Keratinocyte-specific transglutaminase of cultured human epidermal cells: relation to cross-linked envelope formation and terminal differentiation

The predominant form of the cross-linking enzyme, transglutaminase, in cultured normal human epidermal keratinocytes, is found in cell particulate material and can be solubilized by nonionic detergent. It elutes as a single peak upon either anion-exchange or gel-filtration chromatography. Monoclonal antibodies raised to the particulate enzyme cross-react with one of two transglutaminases in the cell cytosol. The second cytosolic transglutaminase, which has distinct kinetic and physical properties from the first, does not cross-react and is not essential for formation of the keratinocyte cross-linked envelope in vitro. The anti-transglutaminase antibodies stain the more differentiated layers of epidermis in a pattern similar to that given by anti-involucrin antiserum. These observations support the hypothesis that the transglutaminase so identified is involved in cross-linked envelope formation in vivo.     

Participation of membrane-associated proteins in the formation of the cross-linked envelope of the keratinocyte

Cultured keratinocytes, like those in natural squamous epithelia, form submembranous protein envelopes cross-linked by cellular transglutaminase. During the cross-linking, the cytosolic protein involucrin becomes incorporated into the envelope and can no longer be extracted by detergents. We show here that when transglutaminase is activated in cultured keratinocytes, at least six other proteins also become nonextractable. In contrast to involucrin, these proteins are associated with membranes. Two of the proteins (210 and 195 kd) are differentiated products specific to the keratinocyte; like involucrin, they are absent from small keratinocytes and fibroblasts, but appear in larger keratinocytes during the course of their terminal differentiation. The other proteins that become nonextractable cannot be destined exclusively for envelope formation since they are also present in fibroblasts. Transglutaminase is used by the mature (large) keratinocyte to make a detergent-resistant envelope from what appears to be a mixture of differentiation-specific and nonspecific proteins, both membrane-bound and cytosolic.     

Annexin I and involucrin are cross-linked by particulate transglutaminase into the cornified cell envelope of squamous cell carcinoma Y1.

The squamous cell carcinoma line, SqCC/Y1, like natural squamous epithelia, forms a cornified cell envelope during differentiation which can be directly correlated with an increase in particulate transglutaminase activity. When transglutaminase is activated in these cells by calcium ionophore X-537A, annexin I and involucrin become incorporated into the cornified cell envelope and cannot be extracted with solutions containing sodium dodecyl sulfate (SDS) and beta-mercaptoethanol. This effect is specific for annexin I; thus, the amounts of annexins II and IV that were extractable from cells by SDS and beta-mercaptoethanol did not change following treatment with ionophore X-537A. Annexin I could be cross-linked in vitro to itself and to other endogenous proteins by transglutaminase extracted from the particulate fraction of SqCC/Y1 cells. Immunofluorescence studies showed that cross-linked annexin I and involucrin form an envelope-like structure in SqCC/Y1 cells during differentiation that cannot be extracted by EGTA and Triton X-100. The amount of staining of this envelope structure corresponded directly to the particulate transglutaminase activity of these cells. Annexin I monoclonal and polyclonal antibodies were shown to bind to purified cornified cell envelopes from SqCC/Y1. These studies suggest that particulate transglutaminase regulates a function of annexin I during the differentiation of SqCC/Y1 cells by covalently cross-linking this protein into the cornified cell envelope.     

Regulation by vitamin A of envelope cross-linking in cultured keratinocytes derived from different human epithelia.

When keratinocytes derived from different squamous epithelia are cultured in the absence of vitamin A, they form cross-linked envelopes during the last stage of terminal differentiation. Addition of the vitamin inhibits envelope formation, but the degree of inhibition is not the same for different keratinocyte subtypes. In the presence of low concentrations of retinyl acetate, conjunctival keratinocytes form virtually no cross-linked envelopes; esophageal and vaginal keratinocytes are less sensitive to the vitamin, and epidermal keratinocytes are the least sensitive. The suppression of cross-linked envelope formation is not associated with a proportional decrease in the concentration of involucrin, a precursor of the envelope, but occurs at the level of cross-linking itself, a process dependent on an increase in the intracellular concentration of calcium ions. Keratinocytes in which spontaneous envelope cross-linking has been prevented by retinyl acetate promptly form cross-linked envelopes if Ca2+ is introduced into the cytoplasm.     

Presence in human epidermal cells of a soluble protein precursor of the cross-linked envelope: activation of the cross-linking by calcium ions.

Late in the terminal differentiation of epidermis and cultured epidermal cells, a protein envelope located beneath the plasma membrane becomes cross-linked by cellular transglutaminase. The process of cross-linking can be initiated in cultured epidermal cells by agents affecting cell membrane permeability--nonionic detergents, high salt concentrations and ionophores. These agents initiate the cross-linking process by making calcium ions available to the transglutaminase. A soluble precursor of the cross-linked envelope has been identified in crude extracts of cultured epidermal cells by its ability to incorporate labeled amines through the action of transglutaminase. The protein has been purified to homogeneity by gel filtration and chromatography on columns of DEAE-cellulose and hydroxyapatite. Comprising an estimated 5--10% of the soluble cell proteins, it has a molecular weight of about 92,000, is isoelectric at pH 4.5 +/- 0.3 and has an unusual amino acid composition (46% Glx residues). It is chemically and immunochemically unrelated to keratins. The following evidence confirms that the protein becomes incorporated into cross-linked envelopes: first, washed cross-linked envelopes bind antibody to the purified protein, as shown by indirect immunofluorescence; second, absorption of the antiserum with washed envelopes removes all detectable antibodies to the purified protein; and third, the protein cannot be extracted from keratinocytes after their envelopes have become cross-linked. Examination of sections of epidermis by immunofluorescence, using antiserum to the purified protein, reveals that in addition to the stratum corneum, the living cells of the outer half of the spinous layer react strongly. The envelope precursor is present in the cytoplasm, but becomes concentrated at the cell periphery, where it will be cross-linked later, when the cells have passed through the granular layer. The protein is also concentrated in a peripheral location in cultured epidermal cells.     

Plasma membrane transglutaminase and cornified envelope competence in cultured human keratinocytes

When confluent cultures of the transformed human keratinocyte line SV-K14 are shifted to serum-free medium the cells achieve, within 4 days, the ability to synthesize a cornified envelope after challenge with the Ca2+ ionophore A23187. During these 4 days the enzyme transglutaminase (EC 2.3.2.13), which catalyses the cross-linking of different envelope precursor proteins, is partially transferred from the cytosolic pool into the plasma membrane. The association of the enzyme with the plasma membrane proves to be an essential step in the envelope formation since a direct correlation between plasma membrane-bound transglutaminase and envelope competence is observed. Retinoids block the insertion of the enzyme and therefore prevent envelope formation.     

Relation of protein synthesis and transglutaminase activity to formation of the cross-linked envelope during terminal differentiation of the cultured human epidermal keratinocyte

When serially cultivated human epidermal keratinocytes are placed in suspension culture they stop growing and form, beneath the plasma membrane, an insoluble envelope consisting of protein cross-linked by ε- (γ-glutamyl)lysine. The formation of envelopes in suspended cells is preceded by a sharp decline in the rate of protein synthesis, and most envelopes appear only after the average rate of protein synthesis has fallen to a very low level. If protein synthesis is reduced over 98 percent with cycloheximide or emetine at the time that surface-grown cells are placed in suspension culture, cross-linked envelopes form in most of the cells. This shows that the precursor of the envelope and the cross-linking enzyme are already in the cytoplasm in most cells of growing surface cultures. The process of envelope formation by suspension cultures is actually accelerated by the inhibitors of protein synthesis; an increased number of cells with cross-linked envelopes is observable within 4-6 h after the addition of cycloheximide. The inhibitor also induces a large fraction of the cells of surface cultures to form enveloped within a few days. These findings suggest that arrest of protein synthesis leads to activation of the cross-linking process. Agents known to inhibit transglutaminase-mediated protein cross-linking-putrescine, iodoacetamide, and ethylene glycol-bis(beta-aminoethyl ether)N,N,N',N'-tetraacetate (EGTA)- also prevent envelope formation. Though the activity of the cross-linking transglutaminase depends on the presence of cellular Ca++, we have not been able to activate the cross-linking process by high external Ca++ concentration or ionophores.     

Transglutaminase type 1 and its cross-linking activity are concentrated at adherens junctions in simple epithelial cells

Transglutaminase type 1 was identified as a tyrosine-phosphorylated protein from the isolated junctional fraction of the mouse liver. This enzyme was reported to be involved in the covalent cross-linking of proteins in keratinocytes, but its expression and activity in other cell types have not been examined. Northern blotting revealed that transglutaminase type 1 was expressed in large amounts in epithelial tissues (lung, liver, and kidney), which was also confirmed by immunoblotting with antibodies raised against mouse recombinant protein. Immunoblotting of the isolated junctional fraction revealed that transglutaminase type 1 was concentrated in the fraction not only as a 97-kDa form but also as forms of various molecular masses cross-linked to other proteins. In agreement with this finding, endogenous transglutaminase type 1 was immunofluorescently colocalized with E-cadherin in cultured simple epithelial cells. In the liver and kidney, immunoelectron microscopy revealed that transglutaminase type 1 was concentrated, albeit not exclusively, at cadherin-based adherens junctions. Furthermore, by in vitro and in vivo labeling, transglutaminase cross-linking activity was also shown to be concentrated at intercellular junctions of simple epithelial cells. These findings suggested that the formation of covalently cross-linked multimolecular complexes by transglutaminase type 1 is an important mechanism for maintenance of the structural integrity of simple epithelial cells, especially at cadherin-based adherens junctions.     

Calcium-induced intracellular cross-linking of lipocortin I by tissue transglutaminase in A431 cells. Augmentation by membrane phospholipids.

Covalently cross-linked multimers of lipocortin I are shown to be present in human epidermoid carcinoma A431 cells treated with epidermal growth factor or the calcium ionophore A23187. This intracellular cross-linking of lipocortin I is suggested to be mediated by the action of tissue transglutaminase, a Ca2(+)-dependent protein cross-linking enzyme. Cross-linking of lipocortin I competes with proteolytic digestion of the protein, and pretreatment of the cells with inhibitors for calpain (Ca2(+)-dependent intracellular protease) markedly enhanced the cross-linking of lipocortin I. Cross-linked lipocortin I is shown to be present in the soluble fraction of A431 cells as well as in the particulate fraction; a 34-kDa fragment of lipocortin I was solubilized successfully by plasmin digestion of the latter fraction. Immunofluorescence microscopy using specific antilipocortin-I antibody showed that cross-linked lipocortin I forms an envelope-like structure, which is not extracted with [ethylenebis(oxyethylenenitrilo)]tetraacetic acid (EGTA) or Triton X-100. In vitro incubation of purified lipocortin I with tissue transglutaminase resulted in the formation of covalently cross-linked lipocortin I dimer, tetramer, and so on. Amine incorporation and cross-linking studies using lipocortin I and its N-terminal truncated derivatives indicated that the cross-linking site is localized within the plasmin-susceptible N-terminal 29 amino acids of lipocortin I. The cross-linking of lipocortin I is shown to be accelerated more than 10 times by the addition of phosphatidylserine vesicles, on which lipocortin I molecules are most likely aligned in a conformation suitable for cross-linking. Collectively, these findings suggest that an increase of intracellular calcium concentration results in the attachment of lipocortin I onto the plasma membrane phospholipids through the C-terminal domain of the molecule where the membrane-bound lipocortin I is cross-linked by the action of tissue transglutaminase through the N-terminal domain.     

Epoxyeicosatrienoic acids activate transglutaminases in situ and induce cornification of epidermal keratinocytes

The cytochrome P450 CYP2B19 is a keratinocyte-specific arachidonic acid epoxygenase expressed in the granular cell layer of mouse epidermis. In cultured keratinocytes, CYP2B19 mRNAs are up-regulated coordinately with those of profilaggrin, another granular cell-specific marker. We investigated effects of the CYP2B19 metabolites 11,12- and 14,15-epoxyeicosatrienoic acids (EETs) on keratinocyte transglutaminase activities and cornified cell envelope formation. Keratinocytes were differentiated in vitro in the presence of biotinylated cadaverine. Transglutaminases cross-linked this substrate into endogenous proteins in situ; an enzyme-linked immunosorbent assay was used to quantify the biotinylated proteins. Exogenously added or endogenously formed 14,15-EET increased transglutaminase cross-linking activities in cultured human and mouse epidermal keratinocytes in a modified in situ assay. Transglutaminase activities increased approximately 8-fold (p < or = 0.02 versus mock control) in human keratinocytes transduced with adenovirus particles expressing a 14S,15R-EET epoxygenase (P450 BM3v). The physiological transglutaminase substrate involucrin was preferentially biotinylated in situ, determined by immunoblotting and mass spectrometry. P450 BM3v-induced transglutaminase activation was associated with increased 14,15-EET formation (p = 0.002) and spontaneous cell cornification (p < or = 0.001). Preferential involucrin biotinylation and the increased cornified cell envelope formation provided evidence that transglutaminases mediated the P450 BM3v-induced cross-linking activities. These results support a physiological role for 14,15-EET epoxygenases in regulating epidermal cornification, and they have important implications for epidermal barrier functions in vivo.     

A new class of soluble basic protein precursors of the cornified envelope of mammalian epidermis

The cornified envelope hs been shown to be formed beneath the plasma membrane as a result of the cross-linking of soluble and membrane-associated precursor proteins by transglutaminase. We have obtained a monoclonal antibody which reacts with the periphery of cells in the upper layers of human epidermis by indirect immunofluorescence (IIF) following immunization of mice with cornified envelopes of cultured human keratinocytes. The antibody also stained the cell peripheries of bovine, rat and mouse epidermis as well as stratified epithelium. Neutral buffer extracts of human cultured keratinocytes and epidermis examined under denaturing conditions contained polypeptides of molecular weight 14 900 and 16 800 which reacted with the antibody, and an additional component of molecular weight 24 800 was found in cultured cells. The polypeptides were shown to have a pI of about 9.0. Under non-denaturing conditions the two lower-molecular-weight polypeptides had an apparent molecular weight of 30 000, while the 24 800 protein had one of 60 000. Incubation of the polypeptides under conditions that activate transglutaminase resulted in a disappearance of the polypeptides or the formation of cross-linked products. Basic polypeptides with somewhat different pI values and molecular weights were identified in neutral buffer extracts of bovine and rat epidermis. The HCE-2 antibody appears to identify a new class of basic protein precursors of mammalian cornified envelope.     

Cellular transglutaminase. The particulate-associated transglutaminase from chondrosarcoma and liver: partial purification and characterization

A transglutaminase from the malignant chondrocytes, rat swarm chondrosarcoma cells, was partially purified and characterized in an effort to understand transformation-induced changes in its activity. This enzyme separated by DE52 column chromatography after extraction from the particulate fraction of cell lysate was found to be distinct from previously characterized transglutaminases in its electrophoretic mobility, molecular size, substrate specificity, and immunologic reactivity. This enzyme was identified as a transglutaminase by its catalysis of amine (putrescine, spermine) incorporation at the carboxamide group of protein-bound gamma-glutamyl residues, and accordance of its kinetic data with the modified double displacement mechanism described for other transglutaminases. Limited proteolysis of the isolated enzyme resulted in a 3-4-fold increase of catalytic activity and a concomitant reduction of molecular size by approximately one-half. Incubation of labeled amine with chondrosarcoma cell lysate resulted in labeling of only a few proteins that appeared to be extensively cross-linked and that were located mostly in the particulate fraction of the cells. Transglutaminase extracted from the rat liver particulate fraction displayed enzymatic and structural properties closely resembling those of the enzyme from chondrosarcoma cells.     

Retinoic acid-induced transglutaminase in mouse epidermal cells is distinct from epidermal transglutaminase

Elevated transglutaminase activity and formation of cornified envelopes are markers of terminal differentiation in mouse epidermal cells. Epidermal transglutaminase catalyzes cornified envelope formation and in cultured cells is inducible by calcium ion or phorbol ester tumor promoters. Retinoic acid also induces transglutaminase activity but inhibits cross-linked envelope formation. This apparent paradox might be resolved by the observation that the retinoic acid-induced transglutaminase appears to be either a different enzyme or a markedly altered form of the epidermal enzyme. The retinoic acid-induced transglutaminase is soluble in aqueous buffers, is thermolabile at pH 9.0, 37 degrees C, and elutes from an anion exchange column at 0.4 M NaCl. In contrast, the epidermal enzyme is particulate and requires detergent for solubilization, is relatively thermostable, and elutes from the anion exchanger at 0.25 M NaCl. The retinoic acid-induced enzyme is probably identical with the "tissue" transglutaminase present in liver and in other cells. It is proposed that the transglutaminase induced by retinoic acid may play a role in the inhibition by retinoids of calcium and tumor promoter-induced differentiation.     

Characterization of transglutaminase activity in rabbit tracheal epithelial cells. Regulation by retinoids

Rabbit tracheal epithelial cells undergo terminal cell division, start to express a squamous phenotype, and form cross-linked envelopes when reaching the plateau phase of the growth curve. This terminal differentiation is accompanied by a 20-30-fold increase in the activity of the cross-linking enzyme transglutaminase. This activity is found almost solely in the particulate fraction of homogenized cells and can be solubilized by nonionic detergents. This transglutaminase crossreacts with a monoclonal antibody raised against type I transglutaminase, but does not react with an antiserum against type II transglutaminase. The tracheal transglutaminase contains a protein subunit of approximately 92 kDa. The omission of epidermal growth factor from the medium or the addition of fetal bovine serum, conditions that induce terminal cell division and expression of a squamous phenotype, enhance transglutaminase activity. High calcium concentrations only stimulate transglutaminase activity after the cells become committed to terminal cell division. Retinoids, which inhibit the expression of the squamous phenotype but not terminal cell division, inhibit the enhancement in transglutaminase activity induced by either confluency or serum, indicating that this enzyme activity is under the control of retinoids. Some retinoids are active at concentrations as low as 10(-12) M. The ability of retinoids to inhibit transglutaminase activity correlates well with their capacity to bind to the retinoic acid-binding protein. Our results show that the increase in transglutaminase activity correlates with the induction of the terminal differentiated phenotype and suggest that this enzyme can function as a marker for this program of differentiation of rabbit tracheal epithelial cells in culture. Our results identify the transglutaminase as type I transglutaminase and are in agreement with the concept that this transglutaminase is involved in the formation of cross-linked envelopes.     

Transglutaminase cross-linking properties of the small proline-rich 1 family of cornified cell envelope proteins. Integration with loricrin

Small proline-rich 1 (SPR1) proteins are important for barrier function in stratified squamous epithelia. To explore their properties, we expressed in bacteria a recombinant human SPR1 protein and isolated native SPR1 proteins from cultured mouse keratinocytes. By circular dichroism, they possess no alpha or beta structure but have some organized structure associated with their central peptide repeat domain. The transglutaminase (TGase) 1 and 3 enzymes use the SPR1 proteins as complete substrates in vitro but in different ways: head domain A sequences at the amino terminus were used preferentially for cross-linking by TGase 3, whereas those in head domain B sequences were used for cross-linking by TGase 1. The TGase 2 enzyme cross-linked SPR1 proteins poorly. Together with our data base of 141 examples of in vivo cross-links between SPRs and loricrin, this means that both TGase 1 and 3 are required for cross-linking SPR1 proteins in epithelia in vivo. Double in vitro cross-linking experiments suggest that oligomerization of SPR1 into large polymers can occur only by further TGase 1 cross-linking of an initial TGase 3 reaction. Accordingly, we propose that TGase 3 first cross-links loricrin and SPRs together to form small interchain oligomers, which are then permanently affixed to the developing CE by further cross-linking by the TGase 1 enzyme. This is consistent with the known consequences of diminished barrier function in TGase 1 deficiency models.     

Retinoic acid induces transglutaminase activity but inhibits cornification of cultured epidermal cells

In cultured mouse epidermal basal cells, retinoic acid is a potent inducer of transglutaminase, the enzyme responsible for isodipeptide bond formation in protein cross-linking in the production of the cornified membrane during terminal differentiation. Paradoxically retinoic acid also inhibits the formation of the cross-linked envelope and greatly reduces the level of dipeptide bond formation in epidermal cells induced to differentiate by calcium. These results suggest a novel mechanism by which retinoids can modify transglutaminase activity and epidermal differentiation.     

Isopeptide bond formation in epidermis

Summary Proteins which are major substrates of epidermal transglutaminases can be identified in cultured keratinocytes of human, cow, and new-born rat.Cow and human keratinocytes both contain substrate proteins which are 30000 to 50000 daltons in size but dissociable in SDS to 12000 daltons or less. In both species these proteins correspond to in vivo synthesized proteins which are probable precursors of cornified envelope. Human keratinocytes synthesize a 125000 dalton protein which is also a precursor of cornified envelope both in cells and tissue. By SDS electrophoresis two 100000 dalton substrate proteins are seen in cow keratinocyte extracts and a 23000 dalton substrate protein is seen in rat keratinocyte extracts. Minor substrates of transglutaminase are seen in human keratinocytes, and one has been isolated by preparative electrophoresis. Major structural proteins of epidermis which are in vitro substrates of epidermal transglutaminase include the keratins and the stratum corneum basic protein.     

Involucrin acts as a transglutaminase substrate at multiple sites

Involucrin is a keratinocyte protein with a specialized function in terminal differentiation. Synthesized initially as a soluble protein, it later becomes a preferred substrate for a membrane-bound transglutaminase and becomes cross-linked into an insoluble envelope. When a crude keratinocyte extract containing about 2% involucrin is heated to 95 degrees, most proteins precipitate, but all of the involucrin remains in solution, where it is over 90% pure. This step has been incorporated into a simplified procedure for purification of the protein. Like intact involucrin, polypeptide fragments formed by the tryptic hydrolysis of involucrin are good substrates for the keratinocyte transglutaminase. Evidently amino acid residues participating in the enzyme-catalyzed cross-linking are distributed at numerous sites along the involucrin molecule.     

Characterization of sciellin, a precursor to the cornified envelope of human keratinocytes

The cornified envelope, located beneath the plasma membrane of terminally differentiated keratinocytes, is formed as protein precursors are cross-linked by a membrane associated transglutaminase. This report characterizes a new precursor to the cornified envelope. A monoclonal antibody derived from mice immunized with cornified envelopes of human cultured keratinocytes stained the periphery of more differentiated cells in epidermis and other stratified squamous epithelia including hair and nails. The epitope was widely conserved among mammals as determined by immunohistochemical and Western analysis. Immunoelectron microscopy localized the epitope to the cell periphery in the upper stratum spinosum and granulosum of epidermis. In the hair follicle, the epitope was present in the internal root sheath and in the infundibulum, the innermost aspect of the external root sheath. The antibody recognized a protein of relative mobility (M(r)) 82,000, pI 7.8. The protein was a transglutaminase substrate as shown by a dansylcadaverine incorporation assay. Purified cornified envelopes absorbed the reactivity of the antibody to the partially purified protein and cleavage of envelopes by cyanogen bromide resulted in release of immunoreactive fragments. The protein was soluble only in denaturing buffers such as 8 M urea or 2% sodium dodecyl-sulfate (SDS). Partial solubility could be achieved in 50 mM TRIS pH 8.3 plus 0.3 M NaCl (high salt buffer); the presence of a reducing agent did not affect solubility. Extraction of cultured keratinocytes in 8 M urea and subsequent dialysis against 50 mM TRIS pH 8.3 buffer resulted in precipitation of the protein with the keratin filaments. Dialysis against high salt buffer prevented precipitation of the protein. The unique solubility properties of this protein suggest that it aggregates with itself and/or with keratin filaments. The possible role of the protein in cornified envelope assembly is discussed. We have named this protein Sciellin (from the old english "sciell" for shell).     

Calcium regulation of growth and differentiation of normal human keratinocytes: modulation of differentiation competence by stages of growth and extracellular calcium

In this study we examined the different aspects of the pathway leading to the differentiation of keratinocytes as a function of time in culture and calcium concentration of the culture medium. Human neonatal foreskin keratinocytes were grown in a serum-free, defined medium containing 0.07, 1.2, or 2.4 mM calcium and assayed for the rate of growth and protein synthesis, involucrin content, transglutaminase activity, and cornified envelope formation at preconfluent, confluent, and postconfluent stages of growth. We observed that keratinocytes grown to postconfluence in all calcium concentrations showed an increased protein/DNA ratio and an increased rate of membrane-associated protein synthesis. Extracellular calcium concentrations did not have a clear influence on these parameters. However, preconfluent and confluent keratinocytes grown in 0.07 mM calcium showed markedly retarded differentiation at all steps, i.e., involucrin synthesis, transglutaminase activity, and cornified envelope formation. Within 1 week after achieving confluence, these keratinocytes began synthesizing involucrin and transglutaminase and developed the ability to form cornified envelopes. Cells grown in 1.2 and 2.4 mM calcium synthesized involucrin and transglutaminase prior to confluence and were fully competent to form cornified envelopes by confluence. Thus external calcium-regulated keratinocyte differentiation is not an all or none phenomenon, but rather it is the rate at which keratinocytes differentiate that is controlled by calcium. We conclude that either or both higher extracellular calcium concentration and the achievement of cell-cell contacts lead to a coordinate increase of at least two precursors--involucrin content and transglutaminase activity--required for cornified envelope formation. We speculate that a critical level of cytosolic calcium, achieved by increased extracellular calcium or by achievement of intercellular communication established by cell-cell contact, may trigger mechanisms required for initiation of keratinocyte differentiation.