bromochloroacetic-acid and cholesteryl-sulfate

Integral hair lipid (IHL) is bound to the keratinized cell surface to make an environmentally resistant lipid envelope. It is mainly positioned on the hair cuticle and inner root sheath. IHL in the hair follicle may regard as hair barrier to be similar to the epidermal lipid layer functioning as skin barrier. Major constituents of IHL are fatty acid, phytosphingosine, ceramide in decreasing order. Minor constituents of IHL are cholesterol, cholesterol sulfate and cholesterol oleate. Cuticle or cortical cell surface in hair are abundant in fatty acids unlike the keratinized area of epidermis or sebaceous gland, and about 30-40% of such fatty acids are composed of 18-methyl-eicosanoic acid which is known to be bound to proteins by ester or thioester bond. Various factors including moisture, solvent, oxidative damage during bleaching or permanent waving affect IHL. Photochemical changes also can occur in IHL as well as in hair protein and hair pigment. Lipid metabolism is thought to play an essential role in lipid envelope of hair, but also involvement in hair development and function.

Topics: Ceramides; Cholesterol Esters; Fatty Acids; Hair Follicle; Humans; Keratins; Lipid Metabolism; Permeability; Sphingosine

Disturbances in the process of normal cornification leading to pathologic scaling provide the pathophysiologic basis for the ichthyoses. These disturbances may result from either abnormalities in protein metabolism (keratinization) (i.e., the "bricks") or in lipid metabolism (i.e., the "mortar") (Fig. 1). The evidence linking the various ichthyoses to defects in protein or lipid metabolism have been reviewed. It is likely that future advances will lead not only to a more complete understanding of the pathogenesis of these disorders, but also will shed significant light on the normal stratum corneum functions of barrier formation and desquamation, as well as lead the way to more rational and effective therapies. In recent years, prenatal diagnosis has been successfully performed in several of the ichthyoses. It is likely that improvements in our ability to prenatally diagnose those disorders will advance hand-in-hand with further progress in unraveling their underlying causes.

Topics: Animals; Cholesterol Esters; Epidermis; Fatty Acids, Essential; Female; Fetal Diseases; Humans; Ichthyosis; Keratins; Lipidoses; Mice; Pregnancy; Prenatal Diagnosis; Refsum Disease; Steryl-Sulfatase; Sulfatases; Syndrome; X Chromosome

The main function of the skin is to protect the body against exogenous substances. The skin barrier is located in the outermost layer of the skin, the stratum corneum. This layer consists of keratin enriched cells embedded in lipid lamellae. These lamellae form the main barrier for diffusion of substances through the skin. In diseased skin the barrier function is often impaired. For a full understanding of the properties of the human skin barrier, insight in the stratum corneum lipid organisation is of great importance. In this paper a short description of the lipid organisation in normal human stratum corneum will be given, after which the role the main lipid classes play in the stratum corneum lipid organisation will be described. In addition the effect of cholesterol sulfate and calcium on the lipid organisation will be discussed. Finally a new model, the "sandwich model", will be proposed that describe the localisation of the fluid phases in the stratum corneum.

Topics: Calcium; Cholesterol Esters; Diffusion; Epidermis; Extracellular Space; Humans; Keratins; Lipids; Models, Chemical; Permeability; Serine Proteinase Inhibitors; X-Ray Diffraction

The expression of cholesterol sulfate (CS) is known to increase during squamous differentiation of keratinocytes and to activate the epsilon, eta, and zeta forms of protein kinase C as a signal transduction molecule for the subsequent expression of transglutaminase-1 (TG-1) and cytokeratins. To gain further insight into the regulation of cellular differentiation and tumorigenesis by CS, we examined the concentration and the potential for synthesis of CS in seven and four surgical specimens from human ovarian and uterine cervical cancer patients, respectively, and eight cell lines established from human uterine cervical cancer patients and compared them for the rate of expression of cytokeratin. CS was present in all of the uterine cervical cancer tissue specimens but only in the mucinous type of cystadenocarcinoma among ovarian cancer tissue specimens, and cytokeratin was highly expressed in the tissues with a high concentration of CS, which were classified as well-differentiated on the basis of morphological examination. Similarly, cells derived from a keratinizing type of well-differentiated cervical carcinoma demonstrated strong potential for synthesis of CS, stained positive with anti-cytokeratin antibody, and exhibited a higher specific activity of TG-1, whereas the cells without CS did not stain positive with anti-cytokeratin antibody and exhibited a lower specific activity of TG-1. These findings indicate that CS is coexpressed with TG-1 and cytokeratin in the well-differentiated types of squamous cell cancers as a tumor marker.

Topics: Biomarkers, Tumor; Carcinoma, Squamous Cell; Cholesterol Esters; Female; Humans; Immunohistochemistry; Keratins; Lipid Metabolism; Lipids; Ovarian Neoplasms; Tumor Cells, Cultured; Uterine Cervical Neoplasms; Uterine Neoplasms

In this study the synthesis of cholesterol sulfate is examined in relation to the process of squamous differentiation in normal human epidermal keratinocytes (NHEK) in culture. During the exponential growth phase, NHEK cells exhibit a relatively high colony-forming efficiency and appear undifferentiated on the basis of their morphology and expression of biochemical characteristics. At confluence, the cells undergo terminal differentiation that is characterized by the commitment to terminal cell division (reduction in colony-forming ability) and expression of the differentiated phenotype. An accumulation of cholesterol sulfate accompanies this program of differentiation. This accumulation of cholesterol sulfate parallels the increase in transglutaminase type I activity and the competence to form cross-linked envelopes, whereas it precedes the "spontaneous" formation of cross-linked envelopes. Increased cholesterol sulfotransferase activity appears to account for the increase in cholesterol sulfate. The cholesterol sulfate accumulation, as well as the increase in cholesterol sulfotransferase and transglutaminase activity, are inhibited by retinoids. However, the presence of retinoids does not prevent NHEK cells from undergoing terminal cell division at confluence. Two NHEK cell lines expressing SV40-large T antigen also undergo terminal differentiation at confluence and start to accumulate cholesterol sulfate. Two other, differentiation-defective cell lines do not exhibit an increase in cholesterol sulfate at confluence. These results show that epidermal keratinocytes in culture, like cells in the epidermis, accumulate cholesterol sulfate when undergoing squamous differentiation. This program appears to consist of a retinoid-insensitive step (commitment to terminal cell division) and a retinoid-sensitive step (expression of the squamous differentiated phenotype).

Topics: Calcium; Cell Differentiation; Cell Line, Transformed; Cells, Cultured; Cholesterol Esters; Epidermal Cells; Epidermis; Humans; Keratins; Sulfotransferases; Tretinoin

Morphological observations suggest that rate tracheal epithelial (RTE) cells undergo squamous differentiation when maintained in cell culture. The purpose of the studies presented here was to examine and define differentiation of cultured RTE cells with the help of markers previously shown to be specific for squamous differentiation. Furthermore, we wanted to determine whether neoplastic transformation of these cells causes significant disruption of their differentiation program. Our experiments showed that squamous differentiation occurs in normal primary RTE cell cultures. Epidermal transglutaminase (transglutaminase type I) activity increased approximately 20-fold in RTE cultures as a function of time. Cholesterol sulfate, another marker of squamous differentiation, increased only modestly with time. A significant number of cells formed cross-linked envelopes in cultures growth-arrested at a cell density of approximately 250 cells/mm2. However, no significant changes in keratin expression were detected. Neoplastically transformed RTE cells which exhibit a greatly increased growth capacity expressed the same three markers of squamous differentiation as normal RTE cells. However, transglutaminase type I activity was relatively low. The cross-linked envelope formation was independent of cell density in the transformed cells. Like in normal RTE cultures, cholesterol sulfate accumulation only increased moderately with increasing cell density. The keratin pattern of transformed RTE cell lines was identical to that of normal primary RTE cells. A well-differentiated squamous cell carcinoma derived from one of the neoplastic cell lines expressed in vivo keratin markers typical of keratinization (56 kd acidic keratin and 65-67 kd basic keratins). We draw the following conclusions. (i) The biochemical studies confirm that normal RTE cells undergo squamous differentiation. The pathway of terminal squamous differentiation is cell density dependent. (ii) In transformed RTE cells, growth as well as differentiation are less subject to regulation by cell density than in normal cells. (iii) Transformed RTE cells are differentiation competent; the main abnormality appears to be that in transformed cell populations proliferation and differentiation occur concomitantly.

Topics: Animals; Cell Division; Cell Transformation, Neoplastic; Cells, Cultured; Cholesterol Esters; Epithelial Cells; Keratins; Male; Rats; Rats, Inbred F344; Trachea; Transglutaminases

This study examines the action of phorbol 12-myristate 13-acetate (PMA) on the synthesis of cholesterol sulfate in cultured normal and transformed human epidermal keratinocytes and assesses the antagonistic effects by retinoids and bryostatins on PMA action in relation to the multistep program of squamous differentiation. Treatment of normal human epidermal keratinocytes (NHEK) with PMA induces terminal cell division (irreversible growth-arrest) and causes a time- and dose-dependent increase in the incorporation of Na2(35)SO4 into cholesterol sulfate, a marker for squamous cell differentiation. This stimulation in sulfate incorporation appears specific for cholesterol sulfate and is due to increased levels of cholesterol sulfotransferase activity. The increase in cholesterol sulfate accumulation parallels the increase in transglutaminase type I, another marker for squamous differentiation. Several transformed NHEK cell lines do not exhibit increased levels of cholesterol sulfate and transglutaminase type I activity after PMA treatment, indicating that they acquired defects in the regulation of squamous differentiation. Bryostatins 1 and 2, and several diacylglycerol analogues neither inhibit cell proliferation nor increase cholesterol sulfate synthesis or transglutaminase activity, indicating that these agents do not induce terminal differentiation. In contrast, the bryostatins block the increase in cholesterol sulfate and transglutaminase activity as well as the commitment to terminal cell division by PMA. Bryostatin 1 inhibits the commitment to terminal cell division and the accumulation of cholesterol sulfate significantly even when added 8 h after PMA administration. Retinoids inhibit cholesterol sulfate accumulation and the increase in transglutaminase activity by PMA but do not affect the commitment to terminal cell division. In summary, phorbol esters induce in NHEK cells a program of squamous differentiation. This process of differentiation consists of the commitment to terminal cell division and expression of a squamous phenotype. Expression of this phenotype is accompanied by an accumulation of cholesterol sulfate and increased cholesterol sulfotransferase activity. Bryostatins 1 and 2 and retinoic acid affect this differentiation process at different stages.

Topics: Bryostatins; Cell Differentiation; Cell Line, Transformed; Cholesterol Esters; Diglycerides; Epidermal Cells; Humans; Keratins; Lactones; Macrolides; Tetradecanoylphorbol Acetate; Tretinoin

In this paper we show that the expression of the squamous differentiated phenotype and mucosecretory phenotype by cultured rabbit tracheal epithelial cells can be regulated by substratum and the presence of retinoic acid. Cells grown on a type I collagen gel matrix in the absence of retinoic acid stratify and undergo squamous differentiation as indicated by the appearance of squamous, cornified cells. Under these conditions cells are rich in desmosomes and heavy tonofilament bundles. These cells also express several biochemical markers for squamous differentiation such as high levels of type I transglutaminase and cholesterol sulfate. High levels of transglutaminase were also observed in areas of squamous metaplasia in tracheas of vitamin A-deficient hamsters. Treatment with retinoic acid not only blocked squamous differentiation as evidenced by the inhibition of the biochemical markers for squamous differentiation but induced the appearance of columnar, polarized cells many of which contained secretory granules. These granules stained positively with periodic acid thiocarbohydrazide and certain lectins indicating the presence of glycoconjugates. Analysis of radiolabeled glycoconjugates released into the medium indicated the synthesis of mucous glycoproteins. It appears that retinoic acid determines the pathway of differentiation whereas the collagen gel matrix is permissive for the expression of both phenotypes. The morphological and biochemical similarities between this in vitro cell system and the normal and metaplastic tracheal epithelium suggest that this rabbit tracheal epithelial cell system is a useful and relevant model to study the regulation of differentiation of the tracheobronchial epithelium.

Topics: Animals; Cell Differentiation; Cell Division; Cells, Cultured; Cholesterol Esters; Collagen; Cytoplasmic Granules; Epithelial Cells; Epithelium; Extracellular Matrix; Keratins; Male; Mucins; Phenotype; Rabbits; Trachea; Transglutaminases; Tretinoin

Effects of cholesterol sulfate on acetate incorporation into lipid fractions were examined in normal human fibroblast and keratinocyte cultures. Inhibition of sterologenesis in normal fibroblast cultures by cholesterol sulfate was less profound than that produced by either lipoprotein-containing serum or 25-hydroxycholesterol. Cholesterol sulfate also inhibited sterologenesis in low density lipoprotein receptor-deficient fibroblasts and inhibited both sterologenesis and 3-hydroxy-3-methylglutaryl coenzyme A reductase activity in keratinocytes. Cholesterol sulfate increased incorporation of acetate into fatty acid-containing lipids in preconfluent cultures of both cell types in lipoprotein-depleted media. Similar effects were not observed either in response to lipoprotein-containing serum or 25-hydroxycholesterol. Cholesterol sulfate had no effect on oleic acid incorporation into diglycerides, triglycerides, or phospholipid fractions; neither did it inhibit acid lipase activity; nor did it inhibit fatty acid oxidation, indicating that cholesterol sulfate does not inhibit catabolism of acyl lipids. Because cholesterol sulfate had similar effects on fatty acid metabolism in steroid sulfatase-deficient fibroblasts lines, desulfation to cholesterol is not a prerequisite. Cholesterol sulfate did not significantly affect incorporation of oleic acid into sterol esters in fibroblast cultures, but in contrast, inhibited sterol esterification in keratinocyte cultures. These data suggest a novel role for cholesterol sulfate as a modulator of cellular lipid biosynthesis.

Topics: Acetates; Acetic Acid; Cells, Cultured; Cholesterol Esters; Fatty Acids; Fibroblasts; Humans; Hydroxymethylglutaryl-CoA Reductase Inhibitors; Keratins; Lipid Metabolism; Skin; Sterols