An immunocytochemical study of keratin reactivity during rat odontogenesis

Summary The cytokeratin distribution in the developing rat enamel organ from day 15 of gestation through to 11 days post partum was examined immunohistochemically using a panel of monoclonal antibodies. A temporo-spatial programme of keratin expression was observed during odontogenesis and positive reactivity of the enamel organ was seen with the pan keratin antibodies CK1 (clone LP34 — reacts with a number of keratins including 6 and 18) and AE1-3 (reacts with most acidic and basic keratins). No reactivity was observed in the enamel organ with the other antibodies examined (Ks 8.12 [reacts with keratins 13 and 16], Ks 8.60 [reacts with keratins 10 and 11) and MCA157 [reacts with rat liver antigen]), although these antibodies did stain other epithelial tissues. This study supports the view that the epithelial cells of the enamel organ synthesize a tissuspecific subset of keratins which are related to the differentiation of the cells.     

Distribution profiles of keratin proteins during rat amelogenesis

We examined rat cells undergoing amelogenesis for the presence of three types of keratin proteins using a polyclonal antibody to keratin (against total keratins (TK) with molecular masses ranging from 41 to 65 kilodaltons (kd) and monoclonal antibodies keratins to KL1 and PKK1 (reactive with keratins with molecular masses of 55-57 and 41-56 kd, respectively). In normal oral epithelia from young rats, the TK, KL1, and PKK1 antibodies bound to all of the epithelial strata. The epithelial cap on the top of incisors and the dental lamina of molar teeth exhibited strong TK staining, moderate staining KL1, and little or no PKK1 staining. In developing molar enamel organs, both the outer and inner enamel epithelia, the stratum intermedium, and stellate reticulum cells were all positively stained by the TK immunoreagent. In developing incisors, TK only bound strongly to stratum-intermedium cells, and no KL1 and PKK1 staining antibodies was observed in ameloblasts or the stratum intermedium.     

Distribution profiles of keratin proteins during rat amelogenesis

Summary We examined rat cells undergoing amelogenesis for the presence of three types of keratin proteins using a polyclonal antibody to keratin (against total keratins (TK) with molecular masses ranging from 41 to 65 kilodaltons (kd) and monoclonal antibodies keratins to KL1 and PKK1 (reactive with keratins with molecular masses of 55–57 and 41–56 kd, respectively). In normal oral epithelia from young rats, the TK, KL1, and PKK1 antibodies bound to all of the epithelial strata. The epithelial cap on the top of incisors and the dental lamina of molar teeth exhibited strong TK staining, moderate staining KL1, and little or no PKK1 staining. In developing molar enamel organs, both the outer and inner enamel epithelia, the stratum intermedium, and stellate reticulum cells were all positively stained by the TK immunoreagent. In developing incisors, TK only bound strongly to stratum-intermedium cells, and no KL1 and PKK1 staining antibodies was observed in ameloblasts or the stratum intermedium.     

The human thymic microenvironment: Thymic epithelium contains specific keratins associated with early and late stages of epidermal keratinocyte maturation

Normal T-cell development is dependent on interactions with the thymic microenvironment; thymic epithelial cells are thought to play a key role in the induction of thymocyte maturation, both through direct contact and, indirectly, via thymic hormone secretion. It has been postulated that thymic epithelial cells progress through an antigenically defined pathway of differentiation similar to that of epidermal keratinocytes. As keratins vary according to epithelial cell type and the stage of epithelial cell maturation, we used a panel of monoclonal antibodies against keratins to study specific types of keratin intermediate filaments within human thymic epithelium. The demonstration in human thymus of keratins previously shown to be associated with distinct stages of epidermal keratinocytic maturation would support the hypothesis that thymic epithelial cells undergo sequential stages of differentiation. Two-dimensional immunoblot analysis of cytoskeletal extracts from human thymus revealed that thymic epithelium contains the following keratins: 1-2, 5, 6, 7, 8, 10, 13, 14, 15, 16, and 17 (molecular masses, 65-67, 58, 56, 54, 52, 56.5, 51, 50, 50', 48, and 46 kilodaltons, respectively). Thus, in thymic epithelium, we found keratins previously observed in epidermal basal cells (5, 14, 15), as well as keratins specific for terminally differentiated keratinocytes in supra-basal epidermis (1-2, 10). Indirect immunofluorescence (IF) performed on fetal and postnatal human thymus demonstrated that keratin epitopes recognized by antibodies AE-3, 35 beta H11, and RTE-23 are present on epithelial cells of the subcapsular cortex, the cortex, the medulla, and Hassall's bodies. In contrast, antibodies AE-1 and RTE-22 reacted primarily with neuroendocrine thymic epithelium (subcapsular cortex, medulla, Hassall's bodies). The epithelial reactivity of antibody AE-2 was limited to epithelial cells in Hassall's bodies and did not appear until 16 weeks of fetal gestation i.e., when Hassall's bodies first formed. Two-dimensional gel analysis of thymic keratins demonstrated that antibody AE-2 identified only the keratins with molecular masses of 56.6 and 65-67 kilodaltons (10 and 1-2 respectively) in thymus. These data, together with the selective reactivity of AE-2 with Hassall's bodies in fluorescence assays, demonstrate the localization in Hassall's bodies of the high-molecular-weight keratins associated with the late stages of epidermal cell maturation. In summary, we demonstrated that human thymic epithelium contains specific keratins found in multiple epithelial types as well as keratins associated with both early and late stages of epidermal cell differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

The 50- and 58-kdalton keratin classes as molecular markers for stratified squamous epithelia: cell culture studies

The keratins are a highly heterogeneous group of proteins that form intermediate filaments in a wide variety of epithelial cells. These proteins can be divided into at least seven major classes according to their molecular weight and their immunological reactivity with monoclonal antibodies. Tissue-distribution studies have revealed a correlation between the expression of specific keratin classes and different morphological features of in vivo epithelial differentiation (simple vs. stratified; keratinized vs. nonkeratinized). Specifically, a 50,000- and a 58,000-dalton keratin class were found in all stratified epithelia but not in simple epithelia, and a 56,500- and a 65-67,000-dalton keratin class were found only in keratinized epidermis. To determine whether these keratin classes can serve as markers for identifying epithelial cells in culture, we analyzed cytoskeletal proteins from various cultured human cells by the immunoblot technique using AE1 and AE3 monoclonal antikeratin antibodies. The 56,500- and 65-67,000-dalton keratins were not expressed in any cultured epithelial cells examined so far, reflecting the fact that none of them underwent morphological keratinization. The 50,000- and 58,000-dalton keratin classes were detected in all cultured cells that originated from stratified squamous epithelia, but not in cells that originated from simple epithelia. Furthermore, human epidermal cells growing as a monolayer in low calcium medium continued to express the 50,000- and 58,000-dalton keratin classes. These findings suggest that the 50,000- and 58,000-dalton keratin classes may be regarded as "permanent" markers for stratified squamous epithelial cells (keratinocytes), and that the expression of these keratin markers does not depend on the process of cellular stratification. The selective expression of the 50,000- and 58,000-dalton keratin classes, which are synthesized in large quantities on a per cell basis, may explain the high keratin content of cultured keratinocytes.     

Immunolocalization of keratin polypeptides in human epidermis using monoclonal antibodies

Three monoclonal antibodies (AE1, AE2, and AE3) were prepared against human epidermal keratins and used to study keratin expression during normal epidermal differentiation. Immunofluorescence staining data suggested that the antibodies were specific for keratin-type intermediate filaments. The reactivity of these antibodies to individual human epidermal keratin polypeptides (65-67, 58, 56, and 50 kdaltons) was determined by the immunoblot technique. AE1 reacted with 56 and 50 kdalton keratins, AE2 with 65-67 and 56-kdalton keratins, and AE3 with 65-67 and 58 kdalton keratins. Thus all major epidermal keratins were recognized by at least one of the monoclonal antibodies. Moreover, common antigenic determinants were present in subsets of epidermal keratins. To correlate the expression of specific keratins with different stages of in vivo epidermal differentiation, the antibodies were used for immunohistochemical staining of frozen skin sections. AE1 reacted with epidermal basal cells, AE2 with cells above the basal layer, and AE3 with the entire epidermis. The observation that AE1 and AE2 antibodies (which recognized a common 56 kdalton keratin) stained mutually exclusive parts of the epidermis suggested that certain keratin antigens must be masked in situ. This was shown to be the case by direct analysis of keratins extracted from serial, horizontal skin sections using the immunoblot technique. The results from these immunohistochemical and biochemical approaches suggested that: (a) the 65- to 67-kdalton keratins were present only in cells above the basal layer, (b) the 58-kdalton keratin was detected throughout the entire epidermis including the basal layer, (c) the 56- kdalton keratin was absent in the basal layer and first appeared probably in the upper spinous layer, and (d) the 50-kdalton keratin was the only other major keratin detected in the basal layer and was normally eliminated during s. corneum formation. The 56 and 65-67- kdalton keratins, which are characteristic of epidermal cells undergoing terminal differentiation, may be regarded as molecular markers for keratinization.     

Cytokeratin immunoreactivity in lobular intraepithelial neoplasia.

Eighteen commercially available antibodies reactive against different cytokeratin proteins were tested on classic examples of lobular intraepithelial neoplasia (LIN) and of ductal intraepithelial neoplasia (DIN) of the breast. About 90% of higher-grade DIN (AIDH and DCIS) show no or substantially diminished reaction with clone 34betaE12 (specified as reactive against keratins 1, 5, 10, and 14 as determined by the manufacturer), while the cells of LIN were found to express the antigen reactive with this antibody. To determine which of these four keratins are present in the cells of LIN, antibodies reactive against these individual four keratins were tested. None of the four antibodies to keratins 1, 5, 10, or 14 reacted with the cells of LIN. To investigate this further, 13 additional monoclonal antibodies to various other keratin proteins were tested on the cells of LIN. Those that successfully reacted with the cells of LIN were further tested on the cells of DIN. All of the individual antibodies reactive with the cells of LIN were also reactive with the cells of DIN to a degree, with clone RCK108 (reactive against keratin 19) coming the closest to demonstrating the reactivity seen with 34betaE12. We conclude that the reactivity seen in the cells of LIN with 34betaE12 is due to either (a) a crossreaction with keratin 19 that is slightly less prominent than the reaction of the individual clone RCK108, (b) a crossreaction with a keratin protein that was not tested (3, 11, 12), (c) a crossreaction with a protein closely resembling keratin in formalin-fixed, paraffin-embedded tissue, or (d) the detection of a mutated or truncated form of keratin 1, 5, 10, or 14 that cannot be detected by the individual monoclonal antibody.     

Correlation of specific keratins with different types of epithelial differentiation: monoclonal antibody studies

We have prepared three monoclonal antibodies against human epidermal keratins. These antibodies were highly specific for keratins and, in combination, recognized all major epidermal keratins of several mammalian species. We have used these antibodies to study the tissue distribution of epidermis-related keratins. In various mammalian epithelia, the antibodies recognized seven classes of keratins defined by their immunological reactivity and size. The 40, 46 and 52 kilodalton (kd) keratin classes were present in almost all epithelia; the 50 kd and 58 kd keratin classes were detected in all stratified squamous epithelia, but not in any simple epithelia; and the 56 kd and 65-67 kd keratin classes were unique to keratinized epidermis. Thus the expression of specific keratin classes appeared to correlate with different types of epithelial differentiation (simple versus stratified; keratinized versus nonkeratinized).     

Embryogenesis of stratified squamous epithelium. II. Developmental stage-specific immunoreactivity of keratins

Throughout embryogenesis of the rat palate, from the early fetal to adult stages, a consistent subset of keratin proteins is synthesized in the epithelial lining cells. Although the relative abundance of particular keratins has been shown to vary with ongoing palatogenesis, the expression of finite keratins appears to be genetically predetermined. In order to preliminarily ascertain whether conformational changes accompanied intermediate filament 'maturation' from monomeric to polymeric keratin formation, we screened cytokeratins with polyclonal and monoclonal antibodies generated against adult-type keratins. Until epithelial stratification occurred on the 16th day of gestation, the keratin proteins were weakly immunoreactive. On the other hand, subsequent to epithelial thickening, adult-type immunoreactivity was initiated and progressed concomitantly with ongoing palatal development. These findings suggest that the cytokeratin intermediate filaments may progress through conformational 'maturation' during polymerization, and play a role in the eventual acquisition of the adult-type epithelial structure and function.     

Various keratin antibodies produce immunohistochemical staining of human myocardium and myometrium

Various polyclonal and monoclonal antibodies to keratins were used to stain different human muscle tissues by paired immunofluorescence and the unlabelled antibody peroxidase-anti-peroxidase method. In the myocardium, distinct coloration of the intercalated discs was produced by two polyclonal reagents to human epidermal keratins but not by two monoclonal antibodies to cytokeratins from pig renal tubular cells. In the myometrium--mainly in the middle layer of the uterine wall--cytoplasmic coloration of a varying fraction of the smooth muscle bundles was produced, especially by one of the polyclonal and by both monoclonal reagents. The staining was often confined to the perinuclear region. The keratin-positive myometrial cells usually coexpressed vimentin and actin in various proportions. These findings indicated that intermediate filaments of the keratin type, or antigenically similar elements, are not restricted to cells of epithelial origin. Other types of muscle cells did not react with keratin antibodies, but keratin-positive macrophages were occasionally found in tongue musculature and in inflamed epicardium. Altogether, our observations emphasize that keratin reactivity cannot be considered specific for epithelial (or mesothelial) cells without reservation.     

Tissue distribution of keratin 7 as monitored by a monoclonal antibody

Monoclonal antibody (RCK 105) directed against keratin 7 was obtained after immunization of BALB/c mice with cytoskeletal preparations from T24 cells and characterized by one- (1D) and two-dimensional (2D) immunoblotting. In cultured epithelial cells, known from gel electrophoretic studies to contain keratin 7, this antibody gives a typical keratin intermediate filament staining pattern, comparable to that obtained with polyclonal rabbit antisera to skin keratins or with other monoclonal antibodies, recognizing for example keratins 5 and 8 or keratin 18. Using RCK 105, the distribution of keratin 7 throughout human epithelial tissues was examined and correlated with expression patterns of other keratins. Keratin 7 was found to occur in the columnar and glandular epithelium of the lung, cervix, breast, in bile ducts, collecting ducts in the kidney and in mesothelium, but to be absent from gastrointestinal epithelium, hepatocytes, proximal and distal tubules of the kidney and myoepithelium. Nor could it be detected in the stratified epithelia of the skin, tongue, esophagus, or cervix but strongly stained all cell layers of the urinary bladder transitional epithelium. When applied to carcinomas derived from these different tissue types it became obvious that an antibody to keratin 7 may allow an immunohistochemical distinction between certain types of adenocarcinomas.     

Transient expression of simple epithelial keratins by mesenchymal cells of regenerating newt limb

Structural proteins of the intermediate filament family are an early indicator of differentiation before organogenesis becomes apparent. Keratin intermediate filaments are characteristically expressed only by epithelial and not by mesenchymal cells. Here we show, using monoclonal antibodies, a transient expression of the keratin pair 8 and 18 in a population of mesenchymal cells in the regenerating newt limb, specifically in the undifferentiated progenitor cells (blastemal cells) which give rise to the new tissues. These keratins are also expressed in cultured limb cells that can differentiate into muscle. In contrast no reactivity with anti-keratin 8 and 18 antibodies was observed in the newt limb bud at an early stage of development, indicating a molecular difference between the developing and regenerating limb. The molecular weights of the newt proteins detected by these antibodies are very similar to those of human keratins 8 and 18, further supporting the immunocytochemical evidence that the newt homologs of these keratins are expressed in blastemal cells. This is the first demonstration of keratin expression in mesenchymal progenitor cells in an adult animal.     

Density-dependent expression of keratins in transformed rat liver cell lines

Immunomorphological examination of the distribution of three keratins in cultured rat liver-derived epithelial cell lines of the IAR series was performed in order to find out the effects of neoplastic evolution on the expression of these epithelium-specific markers. Specific monoclonal antibodies were used to reveal various intermediate filament proteins: keratins with molecular masses of 55, 49 or 40 kD (K55, K49 or K40), and vimentin. The expression of keratins was negligible in sparse and dense cultures of non-transformed lines, which had typical epithelial morphology. The examined keratins were also absent in the sparse cultures of transformed lines, which have lost partially or completely the morphological features of epithelia. However, cells in dense cultures of most transformed lines contained numerous keratin filaments. It is suggested that the paradoxical increase of keratin expression after transformation is due to increased saturation density of transformed cultures; this high density favours the expression. As shown by the experiments with culture wounding, the effects of density are local and reversible. While K55 was present in all the cells of dense cultures, the expression of the other two keratins was dependent on the cell position within these cultures. It is suggested that the expression of the latter two keratins, besides high cell density, also requires the presence (K40) or the absence (K49) of cell-substratum contacts. Possible mechanisms of the effects of cell density on the expression of keratins are discussed.     

Classification of epidermal keratins according to their immunoreactivity, isoelectric point, and mode of expression

Human epidermal keratinocytes express under various growth conditions a total of at least nine keratins that can be divided into two subfamilies. Subfamily A comprises 40-, 46-, 48-, 50-/50'-, and 56.5-kilodalton (kd) keratins which are relatively acidic (pI less than 5.5) and, with the exception of 46-kd keratin, are recognized by AE1 monoclonal antibody. Subfamily B comprises 52-, 56-, 58-, and 65-67-kd keratins which are relatively basic (pI greater than 6) and are recognized by AE3 monoclonal antibody. Within each keratin subfamily, there is a constant member (50-/50'- and 58-kd keratins of the subfamilies A and B, respectively) that is always expressed. The other seven keratins of both subfamilies are variable members whose expression depends upon the cellular differentiated state, which is in turn modulated by the growth environment. The 56.5-kd keratin (subfamily A) and the 65-67-kd keratins (subfamily B) are coordinately expressed during keratinization. In contrast, the 40-, 46-, and 48-kd keratins (subfamily A) and the 52- and 56-kd keratins (subfamily B) are characteristic of cultured epidermal cells forming nonkeratinized colonies. These results demonstrate that human epidermal keratins can be classified according to their reactivity with monoclonal antikeratin antibodies, isoelectric point, and mode of expression. The classification of keratins into various subgroups may have important implications for the mechanisms of epidermal differentiation, the evolution of keratin heterogeneity, and the use of keratin markers for tumor diagnosis.     

Various keratin antibodies produce immunohistochemical staining of human myocardium and myometrium

Summary Various polyclonal and monoclonal antibodies to keratins were used to stain different human muscle tissues by paired immunofluorescence and the unlabelled antibody peroxidase-anti-peroxidase method. In the myocardium, distinct coloration of the intercalated discs was produced by two polyclonal reagents to human epidermal keratins but not by two monoclonal antibodies to cytokeratins from pig renal tubular cells. In the myometrium — mainly in the middle layer of the uterine wall — cytoplasmic coloration of a varying fraction of the smooth muscle bundles was produced, especially by one of the polyclonal and by both monoclonal reagents. The staining was often confined to the perinuclear region. The keratin-positive myometrial cells usually coexpressed vimentin and actin in various proportions. These findings indicated that intermediate filaments of the keratin type, or antigenically similar elements, are not restricted to cells of epithelial origin. Other types of muscle cells did not react with keratin antibodies, but keratin-positive macrophages were occasionally found in tongue musculature and in inflamed epicardium. Altogether, our observations emphasize that keratin reactivity cannot be considered specific for epithelial (or mesothelial) cells without reservation.Supported by the Norwegian Cancer Society, Jahre's Fund, and the Norwegian Research Council for Science and the Humanities     

Microinjection of monoclonal antibodies specific for one intermediate filament protein in cells containing multiple keratins allow insight into the composition of particular 10 nm filaments

Monoclonal antibodies specific for vimentin (V9), keratin 7 (CK 7) and keratin 18 (CK5) have been microinjected into three human epithelial cell lines: HeLa, MCF-7 and RT-4. The effect of the injection on other keratin polypeptides and vimentin filaments has been observed by double label immunofluorescence and in some instances by immunoelectron microscopy using gold labels of different sizes. Microinjection of V9 into HeLa cells causes the vimentin to collapse into a perinuclear cap leaving the keratin filaments unaffected. Injection of CK5 does not affect the vimentin filaments but disrupts the keratin filaments revealing keratin aggregates similar to those seen in some epithelial cell lines during mitosis. The keratin aggregates obtained after microinjection in HeLa contain the keratins 8 and 18 and probably also other keratins, as no residual keratin filaments are observed with a keratin polyclonal antibody of broad specificity. Aggregates in mitotic HeLa cells contain at least the keratins 7, 8, and 18. In MCF-7 cells keratins 8, 18, and 19 are observed in the aggregates seen 3 h after microinjection which, however, show a different morphology from those seen in HeLa cells. In MCF-7 cells a new keratin filament is built within 6 h after the injection which is composed mainly of keratin 8 and 19. The antibody-complexed keratin 18 remains in spherical aggregates of different size. The results suggest that in HeLa cells vimentin and keratin form independent networks, and that individual 10 nm filaments in epithelial cell lines can contain more than two keratins.     

Integration of different keratins into the same filament system after microinjection of mRNA for epidermal keratins into kidney epithelial cells

We have isolated poly (A)+ RNA, highly enriched in keratin mRNA from bovine muzzle epidermis, and injected it into epithelial cells of a different type, i.e., cultured kidney epithelial cells of the same (MDBK) or taxonomically distant (PtK2) species. Both recipient cell lines contain keratin polypeptides that are different from those present in epidermal cells. Using keratin subtype-specific antibodies in immunofluorescence and immunoelectron microscopy, we show that foreign keratin mRNAs when injected into a different type of epithelial cell can recruit polyribosomes and are translated together with the keratin mRNAs of the host cell. Foreign epidermal keratins are excluded from vimentin filaments and other structures but readily coassemble with the endogenous keratins and appear to be integrated into the meshwork of the preexisting kidney-type keratin filaments. Our observations indicate that different sets of keratin polypeptides from the same or different species can coassemble in the living cell into a common filament system. Thus we have developed a procedure that allows experimental alteration of the intermediate filament cytoskeleton within living epithelial cells.     

Keratin 13 expression is linked to squamous differentiation in rabbit tracheal epithelial cells and down-regulated by retinoic acid

Rabbit tracheal epithelial (RbTE) cells in primary culture undergo at confluence a multistep program of squamous differentiation. This study examines the expression of keratins in RbTE cells in relation to this differentiation process. During the exponential growth phase RbTE cells are undifferentiated and express three major keratins, K5, K14, and K19, and two minor keratins, K6 and K16. Squamous differentiation is accompanied by increased expression of keratins K6, K16, and K19, and in particular of keratin K13, which reacts specifically with the monoclonal antibody AE8. These changes in keratin synthesis coincide with the commitment to terminal differentiation. Retinoic acid, an inhibitor of the expression of the squamous differentiated phenotype, inhibits the increase in the expression of K6, K16, and K13 and reduces the expression of K5 and K14; however, retinoic acid treatment results in increased levels of keratin K19 and K18. Retinoic acid inhibits the expression of K16 and K13 at concentrations as low as 10(-9)-10(-10) M. At least some of these changes in keratins appear to be related to alterations in the cellular levels of the respective mRNAs. Our results indicate that specific changes in keratin expression, in particular keratin K13, correlate with the onset of squamous differentiation in RbTE cells. Induction of the expression of keratin K13 may function as a marker of squamous differentiation in tracheobronchial epithelial cells.     

Regulation of differentiation and keratin protein expression by vitamin A in primary cultures of hamster tracheal epithelial cells.

Hamster tracheal epithelial (HTE) cells maintained in primary culture show the induction of specific keratin species under vitamin A-deficient conditions. A comparison was made between the morphology and the expression of keratins in HTE cells in vivo and in primary culture with and without vitamin A. HTE cells cultured in serum-free, vitamin A-supplemented medium formed a simple cuboidal, ciliated monolayer and produced four simple epithelial keratins (7, 8, 18, and 19). In contrast, vitamin A-deficient HTE cells, which were squamous-like and stratified in culture, produced a more complex keratin pattern, with the induction of four additional keratin species (5, 6, 14, and 17). A keratin pair whose expression serves as a marker of stratified epithelia was induced, as well as a single keratin species unique to lesions of squamous metaplasia in vitamin A-deficient hamster tracheal organ cultures. Thus it appears that HTe cells retain the ability to respond to a deficiency in vitamin A through squamous differentiation and increased keratin production when removed from the intact organ and maintained in primary culture in a chemically defined medium. This system may be useful for the study of mechanisms underlying the squamous differentiation of respiratory epithelial cells in the development of bronchogenic tumors.     

Expression of keratins during experimentally induced carcinogenesis in hamster cheek pouch visualized polyclonal and monoclonal antibodies

Summary We obtained immnohistochemical profiles of several keratin proteins during experimentally induced carcinogenesis in hamster cheek-pouch mucosa using a polyclonal antibody (TK; detecting keratins with molecular masses of 41 65 kilodalton) and two monoclonal antibodies (KL1, 55- to 57-kilodalton keratins; PKK1; 40-, 45- and 52.5-kilodalton keratins). The squamous epithelium of normal pouch mucosa exhibited positive TK staining in all layers. KL1 staining in the spinous layer and PKK1 staining in the basal layer, thus indicating a regional or zonal distribution pattern. Epithelia undergoing basal hyperplasia showed irregular localization of PKK1 binding, while hyperkeratinized lesions exhibited the binding pattern found in normal epithelium. In case of epithelial dysplasia, there was reduced KL1 staining in spinous cells and decreased PKK1 staining in the basal and parabasal layers. Papillomas exhibited a rather zonal distribution of keratin staining. All squamous-cell carcinomas, irrespective of their degree of keratinization and infiltration pattern, showed slight or no PKK1 staining. Such lesions were only positive for KL1-detectable keratins in keratinizing tumour cells and exhibited an irregular distribution of TK binding. The expression of keratin proteins during carcinogenesis in hamster cheekpouch mucosa may parallel that of keratins in human squamous-cell carcinomas originating in the oral mucosa.