondroitin-6-sulfate (CS-C; shark cartilage) GAGs was tested by ELISA. The results indicated a preferential reactivity of d1C4 in a concentration-dependent manner with this CS-C GAG preparation and little or no reactivity with the CS-A GAG (Figure 2A). Little or no concentration-dependent reactivity of d1C4 was observed with CS-A GAGs from another tissue source as well (bovine trachea, Sigma and Calbiochem; data not shown). The preferential reactivity of d1C4 with CS-C GAG was corroborated with various ratios of CS-A:CS-C at a constant total concentration of GAG (Figure 2B). The presence of the d1C4 epitope in other GAGs was also tested by ELISA. Little or no reactivity of d1C4 was seen with chondroitin, heparan sulfate, keratan sulfate, or dermatan sulfate (Figure 2C). In addition, immunoreactivity of d1C4 with micromass cultures could be competed by preincubation of the antibody with excess CS-C GAG (Figure 3), whereas preincubation of antibody with the same concentration of CS-A GAG was ineffective. Taken together, these data suggest that the d1C4 epitope is preferentially found in GAGs enriched in CS-C type GAGs.



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Figure 2. d1C4 reacts preferentially with glycosaminoglycans (GAGs) enriched in chondroitin-6-sulfate by ELISA. (A) Plates were coated with increasing concentrations of chondroitin-4-sulfate (CS-A) and chondroitin-6-sulfate (CS-C) GAGs. (B) Plates were coated with a decreasing ratio of CS-A:CS-C at 20 µg/ml total concentration. Plates were incubated with 5 µg/ml d1C4 IgM or an irrelevant IgM in A and 5 µg/ml d1C4 in B. Note concentration-dependent reactivity of d1C4 with CS-C but not with CS-A. (C) Plates were coated with 60 µg/ml CS-C (*Seikagaku and {ddagger}Sigma), chondroitin (CH), heparan sulfate (HS), keratan sulfate (KS), or dermatan sulfate (DS) GAGs, then incubated with 5 µg/ml d1C4. Note reactivity of d1C4 with both CS-C preparations and lack of reactivity with other GAGs.



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Figure 3. d1C4 immunoreactivity of mesenchymal condensations in micromass cultures of Stage 22-23 limb mesenchyme is blocked by CS-C competition. (A) d1C4 (10 µg/ml) immunoreactivity in control cultures was associated predominantly with mesenchymal condensations. (B) Competition of d1C4 immunoreactivity by addition of excess chondroitin-6-sulfate (CS-C; 1 mg/ml) essentially blocked immunostaining. (C) Co-incubation of d1C4 with chondroitin-4-sulfate (CS-A; 1 mg/ml) did not inhibit immunostaining. Cultures were fixed after 24 hr. Bar = 100 µm.

High-density micromass culture of prechondrogenic chick limb mesenchyme duplicates processes that occur during chondrogenesis in vivo (Ahrens et al. 1977 ) and is a well-accepted culture bioassay for embryonic cartilage formation. As shown in Figure 4A, precartilage aggregates could be detected in limb micromass cultures with RhPNA lectin by 16 hr, as described previously (Aulthouse and Solursh 1987 ). However, Type II collagen was immunologically undetectable (Figure 4A, inset). Double labeling of cultures with RhPNA (Figure 4A) and d1C4 (Figure 4B) demonstrated a striking co-localization of CS-GAG epitopes with lectin binding molecules in regions of aggregated mesenchyme before overt chondrogenesis. Interestingly, faint d1C4 immunoreactivity could be observed by 8-12 hr of culture in undifferentiated mesenchyme of the micromass cell layers (data not shown). Localization of PNA-reactive molecules (Figure 4D) and the CS-GAG epitope recognized by d1C4 (Figure 4E) became more restricted to the incipient nodular structures by 48 hr. Immunoreactivity with d1C4 persisted in association with cell aggregates as they matured into cartilage nodules possessing an acidic Alcian blue-positive, chondroitin sulfate proteoglycan-rich ECM by 72 hr of culture (Figure 4G and Figure 4H). Micromass cultures treated with ß-D-xyloside over a 3-day period showed little or no d1C4 immunoreactivity, consistent with a GAG epitope (data not shown). Unlike d1C4 reactivity, RhPNA staining was not abolished by pretreatment of micromass cultures with either testicular hyaluronidase, as reported previously by Aulthouse and Solursh 1987 , or chondroitinase (unpublished observations). Preliminary experiments to either Western blot or immunoprecipitate extracts of micromass cultures with d1C4 were unsuccessful.



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Figure 4. PNA and d1C4 co-localize to prechondrogenic aggregates in micromass cultures of Stage 22-23 limb mesenchyme. RhPNA (A) and d1C4 (B) co-localized to prechondrogenic mesenchymal aggregates after 16 hr in culture. Inset of A illustrates the lack of immunoreactivity for Type II collagen at this time point. (C) Phase-contrast image of A and B. Arrow indicates one of the stained precartilage aggregates observed in A and B. (D-F) After 48 hr in culture, RhPNA (D) and d1C4 (E) co-localized to incipient cartilage nodules. (F) Phase-contrast image of D and E. Arrows show developing nodular structures stained in D and E. (G,H) By 72 hr of culture, cartilage nodules were apparent that stained with both d1C4 (G) and Alcian blue (H). Bars = 100 µm.

Immunolocalization of d1C4 epitopes in paraffin sections of developing chick limb buds paralleled the micromass data and revealed other interesting patterns of reactivity (Figure 5). At Stage 20, a low level of pericellular immunoreactivity with d1C4 was distributed widely in limb mesenchyme. Limb ectoderm, the ectodermal basement membrane, and the immediately subjacent mesenchyme were strongly immunoreactive (Figure 5A). As shown at higher magnification in Figure 5B, there was an abrupt loss of reactivity associated with the apical ectodermal ridge (AER) and subridge basement membrane of the Stage 20 limb bud. In contrast, PNA binding molecules were localized throughout the ridge, nonridge ectoderm, and associated basement membrane (Figure 5C). The staining pattern found in the body of the Stage 20 embryo showed d1C4 immunoreactivity in and around the neural tube and notochord, and also associated with basement membranes of the dorsal ectoderm, gut, and mesonephros (Figure 5A).



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Figure 5. d1C4 immunolocalization in chick limb development. A-E are transverse sections through the body axis. (A) In the Stage 20 embryo, faint d1C4 reactivity was observed in the ECM of limb mesenchyme, with more intense staining found in the ectodermal basement membrane and immediately subjacent mesenchyme. d1C4 reactivity was also observed in and around the neural tube (nt) and notochord (nc), and associated with other basement membranes, including that of the mesonephric duct (asterisk). (B) Higher magnification of the distal tip of a Stage 20 limb bud showed lack of immunostaining by d1C4 in the apical ectodermal ridge (AER; arrows) and subridge basement membrane. (C) Double labeling of the same section with RhPNA revealed continuity of staining in the AER (arrows) and subridge basement membrane. (D) In the Stage 22 limb bud, immunoreactivity was observed in the mesenchymal ECM of the proximal limb extending to the ventral sulcus (vs). (E) At Stage 23, d1C4 reactivity was found in the prechondrogenic mesenchyme of the limb core. Note staining also in mesenchyme surrounding the gut (g). (F) Cross-section of a Stage 28 limb showing d1C4 immunostaining associated with radial and ulnar cartilage, as well as a larger vessel of the limb (v). Bars = 100 µm.

By Stage 22, d1C4 immunoreactivity was prominent in the ECM of the proximal limb, associated primarily with mesenchyme extending from the proximal limb core to the ventral sulcus (Figure 5D). At Stage 23, increased immunopositive material localized to the prechondrogenic core of the developing limb (Figure 5E). It was also noted at these latter stages that the nonridge limb ectodermal basement membrane remained immunoreactive, whereas staining was absent in the basement membrane underlying the AER and the mesenchyme of the distal limb. At Stage 23, immunoreactivity extended into the mesenchyme surrounding the gut epithelium. By Stage 28, d1C4 reactivity was associated predominantly with nascent cartilage tissues (Figure 5F). Immunostaining was also seen surrounding larger blood vessels of the limb.

In addition to the limb, interesting patterns of d1C4 immunoreactivity were found elsewhere in extracellular matrices of the developing chick, including the posterior portion of the somites, surrounding the dorsal aorta, in the eye, and in lung mesenchyme (data not shown). A particularly striking distribution of d1C4 reactivity was found in the developing heart (Figure 6). As shown in Figure 6A, the d1C4 epitope was expressed primarily by mesenchyme within the atrioventricular canal (AV) in the Stage 19 heart. At higher magnification it was apparent that those mesenchyme closest to the AV myocardium were only weakly positive relative to regions nearer the endothelium (Figure 6B and Figure 6C). The AV endothelium was unreactive, as were the premigratory cardiac jelly and the AV myocardium (Figure 6B and Figure 6C). Staining was also observed along the subendothelial myocardium in the atrium and at scattered foci throughout the myocardium of the atrial/AV junction (Figure 6A).



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Figure 6. d1C4 recognizes cushion mesenchyme in the Stage 19 chick heart. Sagittal section through the heart of a Stage 19 chick embryo processed with Dent's fixative. Boxed area in A corresponds to the atrioventricular (AV) region, which is shown at higher magnification in B and C (phase-contrast image of B). Note that d1C4 appears to stain all but the leading mesenchyme (arrows in B and C) in the AV cushions. Staining was also closely associated with the subendothelial myocardium of the atrium (arrowheads in A). Little or no staining was observed in the endocardium (arrowheads in B and C) or myocardium (asterisk in B and C) or in the acellular matrix of the AV and ventricular regions. a, atrium; iav, inferior atrioventricular cushion; ot, outflow tract; sav, superior atrioventricular cushion; v, ventricle; arrow in A, sinoatrial junction. Bars = 50 µm.

By Stage 25, the entire inferior AV cushion ECM and all but the distal aspect of the superior AV cushion stained with d1C4 (Figure 7B and Figure 7C). The acellular matrix of the atrium adjacent to the AV cushions was also positive. In contrast, mesenchyme in the conal ridges of the outflow region differentially expressed the d1C4 epitope. Only those mesenchyme in the outflow tract near the myocardium were stained. Interestingly, the dense layer of myocardium (asterisks in Figure 7B and Figure 7C) in the outflow tract and AV region, as well as the epicardium (arrowheads), were unreactive, whereas the intervening mesenchyme and matrix were positive for d1C4. There was also an abrupt lack of immunoreactivity in the extracardiac mesenchyme of the dorsal mesocardium at the level of the spina vestibuli (Figure 8) that demarcates intra- from extracardiac mesenchyme.



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Figure 7. d1C4 staining co-distributes with a subset of mesenchyme cells in the outflow tract of the Stage 25 chick. Sagittal section through the heart of a cryopreserved Stage 25 chick embryo. Boxed area in A is shown enlarged in B and C. Note the lack of d1C4 reactivity in the region of the outflow tract cushions close to the endocardium (small arrows), yet there was an abundance of mesenchyme. A similar lack of reactivity was observed in the distal most aspect (open circle) of the superior AV cushion. The staining in both AV cushions extended into the acellular extracellular matrix near the atrium. The dense myocardium (asterisks) and epicardial epithelium (arrowheads) did not stain with d1C4. Abbreviations as in Figure 7. Bars = 50 µm.



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Figure 8. Intracardiac mesenchyme derived from the dorsal mesocardium acquires immunoreactivity with d1C4 in the Stage 22 chick. Cross-section through the atrium (at) of a Stage 22 chick embryo processed with Dent's fixative. (A) Indirect immunofluoresence staining with d1C4 and (B) corresponding phase-contrast image. The mesenchyme derived from the dorsal mesocardium (dm) did not stain positively for the d1C4 epitope until it had become incorporated into the heart. This abrupt boundary is denoted by arrowheads. Bar = 50 µm.


  Discussion
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

The use of unfixed, air-dried micromass cultures as an in vitro immunogen proved to be a successful method for obtaining MAbs to precartilage aggregate matrix components in their native state, without modification by solubilization or other typical methods of immunogen preparation. The procedure utilized was an adaptation of that described by Gilbert et al. 1990 for the production of MAbs to kidney collecting duct epithelia. Although in vitro immunization frequently results in the production of IgM antibodies, this technique offers several advantages over standard procedures for MAb production, including rapid production of hybridomas, use of small quantities of immunogen, and the ability to override tolerance for conserved immunogens (Reading 1982 ). The latter two advantages are of particular interest for embryological studies in which quantity or molecular conservation of the immunogen may be problematic for MAb production by traditional methods. However, at present relatively few developmental studies utilizing in vitro immunization have been reported (Gratecos et al. 1987 ; Milos et al. 1990 , Milos et al. 1993 ; Inai et al. 1993 ).

Successful production of hybridomas utilizing the in vitro immunization of mouse lymphocytes in the present study was dependent on several other factors. Micromass cultures fixed lightly with either ethanol or glutaraldehyde (Boss 1986 ), followed by extensive washing with PBS before the addition of splenocytes, were also utilized but resulted in fewer MAbs reactive with the ECM. The most critical variable was the use of thymocyte conditioned medium as reported previously (Luben and Mohler 1980 ; van Ness et al. 1984 ; Reading 1986 ). The stimulation of lymphocytes was also enhanced by the co-culture of peritoneal macrophages with the splenocyte preparation (Reading 1982 ) and the inclusion of MDP as adjuvant (Boss 1986 ). The production of relevant hybridomas was improved by providing splenocytes an opportunity to be challenged for a short period of time in a serum-free environment (van Ness et al. 1984 ). Omitting one or more of these steps resulted overall in the production of fewer hybridomas.

Several lines of evidence indicate that the epitope recognized by d1C4 resides on GAG chains enriched in chondroitin sulfate type C: (a) d1C4 immunohistochemical reactivity was sensitive to pretreatment with chondroitinase ABC, chondroitinase AC, and testicular hyaluronidase; (b) ELISA results showed a concentration-dependent reactivity with CS-C but not with CS-A GAG; and (c) immunohistochemical reactivity was abolished by preadsorption of d1C4 with CS-C but not with CS-A GAG. In addition, ELISA results showed little or no reactivity of d1C4 with chondroitin, heparan sulfate, keratan sulfate, or dermatan sulfate. The sensitivity of d1C4 reactivity towards preparations digested with chondroitinase AC suggests that it is not crossreactive with dermatan sulfate, nor is the d1C4 epitope a heparan sulfate or keratan sulfate, because these GAGs are not digested by chondroitinases ABC or AC (Yamagata et al. 1968 ).

Although the data to date are consistent with the d1C4 epitope being found on GAGs enriched in CS-C, the precise structure of the reactive carbohydrate moiety recognized by d1C4 has yet to be identified. However, mild periodate oxidation (Woodward et al. 1985 ) of high-density micromass cultures did not diminish reactivity with d1C4, suggesting that the epitope either is a terminal carbohydrate sequence resistant to periodate treatment or is a nonterminal component of the CS-GAG chain (Caterson et al. 1990 ). Individual GAG chains of a CS subtype may be composed predominantly of a single repetitive disaccharide unit, but may also exhibit heterogeneity with regard to length, GAG substitution, or sulfation pattern, resulting in structural differences within a particular CS species, all of which are potential targets for developmental or tissue-specific regulation (Seno et al. 1974 ; Caterson et al. 1990 ; Sorrell et al. 1990 ; Fernandez-Teran et al. 1993 ). Although the data in the present study indicate preferential reactivity of d1C4 with GAGs enriched in chondroitin-6-sulfate, it should be noted that the commercial CS-C preparations tested contain other CS derivatives, which may be from either CS-A or CS-C GAG chains. This raises the possibility that the CS-GAG epitope recognized by d1C4 could be a derivative of CS-A or CS-C that is not as highly represented in the CS-A preparations utilized. Further investigation will be required to determine whether the epitope recognized by d1C4 resides on the common CS-C unit (glucuronic acid-N-acetyl-D-galactosamine-6-sulfate), a more highly sulfated sequence, such as CS-D (Yamagata et al. 1987 ) or CS-E (Kongtawelert and Ghosh 1990 ), or potentially on some other atypical structural component of a CS-GAG chain. As noted by others (Avnur and Geiger 1984 ; Rouslahti 1988 ; Sorrell et al. 1990 ), it is often difficult to produce antibodies to ECM molecules such as GAGs because of their poor immunogenicity in traditional routes of administration, and recent reports have suggested that native CS epitopes may require oversulfation or other distinct structural motifs for antigenicity (Sorrell et al. 1993 ; Hascall et al. 1995 ).

Immunostaining of d1C4 in the developing limb is similar but not identical to that reported for other antibodies to CS-GAG epitopes. Using several MAbs, Fernandez-Teran et al. 1993 described differences in the distribution of a variety of CS-GAG epitopes during limb development. As shown with d1C4 in the present study, the MAb 3B3 (Couchman et al. 1984 ) recognizes a CS-C epitope in the prechondrogenic core and developing cartilage in the limb, although chondroitinase pretreatment of tissue sections was required for 3B3 reactivity. Interestingly, unlike d1C4, 3B3 does not stain the limb ectodermal basement membrane. MAb MO-225, which recognizes a native disulfated disaccharide sequence on the nonreducing end of CS-GAG chains (Yamagata et al. 1987 ), stains similarly to d1C4 in the prechondrogenic limb core and ectodermal basement membrane but, unlike d1C4, also stains the AER and subridge basement membrane. MAb CS-56 (Avnur and Geiger 1984 ), which recognizes a native epitope on both CS-A and CS-C residues, stains the ectodermal basement membrane in the developing limb but not the region subjacent to the AER (Critchlow and Hinchcliffe 1991 ), similar to that observed with d1C4. Together, these results suggest a heterogeneity in composition and/or accessibility of CS-GAGs in the basement membrane of the limb bud and, in particular, emphasize differences in the subridge basement membrane.

The CS-GAG epitope recognized by d1C4 is likely to be represented on several PGs. PGs are composed of GAG chains linked covalently to a core protein, exhibit a wide tissue distribution, and represent a major component of the ECM (Rouslahti 1988 ). The localization of several PG core proteins has been described in the prechondrogenic limb (Kimata et al. 1986 ; Shinomura et al. 1990 ; Solursh et al. 1990 ; Nishiyama et al. 1991 ; Gould et al. 1992 ), and a heterogeneous distribution of chondroitin sulfate/dermatan sulfate GAGs in the embryonic chick limb bud has been reported as well (Fernandez-Teran et al. 1993 ). Fernandez-Teran et al. 1993 have demonstrated dynamic spatial and temporal changes in the localization of chondroitin sulfate/dermatan sulfate epitopes during limb development that may reflect different functional roles for individual PGs. We have not attempted in the present study to identify the core proteins of chondroitin sulfate proteoglycans recognized by d1C4, but PG-M, which has been localized to the prechondrogenic core of the developing limb (Kimata et al. 1986 ; Shinomura et al. 1990 ), is a likely candidate in that location.

Of particular interest in the present study was the spatial and temporal localization of d1C4 reactivity in prechondrogenic aggregates of chick limb mesenchyme that enabled us to monitor the process of mesenchymal condensation in culture. In the limb, chondrogenesis is preceded by the aggregation of mesenchymal cells into cellular condensations (Fell 1925 ), which are of paramount importance in the establishment of limb primordia (Hall and Miyake 1992 ). Condensation of precartilage mesenchyme represents a requisite step during chondrogenesis and aggregates must achieve a threshold size before cell differentiation can proceed (Solursh et al. 1978 ; Hall and Miyake 1992 ). Prechondrogenic aggregate formation is a multifactorial process and several ECM molecules have been implicated, including Type I collagen (Dessau et al. 1980 ), fibronectin (Dessau et al. 1980 ; Downie and Newman 1995 ), PG-M (Kimata et al. 1986 ), and hyaluronate (Toole et al. 1972 ; Knudson and Toole 1987 ). Previously, RhPNA, which recognizes terminal galactose-N-acetylgalactosamine residues generally found on glycoproteins, has been demonstrated to demarcate reliably precartilage aggregates in cultured chick limb mesenchyme by 16 hr (Aulthouse and Solursh 1987 ). As reported in the present study, d1C4 reactivity overlapped with that of RhPNA in prechondrogenic condensations after 16 hr of culture and was detected throughout the differentiation of aggregates into cartilage nodules. However, a difference often observed in the staining pattern between RhPNA and d1C4 during the initial phases of culture was that PNA binding molecules appeared more restricted to the microenvironment of the aggregate, whereas d1C4 reactivity was observed consistently at earlier time points and extended into the peripheral mesenchyme, perhaps indicative of the recruitment of surrounding mesoderm into the aggregate (Ede 1983 ; Cottrill et al. 1987 ). Although PNA and d1C4 stain different carbohydrate structures, our data do not necessarily preclude their recognition of the same macromolecule.

Many of the ECM molecules expressed in precartilage aggregates of the developing limb are also expressed in the developing endocardial cushions, including Type I collagen (Johnson et al. 1974 ; Thompson et al. 1979 ), fibronectin (Icardo and Manasek 1984 ; Kitten et al. 1987 ), hyaluronate (Orkin and Toole 1978 ), and CS-GAGs (Markwald et al. 1978 , Markwald et al. 1979 ; Colvee and Hurle 1981 ). The atrioventricular (AV) and outflow tract (OT) endocardial cushions exist initially as an expansive acellular ECM derived in part from the adjacent myocardium (Markwald et al. 1978 ; Krug et al. 1985 ). This ECM is invaded by mesenchyme originating from a subpopulation of endocardial cells that have undergone an epithelial-mesenchymal transformation (Markwald et al. 1975 ) that is regionally specific for the AV and OT. Funderburg and Markwald 1986 showed biochemically that the ratio of CS-C to CS-A decreases in both the AV and OT during cushion tissue formation due to conditioning of the ECM with a mesenchyme-derived chondroitin sulfate proteoglycan (presumably CS-A-rich) that restricts the migration of trailing invasive cells. In the present study, expression of the CS-GAG epitope recognized by d1C4 was essentially absent in the premigratory matrix and increased markedly as AV mesenchyme was formed. Until recently, little has been done to examine the in situ expression pattern of individual CS-GAG chains. Using two MAbs that recognize subpopulations of CS-GAGs, Funderburg et al. 1991 showed regional differences in certain CS-GAGs within the endocardial cushions. CS-56 (Avnur and Geiger 1984 ), which recognizes an epitope on both CS-A and CS-C chains, stained the premigratory acellular ECM. However, an antibody (MO-225; Yamagata et al. 1987 ) that recognizes a disulfated CS-D epitope stained only those regions of the AV cushions that contained invasive mesenchyme. In the present study, the CS-GAG epitope recognized by d1C4 was expressed throughout the AV endocardial cushions of the Stage 25 chick embryo. However, mesenchyme within the OT stained differentially with d1C4, indicative of two phenotypically distinct mesenchymal populations. It is uncertain if these different populations of mesenchyme represent separate contributions of endothelially derived mesenchyme and neural crest cells to this region of the OT (Kirby et al. 1983 ; Miyagawa-Tomita et al. 1991 ; Noden 1991 ) or the localized differentiation of a subset of a previously homogeneous mesenchyme. Perhaps this polarization of staining could represent a "territorial boundary" for invasion of neural crest into this region, similar to that observed by Oakley et al. 1994 . Another interesting feature demonstrated by d1C4 immunostaining was the abrupt change in the expression of this CS-GAG epitope at the interface between the intracardiac and contiguous extracardiac mesenchyme of the dorsal mesocardium. This region of the heart is important because it serves as the entrance point for the spina vestibuli, an extracardiac mesenchymal structure at the venous pole of the developing heart that invades the heart to contribute to atrial septation (Asami and Koizumi 1995 ; Tasaka et al. 1996 ).

Functions attributed to PGs are numerous and range from organization of the ECM (Oldberg and Rouslahti 1982 ; Kleinman et al. 1986 ) to a role in the control of cell division (Grammatikakis et al. 1995 ) and the inhibition (Funderburg and Markwald 1986 ; Perris and Johansson 1987 ) or facilitation (Lane and Solursh 1991 ) of cell migration. The striking localization pattern of d1C4 at sites of critical morphogenetic events underscores the importance of future studies to identify the precise structure of its CS-GAG epitope. Such information will aid in identification of the enzymes responsible for its synthesis, which are likely to be tightly regulated during development. The fact that d1C4 immunoreactivity does not require enzymatic pretreatment may make this an ideal reagent for functional bioassays as well. Studies are under way to examine the functional role of the d1C4 antigen in limb and heart development.


  Footnotes

1 Present address: Pediatric Cardiology, Cook Children's Hospital, Fort Worth, TX.
2 We wish to dedicate this paper to the memory of Professor Michael Solursh, in whose laboratory this work was initiated and who died while this study was in progress.


  Acknowledgments

Supported by grants from the NIH to EK (HL52813), MS (HD05505), and GK (HL42266) and from the AHA to MW (94004580).

We thank Sue Tjepkema-Burrows and John Busey for photographic assistance, Dr Tom Trusk and Josh Spruill for help in preparing the figures, and Jan King, Sandra Kolker, Tanya Rittmann, and Alison Chilton for preparation of tissue sections. Thanks also to Dr Roger Markwald for insightful discussion and critical comments and to Dr Corey Mjaatvedt for suggesting poly-L-lysine treatment of microtiter plates.

Received for publication January 31, 1997; accepted May 28, 1997.


  Literature Cited
Top
Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

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