(Received for publication, June 28, 1996, and in revised form, August 27, 1996)
From the Laboratory of Skin Biology, NIAMS, National Institutes of Health, Bethesda, Maryland 20892-2752
Involucrin was the first protein to be identified
as a likely constituent of the insoluble cornified cell envelope (CE)
of stratified squamous epithelia. However, to date, direct isolation from CEs of involucrin cross-linked by way of the
transglutaminase-induced isopeptide bond has not been reported. We have
treated human foreskin CEs with methanol/KOH (saponification) to
hydrolyze off much of the lipids. By immunogold electron microscopy,
this exposed large amounts of involucrin epitopes as well as of
desmoplakin, a desmosomal structural protein. About 20% of the total
CE protein could be solubilized by proteolytic digestion after
saponification, of which involucrin was the most abundant. Subsequent
amino acid sequencing revealed many peptides involving involucrin
cross-linked either to itself or to a variety of other known CE protein
components, including cystatin , desmoplakin, elafin, keratins,
members of the small proline-rich superfamily, loricrin, and unknown
proteins related to the desmoplakin family. Specific glutamines or
lysines of involucrin were used to cross-link the different proteins, such as glutamines 495 and 496 to desmoplakin, glutamine 288 to keratins, and lysines 468, 485, and 508 and glutamines 465 and 489 for
interchain involucrin cross-links. Many identical peptides were
obtained from immature CEs isolated from the inner living cell layers
of foreskin epidermis. The multiple cross-linked partners of involucrin
provide experimental confirmation that involucrin is an important early
scaffold protein in the CE. Further, these data suggest that there is
significant redundancy in the structural organization of the CE.
The cornified cell envelope (CE)1 is a specialized structure formed during terminal differentiation of stratified squamous epithelia and serves as a vital barrier for the tissue. Foreskin epidermal CEs, for example, consist of an ~15-nm-thick layer of insoluble protein (about 90% of CE mass) on the intracellular or cytoplasmic surface, overlaid by ~5 nm of lipid envelope (10% of mass) located on the extracellular or outer surface (1-6). A similar CE structure of about 5 nm is formed in hair cuticle cells (7, 8). Most other internal "wet" epithelia commonly assemble a 5-10-nm protein but not a lipid component of a CE (3).
The insolubility of the protein portion of the CE is due to extensive
cross-linking of several constituent proteins by both disulfide bonds
and the N-(
-glutamyl)lysine
isopeptide cross-link introduced by the action of transglutaminases
(1-5). Analysis of the protein composition of the CE has been hampered
by the simple fact that the cross-link cannot be cleaved by reagents
that do not also cleave peptide bonds. Nevertheless, many studies using
biochemical and immunological techniques have identified several
protein components of CEs of epidermal or other epithelia, including
cystatin
(9, 10), formerly named keratolinin (11), elafin (12-15),
involucrin (4, 16-21, 23, 24), loricrin (25-30), members of the small
proline-rich superfamily (Spr) (Spr1 and Spr2 in epidermis, and Spr3 in
cultured keratinocytes) (9, 31-36), filaggrin (37, 38), keratin
intermediate filaments (39-42), and possibly trichohyalin (41).
Indeed, recent amino acid sequencing of peptides has demonstrated for
the first time that the proteins elafin, filaggrin, keratin
intermediate filaments, loricrin, and Sprs are in fact isopeptide
cross-linked components of human foreskin epidermal CEs (26,
42).
However, detailed information on the relative abundances, temporal orders of deposition, or the assembly mechanisms of these proteins onto the CE structure is incomplete. Nevertheless, two points are becoming more clear. First, the CEs of different epithelia are not the same. For example, loricrin seems to be unique to the CE of "dry" or orthokeratinizing epithelia such as the epidermis (as well as the forestomach of rodents) (25-29). Spr amounts in CEs vary widely in epithelia, from very abundant in the periderm layer of the fetus (36) to absent in CEs of the relatively thin interfollicular postnatal epidermis (35, 36), yet very abundant in the thickened epidermis of the lip, footpad, and foreskin, and other epithelia such as vagina, penis, and hair follicle cells, which are subject to considerable mechanical stresses (35). Therefore the composition of the constituent proteins and thus the structure of the CE seems to vary in parallel with the function of different epithelia (36, 42, 43). Second, a variety of data in toto suggest that involucrin may be a ubiquitous component of the CEs of most if not all epithelial tissues (reviewed in Refs. 3, 4, and 21). One hypothesis suggests that it may serve as an early or scaffold component of CE structures (3, 4, 20, 21, 44) onto which other proteins such as Sprs (36), loricrin (3, 28, 38, 42, 44), or sulfur-rich proteins (8, 45, 46) are later added to effect final stabilization. Interestingly, involucrin also has been shown to be a component of the primitive CE entity formed in liver apoptotic bodies (47).
We have utilized CEs isolated from human foreskin epidermis as a model system to study these structural and functional issues. Our recent work using limited proteolysis and sequencing of the released peptides has provided information on not only which proteins are cross-linked, but also which glutamines and lysines are used for cross-linking by the transglutaminases in vivo (42). The strategy was successful because, as suggested by immunogold decoration studies (44), the enzyme proteinase K could penetrate the cytoplasmic face but not the lipid face of this CE. We showed that the outer one-third of this CE structure consists almost entirely (>90%) of loricrin (i.e. intra- and interchain cross-linked loricrin molecules) and was admixed with smaller amounts of Spr1 and Spr2 which seem to function as cross-bridging molecules among the loricrin. A middle third of the CE structure was also ~85% loricrin, admixed with Sprs, and the elastase inhibitor elafin. Trace amounts of keratins and filaggrin were also cross-linked. However, a similar analysis of the innermost protein portion of this CE, which was enriched in involucrin and which is perhaps common to the CEs of many other types of stratified squamous epithelia, was not possible. Thus, no data exist yet as to how involucrin is cross-linked with other proteins and to the loricrin-rich phase in the epidermal CE or in any other CE structure.
In this study, we have developed methods to circumvent these technical problems. We have characterized peptides from two sources: (i) mature stratum corneum CEs from which much of the covalently attached lipids have been removed by alkaline hydrolysis (saponification) and (ii) less mature CEs from the inner living cell layers of the epidermis. Our new data identify the many proteins to which involucrin is cross-linked in vivo and confirm that it is indeed a major early cross-linked component of the CE.
The epidermis of human foreskins was extracted in a buffer of 8 M urea, 50 mM Tris-HCl (pH 7.6), 1 mM EDTA. In the absence of a reducing reagent, only the inner living cell layers are dissociated (48, 49). This extract was then filtered through nylon gauze (mesh, 0.1 mm). The retentate of stratum corneum sheets and a filtrate of living cell material were separately pelleted, washed in phosphate-buffered saline, and then used to prepare mature and immature CEs, respectively, by exhaustive boiling in SDS buffer (38, 42, 44). The resultant CE fragments were pelleted through 20% Ficoll in phosphate-buffered saline to remove most adherent (i.e. not cross-linked) solubilized keratins (38, 44). Mature CEs were extracted in 1 M KOH, 95% methanol at 45° for 1 h (saponification). This reaction hydrolyzes the ester linkages by which the ceramide-rich lipid envelope is attached to the protein envelope (6, 50, 51).
Protein Chemistry ProceduresAmino acid analysis of hydrolyzed samples (5.7 N HCl at 110° for 22 h in vacuo) was used routinely to measure protein amounts. The isodipeptide cross-link was measured by amino acid analyses of complete enzymatic digestions of CE samples (26, 42). To generate peptides suitable for microsequencing, aliquots of CEs (1-3 mg of CE protein) before or after saponification were resuspended in 0.1 M N-ethylmorpholine acetate, pH 8.3. They were digested at 37 °C with either trypsin (Sigma; sequencing grade, 1% by weight) for 1-6 h or with proteinase K (Life Technologies, Inc.; 3% by weight) for up to 36 h (42, 44). The solubilized peptide material was collected by pelleting the CE remnants at 14,000 × g and dried.
Peptides were fractionated by HPLC and characterized as described
before (42). Initial experiments showed empirically that cross-linked
peptides were 20-50 residues long and eluted >50 min from the HPLC
column, whereas peptides derived from non-cross-linked portions of
constituent CE proteins generally were 15 residues long and eluted
<40 min. In the case of peptides from saponified CEs, since the
initial tryptic peptides were >50 residues long and poorly resolved,
they were subjected to a second digestion with proteinase K (0.5% by
weight for 30 min) before fractionation. Selected peptides were
sequenced as before (42).
Several affinity-purified
antibodies were used to decorate isolated CE fragments: (i) a
polyclonal antibody generated in rabbits using as immunogen a synthetic
peptide of the sequence PVCSPGGIQEVTINQSLLQPLNVEIDPEIQKVKSRE corresponding to the H1 region of the human keratin 1 chain (52, 53)
(Western blotting methods on epidermal extracts demonstrated specificity for the epidermal type II keratins 1, 2e, and 5 (and 6 in
cultured cells) (data not shown)); (ii) a rabbit polyclonal anti-human
keratin 10 antibody (53); (iii) a goat polyclonal anti-human loricrin
SAF-3 antibody (26); (iv) a mouse monoclonal anti-human involucrin
antibody (Biomedical Technologies Inc., Stoughton, MA); (v) a rabbit
polyclonal anti-human desmoplakin antibody (gift of Dr. R. D. Goldman);
(vi) a polyclonal rabbit anti-rat plectin antibody
(Sigma); (vii) a mouse monoclonal anti-human integrin
3 (ATCC, Rockville, MD); and (viii) a rabbit anti-human BPAG1
antibody (gift of Dr. J.C.R. Jones). Pellets of CEs were subjected to
pre-embedding, labeled as described (25, 44, 54) and using protein
A-gold with a diameter of either 5 or 10 nm.
Our earlier attempt to resolve the structure of the foreskin epidermal stratum corneum ("mature") CE by controlled proteolysis was complicated by the presence on one side of the lipid envelope, which precluded direct access by proteases to the inner layers, and by the dense layer of cross-linked loricrin on the cytoplasmic side (42). Therefore, in this study, we have utilized mature CEs in which the ceramide-rich lipid envelope layer has been removed by alkaline hydrolysis (saponification) or CEs that contain much less loricrin and that have not yet assembled the lipid envelope (from "immature" epidermal cells).
Saponification of Mature CEs Reveals Buried Epitopes for Involucrin and DesmoplakinWe probed mature foreskin epidermal CEs for the
presence of epitopes of several proteins that are known to be present,
including involucrin and loricrin (42, 44) (Fig. 1,
B and D, first part). The linear
distributions of gold particles over >50 µm of CE fragments were
summed to obtain more quantitative information (Table
I). The distributions were reproducible between multiple
experiments with each antibody, but there was wide variation between
antibodies probably due to differences in epitope accessibility or
abundance. Of three available keratin 1 antibodies, only the new one
elicited against the H1 subdomain labeled fragments reliably (Fig.
1C). We also tested for other keratinocyte cell peripheral
antigens including 3 integrin (a marker for cell junctions in
terminally differentiating keratinocytes (55)) and desmoplakin (56) (a marker of desmosomal junctions) as well as two markers for
hemidesmosomal junctions, plectin (57) and BPAG1 (58). All of these
were negative (Fig. 1A for desmoplakin).
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Following digestion with trypsin, epitopes for involucrin and K1 were lost, but epitopes for loricrin were retained (Fig. 1A, second part), as described previously (44).
Next, mature CEs were treated with methanol/KOH (saponification),
washed, and probed for the several epitopes. As a control, we found
that there was little change in the amount or distribution of loricrin
labeling between intact and saponified CEs (Fig. 1D, compare
first and third parts; Table I); i.e.
saponification had not altered the accessibility of loricrin epitopes
on the cytoplasmic side. However, epitopes for desmoplakin, involucrin, and keratin 1 (but none of the other cell peripheral antigens tested)
became exposed in substantial amounts (Fig. 1, A-C,
third part; Table I). By use of double labeling experiments,
we found that desmoplakin (Fig. 2A) and
involucrin (Fig. 2B) labeling occurred on the side opposite
to that of loricrin (Table I). This means that epitopes for desmoplakin
and involucrin had become exposed after saponification. Similarly,
epitopes of keratin 1 became exposed on both sides after saponification
(Table I). Based on previous immunogold decoration studies, most of the
keratin labeling on the cytoplasmic side was due to contaminating
protein (44); thus, keratin 1 epitopes also became exposed on the
delipidized inner surface.
Trypsin digestion after saponification removed ~25% of the total CE protein and resulted in loss of most epitopes, except only for those of loricrin, which became exposed on both sides (Fig. 1D, fourth part; Table I). Mathematical modeling (38, 44) of the amino acid compositions of the solubilized tryptic peptides showed marked enrichment for involucrin, whereas the 75% protein in the insoluble remnant was estimated to be >90% loricrin.
Together, these data suggest that the lipid layer of mature CEs had masked epitopes for certain inner CE protein components, which on exposure could be easily removed, leaving a remnant consisting almost entirely of polyloricrin.
CEs from Immature Foreskin EpidermisImmature CEs obtained from the inner living layers of foreskin epidermis constituted about 1% of the protein mass of the epidermis, which is about one-tenth of that for mature CEs. By light microscopy, they consisted of mixtures, from "fragile" translucent to more rigid structures as reported previously (3) (data not shown). They are expected to contain only traces of lipids (3, 51). These mixed CEs were estimated to contained about 30% loricrin. Preliminary immunogold analyses revealed similar distributions of gold particles for the same antigens shown in Fig. 1 (data not shown). In contrast to the mature CEs, however, digestion with trypsin solubilized ~85% of the total protein. The undigested remnant was estimated to be highly enriched for loricrin.
Characterization of Tryptic Peptides From CEsThe tryptic
peptides from mature CEs were recovered for sequencing analysis in the
following way. First, the CEs were digested to completion with trypsin
to remove ~5% of contaminating adherent non-cross-linked protein,
mostly consisting of keratins and filaggrin (42, 44). This fraction
contained <0.5% of the total CE cross-link. The remnant was subjected
to saponification and then redigested to completion with trypsin, which
solubilized 19.5% of total CE protein mass, which contained 12.7 of 89 nmol of cross-link/mg of total CE protein. Following a brief digestion
with proteinase K, the peptides were fractionated by HPLC (Fig.
3). In this way, 187 peptides ~15-50 residues long
were recovered and sequenced, of which 157 contained one or more
cross-link, so that they contained two or more "peptide branches."
In almost all cases, the structures of the peptides were solved in the
sense that (i) in the two or more branches, the exact identity of the
protein and the location within the protein was identified and (ii) we
could unambiguously assign which glutamine(s) and lysine(s) were linked
by the isopeptide cross-link. Table II illustrates
examples of how sequence information was assigned. Together, the
recovered and sequenced peptides included 402 peptide branches and
accounted for 89% of the total amount of cross-link in the
unfractionated tryptic peptide preparation (Table III);
the remaining cross-link was present as short unresolvable peptides
that eluted very early on the HPLC column (Fig. 3).
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The solubilized tryptic peptides from the immature CEs were resolved (data not shown) and characterized similarly. In this case, the peptides contained 26.7 nmol of cross-link/mg of CE protein, of which 21.1 nmol (79%) could be accounted for in 131 peptides having 380 peptide branches. However, in three four-branched peptides, there was no unique solution as to which glutamine was cross-linked to which lysine (data not shown).
Analysis of Complete List of SequencesTable III lists the yields and proteins of origin of the peptide branches from both sources of CEs, as well as the data for proteinase K digestion of mature CEs obtained previously (42). More than 83% (molar basis) of the sequences exactly matched known or suspected CE structural proteins (26, 42), of which by far the most abundant were involucrin (256 sequences; 36 or 14% molar basis) and loricrin (169 new sequences, total of 458). Interestingly, the third most abundant were a group of three closely related peptides (total of 93 times, 17 or 9% molar basis) of unknown identity, but they are homologous to human desmoplakin (59), BPAG1 (60), and plectin (61) (Table IV). The new cross-linked peptides involving loricrin discovered here were found to use the same glutamines and lysines of loricrin as seen before, so that the molar usage of these residues remained unchanged (42). All of the cross-links involving Spr1 and Spr2 proteins and elafin used amino- or carboxyl-terminal sequences as seen before, confirming the idea that these proteins serve as cross-bridges between CE proteins, usually loricrin (42). A fourth major group of sequences involved the type II keratins 1, 2e and 5, which will be described in detail elsewhere. Table V lists the frequency of cross-linking between various protein partner pairs.
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Sequences involving
involucrin were the second most abundant (Table VI).
Most notably, it was evident that of a total of 150 glutamines and 45 lysines in involucrin (62), only a limited selection of them was used
for cross-linking to specific proteins. In all 27 occurrences, the
"unknown" protein was cross-linked only by way of involucrin lysine
485. In all 18 occurrences, involucrin glutamine 495 or 496 was used
only to cross-link to desmoplakin. The type II keratin chains 1, 2e, or
5 usually used involucrin glutamine 288. In other cases, there was
somewhat less sequence specificity. Involucrin-involucrin cross-links
involved glutamines 465 and 489 and lysines 468, 485, or 508; loricrin
was cross-linked by way of several glutamines (308, 309, 368, 369, 425, 426, 455, or 456); and in involucrin-cystatin and involucrin-elafin
cross-links, as many as six glutamines each were used, although the
exact residues were uncertain because of peptide repeats in involucrin.
All of these residue positions are located in the center of involucrin, encompassing its modern sequences (62, 63).
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Likewise, there was considerable conservation in the glutamine or
lysine residues used for cross-linking within the other proteins,
including elafin, cystatin , and the keratins. In the case of
desmoplakin, only two lysines in the entire sequence were used, located
on its carboxyl tail at the end the C domain (59). Similarly, only two
glutamines were used in homologous sequences of the unknown
protein.
Thus, involucrin participated in many interchain cross-links with multiple different partner proteins (Table V). In some multibranched peptides, involucrin was cross-linked by intermediary proteins such as desmoplakin, loricrin, and the unknown protein (Table VI, peptides 11, 12, and 15). In these cases, they seemed to serve as interchain cross-bridging proteins between involucrin and/or between themselves. Moreover, in ~60% (molar total) of peptides, involucrin was cross-linked to itself (Tables V and VI). Because of the close juxtaposition of the participating glutamines (often 465) and lysines (often 468) within involucrin (see especially peptides 16, 18, and 19), it seems possible that these are interchain cross-links, since steric effects are likely to preclude cross-linking by transglutaminase enzyme(s) of neighboring residues (64).
Historically, involucrin was the first protein to be identified as a constituent of the CE formed in epithelial cells (16). Many studies have since characterized in detail its expression, in vitro transglutaminase cross-linking, biochemical properties, and structural properties (reviewed in Refs. 3, 4, and 21). The data from all of these studies are consistent with the view that involucrin is a covalently attached "early" component of the CE. One extant hypothesis holds that it may serve as a scaffold for the later attachment of other CE structural proteins (3, 4, 20, 21, 44, 65).
Two recent studies have shown unequivocally that the same involucrin-immunoreactive fragments can be released from CEs of foreskin epidermis and cultured keratinocytes by use of CNBr methods (21, 66), indicating that involucrin is covalently attached to the CEs. A 68-kDa fragment was released, which indicates that it had been covalently linked by way of the amino-terminal half of the intact protein (66). However, to date, sequences of involucrin joined together by way of the isopeptide cross-link to itself or another protein have not been isolated and characterized, as has been the case for several other "later" CE proteins (26, 42). The present study reports the identification and characterization of a large number of peptides containing one or more cross-links that adjoin involucrin to itself and/or to other proteins. These data, together with our immunogold work, provide important information on the likely multiple roles of involucrin in the CE. Our data are predicated on the operational definition of the CE as that which is insoluble after exhaustive extraction with powerful protein solvents that break disulfide bonds but not peptide bonds; i.e. the CEs used in these studies are an insoluble protein complex cross-linked by isopeptide bonds (38, 42-44). However, it is also possible that involucrin and other structural proteins and enzymes are associated with or even covalently attached to the CE but do not become cross-linked by transglutaminases. In this case, they may be lost by our method of isolation of CEs and thus not recognized in this study.
Cross-linked Involucrin Is Indeed a Major Component of CEs Formed in VivoIn our previous studies on mature foreskin CEs, we were
unable to find cross-linked peptides involving involucrin (42), in part
because the exhaustive proteolysis procedures from the cytoplasmic side
rendered the peptides too small for sequencing, although they were
predicted to be enriched involucrin, and in part because the lipid
envelope seemed to have precluded proteolytic access to the inner
surface of the CE structure. However, we show here that following
alkaline hydrolysis to remove lipids from the mature CEs formed
in vivo, epitopes for several proteins become exposed,
including involucrin, keratin 1, and desmoplakin. After saponification,
trypsin could release about 20% of the protein mass of the CE.
Sequencing of these peptides revealed prominent amounts of interchain
cross-linked species involving these proteins, of which involucrin was
in fact the most abundant (40%; Table III). Many peptides involved
interchain cross-links between involucrin and itself, or cystatin ,
elafin, the type II keratins 1, 2e, and 5, desmoplakin, or a novel
protein of unknown identity.
In addition, peptides released from the immature CEs formed in vivo, in which lipid envelope assembly was presumed to have been incomplete (3, 51) and which contained less loricrin, also contained abundant amounts of interchain cross-linked involucrin (~17%; Table III). Many of these cross-linked peptides involved the same protein and amino acid residue partners as found in the mature CEs (Table VI).
Therefore, these data establish that involucrin is indeed a major component of the CE and is cross-linked to itself and to several other proteins.
What Is the Unknown Protein?The nature of the three highly homologous variants of the unknown peptides found in cross-links of these CEs remains uncertain due to the absence of more sequence information. Nevertheless, by searches in protein sequence data bases, they share part of a sequence motif with the terminus of the cytoplasmic domain of members of the desmoplakin family of proteins that are associated at the point at which intermediate filaments meet desmosomes or hemidesmosomes (67). The sequence variants may be polymorphisms of a novel single protein, or they may represent individual members of a new family of desmoplakin-like proteins. One candidate is IFAP-300, previously identified as an important protein at the point where keratin intermediate filaments meet desmoplakin (68, 69), but other proteins cannot be excluded at this time (18, 58, 70-72).
Involucrin Is a Quantitatively Major Early CE Protein ComponentSeveral types of data have suggested previously that involucrin is an early CE protein component (3, 4, 21). Our new data confirm this concept. First, the saponification procedure allowed proteolytic release of about 20% of the CE protein that was especially enriched in involucrin, but contained only a minor proportion of the amounts of the known late CE proteins elafin, Sprs, and loricrin (Table III). In addition, we found that involucrin was located predominantly on the side opposite to that of loricrin (Fig. 2B, Table I). This is consistent with the idea that it had been accumulated onto the CE prior to loricrin.
Second, based on the yields of proteins released by proteolysis with
different enzymes both before (late proteins) and after (early
proteins) saponification (Table III), we can make estimates more
accurately than heretofore possible of their total amounts in intact
mature CEs (Fig. 4). As foreshadowed in earlier
predictive analyses (3, 4, 21, 38, 44), these data illustrate quantitatively the inverse relationship between the amounts of early
proteins involucrin and cystatin (and the newly encountered desmoplakin and unknown proteins), and the late proteins elafin, Sprs,
and loricrin. The cross-link data from immature CEs, presumably obtained for CEs of an early degree of maturation, seem to afford an
intermediary stage in this progression. These analyses provide the best
evidence to date for the likelihood of an orderly temporal accumulation
of proteins as the CE is assembled (3, 44). We calculate that mature
foreskin epidermal CEs contain about 5.5% involucrin and 2-3% each
of desmoplakin and the unknown proteins but more than 70% loricrin.
This value for involucrin is about twice that estimated by mathematical
modeling (38, 44) but is within the range of accuracy of the method.
Furthermore, since the CE itself is 10% of the mass of cornified
keratinocyte, of which 90% is protein (3, 4), this means that
0.4-0.5% of the protein mass of the epidermis is involucrin
cross-linked in the CE. Since involucrin constitutes about 1% of total
epidermal keratinocyte cell protein (20, 73), this suggests that only part of it in fact becomes tightly cross-linked to the CE. This raises
the intriguing possibility that a considerable amount of involucrin is
associated with the CE in other ways: e.g. (i) is covalently
attached by some other methods (including disulfide bonds, polyamines,
or lipids); (ii) is partially cross-linked through glutamine and lysine
residues other than those reported here (66); (iii) remains soluble; or
(iv) may be utilized for some other purpose in the keratinocyte.
Third, we are intrigued by the abundance of cross-links between involucrin and carboxyl-terminal sequences of desmoplakin. Desmoplakin is a major structural protein of desmosomes. While part is perhaps anchored at the cell junction, a central rod domain projects into the cytoplasm, and a series of peptide repeating domains at the carboxyl-terminal end are believed to interact directly or indirectly with cytoskeletal intermediate filaments (56, 59). Our pre-embedded electron microscopy images show that in isolated CEs the desmosomes have lost their structural integrity, but desmosomal remnants could be recognized by the fact that desmoplakin antigens were exposed and located in thickened zones along the CE fragments (Fig. 1A, third part). The isolation of cross-links involving desmoplakin carboxyl-terminal sequences indicates that at least this portion had become attached to the CE by the action of transglutaminases. Perhaps more substantial portions of desmoplakin also form part of the CE, since epitopes thought to be located within its rod domain were recognized by the polyclonal antibody (Fig. 1A, third part). Moreover, we found remarkable specificity in cross-linking, since only two glutamines (residues 495 and 496) of involucrin were used to cross-link to only three lysines of desmoplakin (residues 1659, 1661, and 1667) (Table VI). Notably, in vitro cross-linking experiments with the model amine donor putrescine have documented previously that glutamines 495 and 496 are the most highly reactive residues in involucrin (19). An earlier study reported immunogold localization of two monoclonal antibodies to desmosomal remnants in cornifying epidermal cells (74), which may be related to desmoplakin or the unknown proteins described here. Therefore, further experiments now will be required to test the interesting possibility that the cross-linking of involucrin onto desmosomal proteins may be a very early step in CE assembly.
The Multiple Scaffold Roles of InvolucrinPrevious structural
analyses have suggested that involucrin may function as a scaffold
during the assembly of the CE (4, 21). The data of Tables V and VI
provide robust support for this concept. First, involucrin was most
commonly interchain cross-linked to itself by way of neighboring
lysines and glutamines (Table VI, peptides 10, 14, 16, 18, and 19).
Second, >20% of involucrin cross-links involved other early CE
components such as desmoplakin, cystatin , and the unknown protein
(peptides 1, 2, 4, 11-14, and 17). However, another 15% of involucrin
cross-links involved the late CE proteins elafin, loricrin, and Sprs
(peptides 3, 5-9, and 15). Taken together, these observations indicate
that an intermolecularly cross-linked polymeric layer involucrin not
only seems to form an early part of the CE but also serves as a
platform for the addition of the late CE proteins.
We show here that the removal of much of the lipids (possibly mostly ester-linked ceramides) exposes the involucrin-rich inner portion of the CE. This supports the prediction that involucrin may serve as a scaffold for the covalent attachment of CE lipids (6, 75).
Redundancy of Cross-linking between ProteinsThe summary data of Table V provide information on the frequency of cross-links between the several CE proteins. Mostly, involucrin (>60%) and loricrin (>50%) were cross-linked to themselves. However, some proteins had preferred cross-linked partners such as desmoplakin with involucrin or the unknown protein; the unknown protein with involucrin or keratins; and Sprs with loricrin, etc. More significantly, while most proteins had multiple cross-linked partners, involucrin and loricrin were the most versatile, having eight each. In part, this could be explained in terms of the multiple scaffold roles of involucrin. An alternative or concurrent possibility is that there is considerable redundancy in the assembly of proteins into the CE structure, both during its early stages and then later in the final reinforcement stages of its assembly. This conclusion may offer an explanation of why the substantial overexpression of involucrin in transgenic mice leads to a negative phenotype in the epidermis, internal epithelia, and hair follicle (23); a too dense layer of cross-linked involucrin may interfere with redundant cross-linking. In contrast, loricrin overexpression appears to have no ill effect (28). Conversely, it could be predicted that diminished levels of involucrin may not cause a seriously negative phenotype.
ConclusionMathematical modeling has suggested that CEs from
cultured keratinocytes contain significantly more of the early proteins involucrin and cystatin (38) and perhaps, in view of the present data, desmoplakin as well. Moreover, such CEs can be decorated with
involucrin antibodies (21, 22, 76). Thus, cultured keratinocytes may
provide a valuable system with which to explore further the earliest
stages of CE assembly. Mutational analyses of the specific glutamine or
lysine residues used for cross-linking of involucrin or desmoplakin
discovered here could be explored in culture systems.
We thank Drs. Vincenzo De Laurenzi, Peter Elias, Tonja Kartasova, and Edit Tarcsa for stimulating discussions.
Subsequent to submission of this manuscript an article was published describing the novel cell envelope protein envoplakin (Ruhrberg, C., Haijibagheri, M. A. N., Simon, M., Dooley, T. P., and Watt, F. M. (1996) J. Cell Biol. 134, 715-729). The sequence of the second "unknown" protein variant described in Table IV of our paper is identical to human envoplakin. The other unknown variants described in our paper may be polymorphisms of envoplakin or may represent additional members of this new class of cell envelope proteins.