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Hemicentins Assemble on Diverse Epithelia in the Mouse

Xuehong Xu, Chun Dong and Bruce E. Vogel

Program in Cell Structure and Development, Medical Biotechnology Center, University of Maryland Biotechnology Institute, Baltimore, Maryland

Correspondence to: Bruce E. Vogel, Medical Biotechnology Center,725 W. Lombard St., Baltimore, MD 21201. E-mail: vogel{at}umbi.umd.edu

	Summary

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Hemicentins are recently described extracellular matrix (ECM) proteins with a single ortholog in C. elegans that assembles into discrete tracks constricting broad regions of epithelial cell contact into adhesive and flexible line-shaped junctions. There are two highly conserved hemicentin genes in most vertebrate species; however, nothing is known about the function or distribution of vertebrate hemicentins. To determine the distribution of vertebrate hemicentins, we used a polyclonal antibody to stain mouse tissue and showed that hemicentins are found in the pericellular ECM of epithelial cells in a number of tissues including embryonic trophectoderm and adult skin and tongue, in addition to the ECM of some, but not all, blood vessels. Hemicentins also assemble on multiple epithelia in the eye, including cornea, lens, and retina. The pericellular localization of vertebrate hemicentins on epithelia and other cell surfaces suggests that vertebrate hemicentins, like their nematode counterpart, are secreted ECM proteins likely to have a role in the architecture of adhesive and flexible cell junctions, particularly in tissues subject to significant amounts of mechanical stress. (J Histochem Cytochem 55:119–126, 2007)

Key Words: extracellular matrix • basement membrane • hemidesmosome • cell adhesion

	Introduction

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EXTRACELLULAR MATRIX (ECM) proteins form networks with distinct compositions and geometries, providing cells with regulatory and structural information to guide the morphogenesis and histogenesis of complex three-dimensional tissues. Hemicentins are a family of secreted ECM components first identified in C. elegans, with two orthologs in most vertebrate genomes including human and mouse (Vogel and Hedgecock 2001). Hemicentins are characterized by a single highly conserved von Willebrand A (VWA) domain at the amino terminus, followed by a long stretch (>40) of tandem immunoglobulin domains, multiple tandem epidermal growth factor repeats (EGFs), and a single fibulin-like C-terminal domain (Vogel and Hedgecock 2001; Whittaker and Hynes 2002; Argraves et al. 2003). In C. elegans, hemicentin is secreted from bodywall muscle and gonadal leader cells and assembles at multiple distant locations. At assembly sites, hemicentin forms an oriented track-like geometry whose apparent function is to constrict broad regions of cell contact into discrete line-shaped junctions. Hemicentin organizes hemidesmosome-mediated mechanosensory neuron and uterine attachments to the epidermis and can assemble into 7- to 9-µm-long flexible rods that insert between pairs of bodywall muscle cells and attach to the pharyngeal basement membrane. Hemicentin is also required for migration of the male somatic gonad leader cell, to stabilize plasma membranes of syncytial germ cells, and for the invasion of the anchor cell from uterine tissue through two basement membranes into vulval tissue, creating a pathway for fertilized eggs to move from the uterus to the exterior of the animal (Vogel and Hedgecock 2001; Sherwood et al. 2005).

Although a recent study has implicated human hemicentin-1 in age-related macular degenerative disease, there is nothing else known about the function or distribution of the two vertebrate hemicentins (Schultz et al. 2003). Here we present the first evidence that vertebrate hemicentins are found in the pericellular ECM of a number of epithelial cells including embryonic trophectoderm and the epidermis of skin and tongue, in addition to the ECM of some blood vessels. Hemicentin is also associated with multiple epithelia in the eye, including cornea, lens, and retina. The data suggest that vertebrate hemicentins, like their nematode counterpart, may have a role in the architecture of adhesive and flexible epithelial cell attachments, particularly in tissues subject to significant amounts of mechanical stress.

	Materials and Methods

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RT-PCR Detection of Hemicentin-1 and -2
RNA was extracted from adult tissue using Trizol reagent (Invitrogen; Carlsbad, CA), and cDNA was prepared from 3 µg of total RNA using SuperScript First-strand Synthesis System (Invitrogen) with random hexamer primers. For PCR, the primers used were hemicentin-1: 5'-ATGATTGCCCAGGAAGTG and 5'-CTAGACATGGGTGGGGAA; hemicentin-2: 5'-ATGACGCCTGGGGCGCAG and 5'-ATGAACTTTGGAGGCCTG. PCR products were sequenced to avoid misinterpretation due to spurious PCR products and quantitated using Image J software (NIH).

Expression and Detection of Mouse Hemicentin-1 and -2 Fusion Proteins
Fragments encoding the first 113 amino acids of hemicentin-1 and the first 230 amino acids of hemicentin-2 were amplified by RT-PCR using RNA prepared from adult mouse skin, cloned into bacterial expression vector pFLAG-MAC (Sigma; St Louis, MO), and transformed to E. coli NovaBlue competent cells (Novagen; San Diego, CA). The primers used were 5'-AGCTTATGATTGCCCAGGAAGTG, 5'-GATCTCTAGACATGGGTGGGGAA for hemicentin 1 and 5'-AGCTTATGACGCCTGGGGCGCAG, 5'-GATCCATGAACTTTGGAGGCCTG for hemicentin 2, respectively. The constructs were verified by DNA sequencing. Flag-tagged proteins were expressed by induction with 1 mM IPTG (isopropyl-ß-D-thiogalactopyranoside) according to manufacturer's instructions.

E. coli cell pellets were boiled in SDS-PAGE sample buffer, and extracted proteins were separated on a 16% Tris–glycine gel (Invitrogen) and transferred to nitrocellulose membrane. After blocking with 5% non-fat milk in TBST, fusion proteins were detected with rabbit anti-hemicentin antibody followed by goat anti-rabbit IgG conjugated with horseradish peroxidase (HRP) and developed using Supersignal West Pico Chemiluminescent Substrate (Pierce Biotechnology; Rockford, IL). After the membrane was stripped with 200 mM glycine–HCl (pH 2.0), the membrane was re-probed with anti-Flag–HRP antibody (Sigma).

Animal and Tissue Preparation
C57BL/6J mice (The Jackson Laboratory; Bar Harbor, ME) were bred under standard conditions and sacrificed by cervical dislocation. All tissues were harvested immediately and snap frozen with liquid nitrogen upon dissection. Appearance of the vaginal plug was designated embryonic day (E) 0.5, and embryos were either collected from E9.5–17.5, or pregnancies were allowed to reach term. Newborn mice were collected at postnatal (P) day 2 or 14. All animal procedures were conducted under guidelines approved by the University of Maryland Biotechnology Institute Animal Care and Use Committee.

Histological Analysis and Immunofluorescent Staining
After sample collection, tissues or embryos were frozen in optimal cutting temperature, sectioned (5–10 µm) by cryostat, and air dried for 40 min. The sections were fixed in 4% paraformaldehyde followed by acetone.

Endostatin/collagen XVIII monoclonal antibodies (kind gift from Drs. A. Marneros and B. Olsen) (Marneros et al. 2004), desmocollin-3 antibodies (kind gift of Dr. P. Koch) (Den et al. 2006), affinity-purified hemicentin antibodies, and monoclonal anti-cytokeratin 8.13 (Sigma) were used as primary antibodies to stain mouse tissue. Secondary antibodies were rhodamine-conjugated goat anti-rabbit IgG (Jackson Immuno-Research Laboratory; West Grove, PA) and FITC-conjugated goat anti-mouse IgG (Jackson ImmunoResearch Laboratory). Microscopic observation of immunofluorescence was performed with a confocal microscope (LSM 410; Carl Zeiss, Oberkochen, Germany).

	Results

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Characterization of Anti-hemicentin Antibody
The structural organization of C. elegans hemicentin from the N-terminal is a signal sequence followed by a VWA domain, 48-tandem immunoglobulin, three EGFs, and a fibulin-like C-terminal module. The VWA domain of C. elegans hemicentin is highly conserved in mouse hemicentins-1 and -2 with 95 and 87 amino acid identities with C. elegans hemicentin out of 158, respectively (Vogel and Hedgecock 2001; Whittaker and Hynes 2002) (Figure 1A ). A nematode hemicentin VWA domain::GST fusion protein was expressed in bacteria and used to immunize rabbits. Affinity-purified antibodies were characterized by Western blot and immunofluoresence on wild-type and hemicentin mutant animals (Dong et al. 2006). In Western blots, the affinity-purified antibody recognized a band of 600 kDa in wild-type, but not in hemicentin mutant animals (Dong et al. 2006).In immunofluoresence with C. elegans tissues, hemicentin was detected on mechanosensory neurons, tracks that connect the basement membrane of the pharynx to the basement membrane of bodywall muscle cells, and on germ cell plasma membranes in wild-type animals (not shown). These results are in complete agreement with the distribution of a functional GFP::hemicentin translational fusion that assembles on each of these tissues but not on neighboring muscle or epithelia (Vogel and Hedgecock 2001) and suggests that these antibodies can recognize native hemicentin protein found in these tissues with little background staining. The fact that this antibody recognizes a region of C. elegans hemicentin that is highly conserved in mouse hemicentin-1 and -2 (Figure 1A) suggests that this antibody might recognize these hemicentins in mouse tissues. To test this possibility, hemicentin-1 and -2 fusion proteins containing parts of the conserved VWA domain were expressed as Flag-tagged fusion proteins in bacteria. The antibody raised to the nematode hemicentin VWA domain recognized mouse hemicentin-1 and -2 fusion proteins but not an unrelated control fusion protein in Western blots of bacterial cell extracts (Figure 1B). In detergent and urea extracts of mouse skin, lung, tongue, eye, heart, and brain we were only able to detect low molecular mass (100–200 kDa) bands, even though these tissues have abundant hemicentin mRNA and antibody staining (see below). This suggests that the full-length proteins may be proteolyzed or modified in some other way that makes them difficult to detect in Western blots.

View larger version (44K): [in this window] [in a new window]   Figure 1 (A) Comparison of von Willebrand A domain sequences from C. elegans hemicentin and mouse hemicentins-1 and -2. Amino acids in mouse sequence that are identical to the C. elegans amino acids in the same position are shown in red. (B) Western blot of hemicentin-1 (Lane 1) and hemicentin-2 (Lane 2) and unrelated control protein (Lane C) detected with anti-hemicentin antibody (left) and re-probed with anti-Flag antibody (right). (C) Detection of hemicentin-1 (top) and hemicentin-2 transcripts (bottom) by RT-PCR of RNA from eye, skin, tongue, and lung tissue.

View larger version (66K): [in this window] [in a new window]   Figure 2 Anti-hemicentin antibody staining of mouse four- to six-cell embryo (A), morula (B), and blastocyst (C). (D–F) Blastocyst stained with anti-hemicentin (D,F) and anti-desmocollin-3 (E,F). Bars: A,B = 20 µm; C–F = 40 µm.

View larger version (122K): [in this window] [in a new window]   Figure 3 Anti-hemicentin (A,C,E,G–K,N–R) and H-E staining (B,D,F,L,M) of mouse skin at different development stages. (A,B) E14.5. (C,D) E17.5. Fluorescence is most intense at periphery of basal epithelial cells (arrowheads in C,D) and suprabasal keratinizing epithelial cells. (E,F,N,O) Hemicentin accumulates around epithelial cells of single and double hair follicles (arrowheads) and sebaceous glands (arrows in E,F), flattened basal epithelial cells (arrowheads in O) in P14 mouse as observed in transverse (E,F,N,O) sections. (G–I) Hemicentin around periphery of epithelial cells of sweat glands but not around myoepithelial cells (arrowheads in G). Higher magnification views of hemicentin staining at periphery of secretory epithelial cells with a space between two neighboring cells (arrowhead pairs in H,I). (J–M) Hemicentin at periphery of epithelial cells of whisker hair follicles in P2 mice, arrowheads indicate inner root sheath, arrows indicate outer root sheath. (Q) Staining of epidermal cells of P2 animal with hemicentin (red) and cytokeratin (green) antibodies. Control staining of epidermal cells of P2 animal using preimmune serum (R) and with hemicentin antibody preincubated with the immunizing fusion protein (25 µg/ml) to block fusion protein specific staining (P). Bars: A–G,J,L,P,R = 20 µm; H,I,K,M–O,Q = 10 µm.

In sweat glands, hemicentin is detected at the periphery of epithelial cells in the secretory portion of the sweat gland tubule, but no fluorescence is associated with surrounding myoepithelial cells (arrowheads in Figures 3G–3I). Higher magnification views of secretory epithelial cells show pericellular hemicentin staining with spaces between hemicentin on neighboring cells (arrowhead pairs in Figures 3H and 3I).

In addition to its distribution in the hair follicle in mouse skin, hemicentin staining is also detected in specialized whisker hair follicles (Figures J–3M). On day P2, fluorescence can be detected in both inner root sheath and outer root sheath. Higher magnification views showed that the signal is mainly in pericellular ECM around squamous inner sheath epithelial cells and cuboidal outer sheath epithelial cells (Figures 3K and 3M). There is no detectable fluorescence in the center of the hair shaft.

The tongue consists of striated muscle fibers arranged in bundles that run in three dimensions wrapped in a partially keratinized epithelium. On tongue upper and lower surfaces, staining is detected around the periphery of non-keratinized epithelial cells (Figures 4A and 4B). Epithelial cells located closer to the tongue outer surfaces become keratinized, and hemicentin on epithelial cell membranes goes from being discrete lines around the periphery of cells to a series of flattened layers (Figure 4D). Hemicentin also becomes a series of flattened layers as taste bud epithelial cells keratinize (Figure 4C). Weak hemicentin staining is also detected on the surface of sensory cells in the taste bud (Figure 4C). No detectable signals are observed in taste bud neurons (Figure 4C) or in lamina propria or striated transverse and longitudinal muscle fibers (Figures 4A, 4B, and 4E).

View larger version (75K): [in this window] [in a new window]   Figure 4 Hemicentin localization in mouse tongue epithelium. Hemicentin is detected around the periphery of non-keratinized epithelial cells on both the upper surface (A) and the underneath surface (B). (C) Keratinizing taste bud epithelium, arrow indicates taste pore. (D) Keratinized region of outer surface of tongue. Arrow indicates direction of epithelium keratinization. (E) No detectable signals either in lamina propria (indicated with bracket) or in striated transverse and longitudinal muscle fibers (SMF). (F) Higher magnification view of epithelial cells. Bars: A,B = 100 µm; C,D = 20 µm; E = 40 µm; F = 10 µm.

Hemicentin Distribution in the Eye
We were particularly interested in the distribution of hemicentins in the eye because human hemicentin-1 was recently implicated in age-related macular degenerative disease (Schultz et al. 2003). We compared hemicentin distribution in the eye to that of collagen XVIII, which is predominantly found in Bruch's membrane between choroid and RPE cells (Marneros et al. 2004). Hemicentin staining was detectable in the sclera and associated with the neuronal layers of the retina and Bruch's membrane (Figures 5A –5F). In Bruch's membrane, collagen XVIII is found in the central elastic layer (Marneros et al. 2004) (Figures 5H and 5I), whereas hemicentin forms a continuous, unbroken boundary distributed in the RPE and choroid basement membranes that flank the central elastic core of Bruch's membrane (Figures 5G, 5I, and 5J). In the sclera, both collagen XVIII and hemicentin are distributed in strips that run parallel to the surface of the sclera.

View larger version (120K): [in this window] [in a new window]   Figure 5 Immunofluorescence (A–C,E,G–I,K,M,O) and H-E staining (D,F,J,L,N,P) of eye from adult mouse. (A–J) Region flanking retina. (A,C,E,G,I) Hemicentin staining. (B,C,H,I) Collagen XVIII staining. Sc, sclera. Ch, choroid. RPE, retinal pigmented epithelium. INL, inner nuclear layer. ONL, outer nuclear layer. Hemicentin staining is detected in RPE and choroid basement membranes (G,I) that flank collagen XVIII staining in Bruch's membrane (H,I). Arrowheads in D indicate RPE and choroid. Arrowheads in G,J indicate Bruch's membrane. (K,L) Hemicentin is detected around the periphery of stratified corneal epithelial cells (SE). Also shown are Bowman's membrane (BM) and substantia propria (S). (M–P) Lens of adult mouse. Hemicentin is detected around the periphery of subcapular anterior epithelial cells (SAE) but not in lens capsule (Cs) and at the posterior of the lens, at the border (arrowheads) between lens fibers (LF) and lens capsule basement membrane (O,P). Bars: A–D = 100 µm; E–J = 10 µm; K–P = 20 µm.

In the lens, hemicentin staining was detected in the subcapular anterior epithelium around the periphery of lens epithelial cells but not observed in the lens capsule, a specific basement membrane enveloping the lens cell layer (Figures 5M and 5N). Lens fibers are elongated cells that extend across the entire lens from anterior epithelium, forming a major part of the lens body. At the posterior of the lens, hemicentin staining is detected along the length of the junction between lens fibers and the lens capsule basement membrane (Figures 5O and 5P).

Hemicentin Distribution in Blood Vessels
In a number of tissues, prominent hemicentin staining was observed in some, but not all, blood vessels. In the choroid of the adult eye, hemicentin was associated with the subendothelial ECM of arteriole vessels near the optic disk in addition to a number of smaller unidentified vessels (Figures 6A and 6B).

View larger version (83K): [in this window] [in a new window]   Figure 6 Hemicentin distribution in blood vessels. (A,B) Staining of arteriole vessel in the choroid layer of adult eye. (C–F) Staining of blood vessels (arrowheads) between neighboring alveoli of E17.5 embryo. Arrows indicate capillaries. (G,H) Staining of endothelial cells in blood vessels in uterus perimetrium of E9.5 pregnant mouse. Bars: A,B = 10 µm; C,D = 40 µm; E–H = 20 µm.

Approximately 9 days postcoitus, hemicentin was detected in blood vessels in the perimetrium, the outer serosal layer of the pregnant mouse uterus. Hemicentin staining was most prominent in the subendothelial ECM and the pericellular ECM of endothelial and smooth muscle cells, including what appears to be the surface of the vessel lumen (Figures 6G and 6H).

	Discussion

Top Summary Introduction Materials and Methods Results Discussion Literature Cited

 
Hemicentins are a family of secreted ECM proteins first identified in C. elegans with two orthologs in most vertebrate genomes including human and mouse (Vogel and Hedgecock 2001). In C. elegans, hemicentin is secreted by bodywall muscle and gonadal leader cells and assembles at multiple distant locations, where it forms an oriented track-like geometry whose function appears to be to constrict broad regions of cell contact into discrete line-shaped junctions. Hemicentin functions include organizing hemidesmosome-mediated attachments of mechanosensory neuron and uterine cells to the epidermis and stabilizing the plasma membranes of syncytial germ cells (Vogel and Hedgecock 2001).

Although nothing is known about the function or distribution of the two vertebrate hemicentins, a recent study has implicated human hemicentin-1 in age-related macular degenerative disease (Schultz et al. 2003). Using an antibody designed to recognize both nematode and vertebrate hemicentins, we present evidence that hemicentins are distributed in the pericellular ECM of mouse epithelial cells in the skin, tongue, and eye and also the subendothelial ECM and pericellular ECM in some, but not all, blood vessels.

In C. elegans, hemicentin is found in multiple regions where there is a requirement for adhesion and flexibility. Hemicentin distribution around the periphery of epithelial cells in skin and tongue suggests that hemicentins may have similar functions in vertebrates. Although epithelial cells in the eye are not subject to the same mechanical forces as those found in skin and tongue, retina, lens, and cornea are flexible tissues in the sense that they are able to accommodate modest shape changes without sustaining structural damage.

Prominent hemicentin staining is first detected in the trophectoderm, the first epithelium of developing vertebrates. Although hemicentin is located around the periphery of epithelial cells, it does not necessarily fill the ECM between cells. This is particularly noticeable as a distinct space between tracks of hemicentin staining on neighboring cells in multiple tissues, including tongue and sweat glands. Hemicentin is also absent from a number of ECMs including the ECM of Bowman's membrane, lens capsule, and dermis. The presence of hemicentin in the pericellular ECM of epithelial cells, but not in most ECMs, is consistent with hemicentin distribution in C. elegans where hemicentin is found in distinct locations at epithelial and other cellular junctions but is not found in most ECMs. This suggests that the function of hemicentins in the organization of specific epithelial cell junctions may be conserved in different organisms.

Fibulins are a family of five extracellular glycoproteins associated with basement membranes and elastic fibers in vertebrates (Argraves et al. 2003; Timpl et al. 2003). Defects in fibulin family members result in connective tissue disorders that include macular degenerative diseases and cutis laxa (Stone et al. 1999,2004; reviewed in Chu and Tsuda 2004). Fibulin-1 is a prominent component of skin, lung, and cardiovascular tissue and is essential for the morphology of endothelial cells lining capillary walls and the integrity of small blood vessels (Kostka et al. 2001). The recent demonstration that assembly of fibulin and hemicentin orthologs are codependent in C.elegans (Muriel et al. 2005) suggests that it may be interesting to determine whether hemicentin may coassemble with fibulin-1 and possibly other fibulin family members in vertebrate tissues.

	Acknowledgments

 
This work was supported by National Institutes of Health Grant GM-65184.

We thank Drs. Alexander Marneros and Bjorn Olsen for antibodies to Col XVIII and Dr. P. Koch for desmocollin-3 antibodies. We also thank Drs. Shengyun Fang, Gloria Hoffman, and Mon-Li Chu for helpful discussions.

	Footnotes

 
Received for publication March 17, 2006; accepted September 9, 2006

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This Article Abstract Full Text (PDF) All Versions of this Article: jhc.6A6975.2006v1 55/2/119    most recent Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Xu, X. Articles by Vogel, B. E. Search for Related Content PubMed PubMed Citation Articles by Xu, X. Articles by Vogel, B. E. Social Bookmarking                      What's this?

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