Mast cell lines HMC‐1 and LAD2 in comparison with mature human skin mast cells – drastically reduced levels of tryptase and chymase in mast cell lines

Please cite this paper as: Mast cell lines HMC‐1 and LAD2 in comparison with mature human skin mast cells – drastically reduced levels of tryptase and chymase in mast cell lines. Experimental Dermatology 2010; 19 : 845–847. Abstract: To circumvent the costly isolation procedure associated with tissue mast cells (MC), two human MC lines, i.e. HMC‐1 and LAD2, are frequently employed, but their relation to mature MC is unknown. Here, we quantitatively assessed their expression of MC markers in direct comparison to skin MC (sMC). sMC expressed all lineage markers at highest and HMC‐1 cells at lowest levels. LAD2 cells expressed comparable high‐affinity IgE receptor α (FcεRIα) and FcεRIγ but less FcεRIβ than sMC and displayed slightly reduced, but robust FcεRI‐mediated histamine release. Only minor differences were found for total histamine content and c‐Kit expression. Huge, and to this level unexpected, differences were found for MC tryptase and chymase, with sMC >>> LAD2 > HMC‐1. Taken together, HMC‐1 cells represent very immature malignantly transformed MC, whereas LAD2 cells can be considered intermediately differentiated. Because of the minute levels of MC proteases, MC lines can serve as surrogates of tissue MC to a limited degree only.     

Purification of mast cell proteases from murine skin

Different subpopulations of mast cells are characterized by their abundant contents of either tryptase or in addition chymase. These two neutral proteases are found in mast cells and may thus hold a key to the understanding of mast cell dependent reactions. Such studies are however hampered by the lack of readily available supplies of chymase. We have therefore studied the simultaneous purification of both proteases from hairless moro hr/hr mouse skin, using a sequence of salt extractions and chromatographic separations. After three steps of extraction, a 13-fold purification with an 82% yield was obtained for tryptase and a 15-fold purification with a 90% yield for chymase. Further one step purification on conventional sephadex, sephacryl and octyl sepharose columns was unsatisfactory because of further protein contamination of the fractions. Heparin affinity chromatography caused a high loss of tryptase and residual protein contamination. Gradient elution on a benzamidine sepharose 6B column resulted however in a single, low yield (17.9%) tryptase peak and a broader, high yield (>90%) chymase peak, and a 34% yield high purity fraction. The proteases thus purified exhibited their typical inhibitor profile. On Western blot analysis and on autoradiography in the presence of the serine protease inhibitor diisopropylfluorophosphate (DFP), only one 28 kD molecule with chymase activity was identified, whereas a broad 32-38 kD band of tryptase monomers was noted. Taken together, these data show that, after salt extraction and a single benzamidine affinity chromatography step, both mast cell chymase and tryptase can be separated and in case of chymase also highly purified, allowing thus for the study of biological activities of this molecule.     

NKp46 regulates the production of serine proteases and IL‐22 in human mast cells in urticaria pigmentosa

NKp46 (natural cytotoxic receptor 1/CD335) is expressed on natural killer cells and Th2‐type innate lymphocytes. However, NKp46 expression in human mast cells has not yet been reported. Here, we explored the expression of, and possible role played by, NKp46 in such cells. NKp46 protein was expressed in human mast cells in urticaria pigmentosa principally of the tryptase‐positive/chymase‐negative type (MCT), but not in human non‐neoplastic skin mast cells of the tryptase‐positive/chymase‐positive (MCTC) type. NKp46 expression was also evident in the human neoplastic mast cell line HMC1.2. NKp46 knockdown changed the phenotype of this cell line from MCT to MCTC and downregulated GrB production, but did not influence IL‐22 production. An agonistic anti‐NKp46 antibody upregulated production of GrB and IL‐22, but did not change the MCT‐like phenotype of HMC1.2 cells. NKp46 was thus involved in the production of serine proteases and IL‐22 in human mast cells.     

Alterations in mast cells showing tryptase and chymase activity in epithelializating and chronic wounds

Mast cells can be found in contact with epidermis in certain circumstances; especially in chronic inflammatory skin diseases and chronic ulcers, but the significance of this association is obscure. In this study, the association of mast cells with wound healing was studied by counting mast cells in the wound edges at different stages after wounding the donor site skin for pinch-grafting. Chronic venous leg ulcers were biopsed for comparison. Tryptase- and chymase-positive mast cells were stained enzyme-histochemically for active proteinases. Both the number of tryptase-positive, i.e. total mast cells, and chymase-positive mast cells decreased during wound healing, but only the change in chymase-positive mast cells was statistically significant (P< or =0.03) the maximal decrease being 63% on day 7. No mast cells could be found in the vicinity of epithelialization margin. In venous leg ulcers, significantly more mast cells were present in the perilesional skin near the epithelium margin than in the wound bed (P=0.03), and mast cells were also seen in close contact with the basement membrane. Immunoreactivity for IL-4 and TNF-alpha in mast cells was studied to see if either of these molecules was associated with wound healing. In normally healing wounds, only a minority of mast cells were immunoreactive for these cytokines and no change in positive mast cell numbers could be seen during wound healing. In chronic wounds, IL-4 was absent in mast cells, and TNF-alpha positive mast cells were present only in perilesional skin and in small numbers. These results show that mast cells especially chymase-positive - decrease in number and can not be found in the epithelialization zone in normal wound healing, whereas tryptase-positive mast cells are associated with delayed wound healing and epithelialization in chronic wounds. Thus it seems, that mast cells attempt to control hyperproliferation of epidermis in chronic wounds.     

Skin mast cells develop non‐synchronized changes in typical lineage characteristics upon culture

Despite their hematopoietic origin, mast cells (MCs) develop exclusively in tissues, hampering their ample use in research. To circumvent this problem, tissue‐derived MCs are typically first expanded in culture, but the changes MCs may undergo in the novel micromilieu are poorly defined. Here, we monitor skin MCs from a number of donors over time, revealing profound yet non‐synchronized modulations in culture. While tryptase and chymase, the most specific markers, strongly decline, FcεRI surface expression, and FcεRI‐mediated histamine release steeply increase (from ≈15.5% to ≈60%), replicated by similar increments in TNF‐α secretion. Interestingly, the modulations are independent of cell cycle progression, as they are comparable in the growth and postgrowth phase, implying they primarily result from microenvironmental conditioning. The data highlight a high degree of MC versatility, but also advise that results based on cultured MCs should be viewed with some caution, as they may not accurately reflect their counterparts in situ.     

Differential expression of mast cell characteristics in human myeloid cell lines

In order to better understand the mechanisms governing display of mast cell characteristics in human myeloid cells, we have studied the mast cell phenotype in human promyelocytic (HL-60) and myelocytic (U-937, TPH-1) vs. basophilic (KU-812) and mast cell (HMC-1) lines, in part also in skin mast cells and blood monocytes, at mRNA and protein level before and after stimulation with mast cell growth factors. In unstimulated cells, mRNA for the stem cell factor (SCF) receptor c-kit and the gamma chain of the high-affinity IgE receptor (FcepsilonRI) was noted in all cells studied. Like mast and basophilic cells, THP-1 cells expressed the FcepsilonRIalpha and beta chains and weakly histidine decarboxylase (HDC), but they lacked mRNA for mast cell-specific proteases [tryptase, chymase, carboxypeptidase A (CPA)]. In contrast, HL-60 and U-937 cells lacked FcepsilonRIalpha, but expressed tryptase and chymase, HL-60 cells also CPA. KU-812 cells failed to express the basophil-specific marker 2D7. After a 10-day culture with SCF or fibroblast supernatants, baseline mRNA expression of most mast cell characteristics was upregulated, whereas c-kit mRNA expression decreased in all but THP-1 cells. Differential mRNA expression of FcepsilonRI vs. protease (tryptase) was confirmed at protein level by immunocytochemistry and enzymatic activity. KU-812 cells are thus closest to skin mast cells in that they express all molecules studied, except for chymase, followed by THP-1 cells that lack all mast cell proteases. In contrast, HL-60 and U-937 cells fail to express the FcepsilonRIalpha and beta chains but express most mast cell proteases. The selective and differential expression of mast cell characteristics in human myeloid cell lines suggests that induction of the mast cell phenotype is regulated by several independent genes and that mast cells and basophils branch off at early and distinct points of myeloid development.     

The production of collagen and the activity of mast-cell chymase increase in human skin after irradiation therapy

Fibrosis is a common complication of radiotherapy. The pathogenesis of radiation-induced fibrosis is not known in detail. There is increasing evidence to suggest that mast cells contribute to various fibrotic conditions. Several mast-cell mediators have been proposed to have a role in fibrogenesis. Tryptase and chymase, the predominant proteins in mast cells, have been shown to induce fibroblast proliferation and collagen synthesis in vitro. In order to explore the role of mast cells in irradiation-induced fibrosis, we analyzed skin biopsies and suction blister fluid (SBF) samples from the lesional and healthy-looking skin of 10 patients who had been treated for breast cancer with surgery and radiotherapy. The biopsies were analyzed histochemically for mast-cell tryptase, chymase, kit receptor, and tumor necrosis factor-alpha. Skin collagen synthesis was assessed by determining the levels of type I and III procollagen amino-terminal propeptides (PINP and PIIINP) in SBF and using immunohistochemical staining for PINP. Immunohistochemical stainings for prolyl-4-hydroxylase reflecting collagen synthesis and chymase immunoreactivity in irradiated and control skin were also performed. The mean level of procollagen propeptides in SBF, which reflects actual skin collagen synthesis in vivo, was markedly increased in irradiated skin compared to corresponding healthy control skin areas. The mean number of PINP-positive fibroblasts was also significantly increased in the upper dermis of radiotherapy-treated skin. The number of cells positive for tryptase, chymase and kit receptor was markedly increased in irradiated skin. In addition, using double-staining techniques, it was possible to demonstrate that in some areas of the dermis, tryptase-positive mast cells and fibroblasts are closely associated. These findings suggest a possible role of mast cells in enhanced skin collagen synthesis and fibrosis induced by radiotherapy.     

Immunoperoxidase and enzyme-histochemical demonstration of human skin tryptase in cutaneous mast cells in normal and mastocytoma skin

Summary Trypsin-like proteinase isolated from human skin was localized in cutaneous mast cells using immunoperoxidase and enzyme-histochemical techniques. Skin biopsy specimens were taken from four mastocytoma and four healthy patients. Immunoperoxidase staining was performed with protein A-sepharose purified rabbit polyclonal antibody raised against human skin tryptase and using aminoethylcarbazole as chromogen. The positively stained cells in the dermis were granular in character. Using peptide 4-methoxy-2-naphthylamide substrates (Bz-Arg-MNA, Z-Lys-Arg-MNA, Z-Gly-Arg-MNA, Z-Pro-Arg-MNA and Z-Gly-Pro-Arg-MNA) and Fast Garnet GBC as chromogen the red azo dye was found to precipitate in the cytoplasmic granules of the cutaneous mast cells. The enzymatic reaction was totally inhibited by diisopropyl fluorophosphate, leupeptin, and benzemidine. No marked inhibition was seen with soybean trypsin inhibitor and alpha-1-antitrypsin. The best substrate was Z-Gly-Pro-Arg-MNA giving the strongest red azo dye when incubation time was 15,30 or 60 min. These results show the localization of human skin tryptase in dermal mast cells and the usefullnes of Z-Gly-Pro-Arg-MNA as a suitable substrate tested for enzyme-histochemical localization of mast cells in healthy or mastocytoma skin.     

The effect of ultraviolet radiation exposure on the prevalence of mast cells in human skin

BACKGROUND: Dermal mast cells have been implicated as important effector cells in innate immunity, hypersensitivity responses and ultraviolet (UV)B-induced suppression of cell-mediated immune responses to contact allergens. Humans, like mouse strains, display variations in dermal mast cell prevalence. The factors determining these differences are yet to be fully elucidated. In mice, expression of the receptor for stem cell factor, c-kit, on dermal mast cells correlates with prevalence. OBJECTIVES: To evaluate dermal mast cell prevalence and mast cell c-kit expression in non-sun-exposed and sun-exposed skin in the same donor. METHODS: In 14 subjects, biopsies of skin (4 mm) were sampled from the skin sites of buttock, inner arm, shoulder and back of hand skin and dermal mast cell prevalence quantified. Non-sun-exposed buttock and chronically sun-exposed hand skin were evaluated for mast cell expression of c-kit and elastin content, a feature of photoageing and surrogate marker of UV exposure. RESULTS: The prevalence of dermal mast cells was significantly higher in hand skin than in the three other anatomically different skin sites. Significant correlations were observed in hand but not buttock skin between increasing dermal mast cell densities, extent of elastin content in the papillary dermis and age of the subject. Cellular expression of c-kit correlated with mast cell prevalence in hand skin. However, no relationship was observed in hand skin between c-kit expression, elastin content and age. CONCLUSIONS: The prevalence of mast cells in human skin is altered by factors that are intrinsic (mechanisms regulating c-kit expression) and extrinsic (chronic sun exposure), and the fact that the associations of mast cell prevalence with age is explained by the latter being a correlate of cumulative sun exposure.     

Mast cell chymase and tryptase during tissue turnover: analysis on in vitro mitogenesis of fibroblasts and keratinocytes and alterations in cutaneous scars

In order to shed further light on the potential role of mast cells during tissue turnover, we have investigated the number of mast cells containing only tryptase and those storing both tryptase and chymase by enzyme histochemistry in normal versus healing skin. Furthermore, we have studied the in vitro effect of these enzymes on the mitogenesis of subconfluent quiescent fibroblast and HaCaT keratinocyte cultures, using flowcytometric DNA analysis. Chymase-containing mast cell numbers were markedly decreased in scars (P<0.001), whereas the overall number of tryptase-containing mast cells was not decreased, although these cells were smaller and stained more faintly in scars. Chymase (5 to 300 mU/ml) induced a marked, dose-dependent in vitro mitogenic response in 3T3 fibroblasts, whereas the effects of tryptase, at up to 60 nM, were only moderate, compared to the known fibroblast mitogens EGF, TGF-alpha, alpha-thrombin and trypsin at optimal concentrations. Coincubation of either protease with EGF or alpha-thrombin had additive effects. In contrast to fibroblasts, keratinocytes showed only minor mitogenic responses to tryptase and chymase, also in comparison to other known mitogenic stimuli, and responses to EGF and alpha-thrombin were inhibited on costimulation of cells with the proteases. These findings document for the first time a potential role of mast cell chymase in connective tissue repair, with tryptase being less active on fibroblasts, and with inhibitory effects of both mast cell proteases on keratinocytes.     

Non-pathogenic commensal Escherichia coli bacteria can inhibit degranulation of mast cells

Background:  The mast cell's (MC) ability to rapidly release presynthesized mediators allows it to play a critical role in the immune system's first-line response to pathogens. Although recent research has illuminated the role of MCs in bacterial infection, little is known about how non-pathogenic bacteria influence MC responses.
Objective:  To characterize the influence of non-pathogenic Escherichia coli bacteria on MCs.
Results:  High concentrations of live E. coli strongly down-modulated the degranulation of murine peritoneal MCs under all activator conditions. Bacteria did not induce MC degranulation by themselves, and staining of MCs showed they were still entirely viable. Dead bacteria and bacterial supernatant had no effect on MC degranulation. Ex vivo experiments confirmed that E. coli exposure down-modulates subsequently induced MC degranulation and that this effect lasts for up to a few days after exposure.
Conclusion:  Our results show that high doses of non-pathogenic E. coli bacteria can function as a strong, direct inhibitor of MC degranulation. This suggests a possible basis for future antiallergic treatment or prophylaxis with commensal bacteria, i.e. probiotics.     

Mast cell survival and apoptosis in organ-cultured human skin

Mast cells accumulate and persist predominantly in the upper dermis of the skin but the mechanism for this is obscure. The skin is normally exposed to external air, which is essential for the maturation of the epidermis and probably also the dermis. In order to clarify the importance of air exposure on dermal mast cells, skin organ culture at the air-liquid interface (ALI) and submerged (SM) in medium (10% fetal calf serum and Dulbecco's modification of Eagle's medium) was used to study changes in tryptase-, chymase- and Kit-positive mast cell numbers during cultivation for up to 14 days. In addition, possible apoptosis (TACS TdT in situ apoptosis detection method) in chymase-positive mast cells was studied during the culture. In the less-physiologic SM culture, the number of Kit-positive mast cells decreased rapidly on day 1-2 and tryptase-positive cells decreased markedly on day 14. This decrease in mast cell numbers can be explained by the finding that a rapid increase in the apoptosis index of mast cells was induced on day 1-2. In contrast, in the more physiologic ALI culture, the number of Kit-positive cells was sustained over 1-2 days but then decreased on day 7. In addition, tryptase-positive cells decreased steadily in number but not to the same extent as those in the SM culture. Moreover, the increase in the apoptosis index of mast cells was delayed until day 7 in the ALI culture. Addition of exogenous stem cell factor (up to 200 ng/ml) to the SM culture could not prevent the decay in tryptase- and chymase-positive cells. However, stem cell factor reduced significantly the number of Kit-positive cells already on day 2 indicating that the cells had responded. Addition of histamine (0.25 or 1 mM) or tumor necrosis factor-alpha (500 or 2000 U/ml) caused a decrease in the number of tryptase- and Kit-positive cells in the SM culture. In conclusion, a novel finding was that air exposure in the ALI culture markedly delayed the rapid apoptosis and subsequent decrease in mast cell numbers noted to occur in the SM culture. Stem cell factor could not prevent the rapid decrease in mast cell numbers. Histamine and tumor necrosis factor-alpha are possible factors promoting the decline in mast cells.     

Cytokine secretion by human mast cells

Abstract Mast cells have been traditionally viewed as effector cells of immediate-type hypersensitivity reactions. Besides this, mast cell activation and degranulation have been associated with various biologically and clinically important functions. Results of the past few years suggest that mast cells are involved in the development of late-phase reactions and influence other chronic inflammatory responses through the generation and secretion of various multipotcnlial cylokines.     

Testosterone exerts selective anti‐inflammatory effects on human skin mast cells in a cell subset dependent manner

Androgens are known to exert anti‐inflammatory effects but their impact on mast cells (MCs) remains to be determined. Here, we show that MCs isolated from human foreskin samples (male) and those from breast skin (female) express the androgen receptor, albeit with a 10‐fold difference between the subsets. While fundamental MC properties (FcεRI, c‐Kit, tryptase; histamine release upon FcεRI cross‐linking) were unaffected or slightly reduced (chymase) by testosterone, the hormone had a more profound impact on the production of cytokines, with IL‐6 being a target (reduction by 53%). Interestingly, this effect was limited to breast skin MCs (15 of 16 donors displayed this phenomenon), but was not reproduced by foreskin MCs. Collectively, effector functions of human skin MCs are modulated by androgens in a gene‐selective and MC subset‐specific fashion. Possibly, MCs from women are more susceptible to testosterone. We also demonstrate that MC IL‐6 production is highly variable among individuals.     

Controversial role of mast cells in skin cancers

Cancer development is a multistep process characterized by genetic and epigenetic alterations during tumor initiation and progression. The stromal microenvironment can promote tumor development. Mast cells, widely distributed throughout all tissues, are a stromal component of many solid and haematologic tumors. Mast cells can be found in human and mouse models of skin cancers such as melanoma, basal and squamous cell carcinomas, primary cutaneous lymphomas, haemangiomas and Merkel cell carcinoma. However, human and animal studies addressing potential functions of mast cells and their mediators in skin cancers have provided conflicting results. In several studies, mast cells play a pro‐tumorigenic role, whereas in others, they play an anti‐tumorigenic role. Other studies have failed to demonstrate a clear role for tumor‐associated mast cells. Many unanswered questions need to be addressed before we understand whether tumor‐associated mast cells are adversaries, allies or simply innocent bystanders in different types and subtypes of skin cancers.     

Analysis of mast cell subpopulations (MCT, MCTC) in cutaneous inflammation using novel enzyme-histochemical staining techniques

Abstract In order to gain insights into the dynamics of mast cell subpopulations in normal and diseased skin, a novel enzyme-histochemical double and triple staining method was employed that allowed the detection of metachromasia (toluidine blue) and the mast cell proteases tryp-tase and chymase within the same cell. Cryostat sections were used of skin biopsies from the following specimens: normal skin (N=4), psoriasis (N=13), atopic eczema (N=7), lichen planus (N=6), interferon α2a injection sites (N=l) of a leukemic infiltrate and corresponding normal skin of the same patient before and after treatment. (i) Equal numbers of tryptase-and chymase-positive mast cells (MCTC) were obtained in all normal and diseased specimens in papillary and reticular dermis, with threefold increases around appendages, (ii) Tryptase-positive mast cells (MCT) were absent in normal skin, but were markedly increased in a disease-specific pattern within the papillary dermis, the inflammatory infiltrate and around appendages, (iii) Marked increases of MCT were also noted at interferon injection sites within the leukemic infiltrate, but not in the normal skin of the same patient. These data suggest that disease-dependent mast cell dynamics involve only MCT in cutaneous inflammation and that MCT numbers are controlled by distinct, disease-specific local tissue factors.     

Ablation of human skin mast cells in situ by lysosomotropic agents

Mast cells are known to have a detrimental impact on numerous types of inflammatory skin diseases such as contact dermatitis, atopic eczema and cutaneous mastocytosis. Regimens that dampen skin mast cell‐mediated activities can thus offer an attractive therapeutic option under such circumstances. As mast cells are known to secrete a large array of potentially pathogenic compounds, both from preformed stores in secretory lysosomes (granules) and after de novo synthesis, mere inhibition of degranulation or interference with individual mast cell mediators may not be sufficient to provide an effective blockade of harmful mast cell activities. An alternative strategy may therefore be to locally reduce skin mast cell numbers. Here, we explored the possibility of using lysosomotropic agents for this purpose, appreciating the fact that mast cell granules contain bioactive compounds prone to trigger apoptosis if released into the cytosolic compartment. Based on this principle, we show that incubation of human skin punch biopsies with the lysosomotropic agents siramesine or Leu‐Leu methyl ester preferably ablated the mast cell population, without causing any gross adverse effects on the skin morphology. Subsequent analysis revealed that mast cells treated with lysosomotropic agents predominantly underwent apoptotic rather than necrotic cell death. In summary, this study raises the possibility of using lysosomotropic agents as a novel approach to targeting deleterious mast cell populations in cutaneous mastocytosis and other skin disorders negatively influenced by mast cells.     

Effects of pulsed infra-red low level-laser irradiation on mast cells number and degranulation in open skin wound healing of healthy and streptozotocin-induced diabetic rats

Abstract

Introduction: Low-level laser therapy (LLLT) has been reported to be capable of changing mast cell numbers and degranulation in experimental wounds. Objective: We conducted a study on the influence of pulsed LLLT on mast cells in wounds of non-diabetic and diabetic rats. Methods: Thirty-six rats were randomly divided into non-diabetic and diabetic groups. Type 1 diabetes milletes (DM) was induced in rats of the diabetic group by administration of streptozotocin (STZ). We inflicted two wounds in each rat. The first wound in both non-diabetic and diabetic groups was treated with an 890-nm laser, having pulse frequency of 80 Hz and energy density of 0.2 J/cm². Mast cell numbers and degranulation of all subgroups were assessed at 4, 7, and 15 days after the infliction of the wounds. Results and conclusion: According to the paired t-test, the total number of laser-treated mast cells was significantly higher than that of the placebos in the non-diabetic groups on days 4 and 15. The total number of laser-treated mast cells was significantly higher than that of the placebos in the diabetic groups on days 4 and 15. The number of granulated mast cells was significantly higher than that of degranulated mast cells for all laser-treated mast cells and placebo mast cells of the non-diabetic and diabetic groups.     

Structural diversity of mast cell granules in black and white skin

BACKGROUND: There are conflicting reports of structural differences between black and white skin, other than pigmentary differences. OBJECTIVES: To evaluate differences in mast cells between black and white skin. METHODS: Biopsies of normal buttock skin were obtained from four African-American males (29.2 +/- 3.0 years old) and four Caucasian males (29.4 +/- 1.2 years old) and processed routinely for electron microscopy. For the quantitative assessment of mast cell granules, five electron micrographs at a final magnification of x 53,700 were analysed for each individual, using a computer-assisted image analyser. More than 10 granules per cell, and a total of 1210 granules, were evaluated for their internal structures. RESULTS: Mast cells in black skin contained larger granules than those in white skin (P < 0.0001). In black skin, fusion of granules seemed to account for the larger sizes. The percentage of granule matrix occupied by curved lamellae was higher in white skin, whereas parallel-linear striations were more frequent in black skin (P < 0.05). The subgranular distribution of the mast cell proteases, tryptase and cathepsin G, were evaluated by immunoelectron microscopy. Tryptase reactivity was localized preferentially over the parallel-linear striations and partially over the dark amorphous subregions within granules of black skin, whereas it was confined to the peripheral area of granules, including curved lamellae, in white skin. Cathepsin G reactivity was more intense over the electron-dense amorphous areas in both groups, while parallel-linear striations in black skin and curved lamellae in white skin were negative. CONCLUSIONS: This study has confirmed ultrastructural differences in mast cell granules between black and white skin, which may be of functional importance.