Ultrastructural localization of amyloid P component in primary localized cutaneous amyloidosis

Amyloid P component (AP) was specifically localized to dermal amyloid deposits in the papular and nodular variants of primary localized cutaneous amyloidosis by an immunoperoxidase technique using an antibody to serum amyloid P component (SAP). Specific staining with anti-SAP of elastic fibre microfibrils which has previously been observed in normal skin, was also present and was noted in close proximity 10 deposits of amyloid material. AP associated with normal elastic fibre microfibrils may be involved in the deposition of amyloid fibrils in vivo.     

Amyloid elastosis: analysis of the role of amyloid P component.

We report the second case of amyloid elastosis. Our patient had an underlying primary systemic amyloidosis with lambda light chain paraproteinemia. Salient clinical features included a sclerodermatous facial appearance, cordlike thickening of superficial blood vessels, neck skin resembling that in pseudoxanthoma elasticum, livedo reticularis-like changes on the trunk, Raynaud's phenomenon, arterial and venous thromboses, and the nephrotic syndrome. Amyloid deposits were present in the dermis, around appendages, in blood vessel walls, and in a striking distribution surrounding individual elastic fibers, that appeared shortened and fragmented. Immunofluorescence, electron microscopic, and immunoultrastructural studies with antibodies to lambda light chain, localized the amyloid deposits to the region of the elastic fiber microfibrils, with which amyloid P component (AP) is invariably associated in normal tissues. Because AP binds amyloid fibrils, codistribution of amyloid deposits and AP in amyloid elastosis strongly supports the theory that elastic fiber-associated AP may act as a nidus for amyloid deposition.     

Tissue amyloid P component in normal human dermis is non-covalently associated with elastic fiber microfibrils

Tissue amyloid P component (TAP), a protein that crossreacts immunohistochemically with the normal plasma glycoprotein serum amyloid P component (SAP), is invariably associated with elastic fiber microfibrils in adult humans. We have investigated the nature of this association. Aliquots of minced, homogenized dermis, obtained following ethylenediamine tetraacetic acid (EDTA) separation of whole adult human skin, were extracted with different reagents, and the presence or absence of TAP in the pellet and in the supernatant following centrifugation was determined by SDS-PAGE and immunoblotting using anti-SAP antibodies. TAP was extractable from dermis using reagents which disrupt non-covalent bonds, including sodium dodecyl sulfate (SDS) and guanidine hydrochloride. TAP was not extracted by high molarity salt solutions, non-ionic detergents, or the reducing agents dithiothreitol and 2-mercaptoethanol. EDTA solution was similarly unsuccessful at eluting TAP from the dermal preparation, indicating that the association of TAP with elastic fiber microfibrils is not simply the result of Ca++-dependent binding. Collagenase solubilized some TAP, but this does not prove covalent linkage to elastic tissue of part of the TAP, because the apparent Mr of TAP extracted was identical to that of normal SAP subunits. We cannot completely exclude the possibility that a few subunits in each multimeric TAP molecule are covalently attached to the microfibrils. However, our findings that denaturing agents alone extracted most of the TAP from normal human dermis strongly suggest that the great majority of the dermal TAP is non-covalently bound to elastic fiber microfibrils. Thus TAP is not an integral constitutent of elastic fiber microfibrils.     

Immunohistochemical studies of amyloid P component distribution in normal human skin

The distribution of amyloid P component (AP) in normal human skin was investigated by a light and electron microscopic immunoperoxidase technique, using antibodies to serum amyloid P component (SAP). AP, or an immunologically cross-reactive protein, was found to be specifically localized to the microfibrils of papillary oxytalan fibers and to the peripheral microfibrillar mantle surrounding the elastin core of mature elastic fibers in the reticular dermis; collagen fibers were not stained with anti-SAP. AP was not detected in the dermal-epidermal basement membrane or in the basement membranes surrounding dermal papillary blood vessels and eccrine structures. These findings, which establish the detailed distribution of normal tissue AP in the skin, provide a basis for further studies of the function and behavior of this protein in health and disease.     

Primary localized cutaneous amyloidosis: dermal amyloid deposits do not bind antibodies to amyloid A protein, prealbumin or fibronectin

The chemical nature of the dermal amyloid deposits in primary localized cutaneous amyloidosis (PLCA) was investigated using histochemical and immunohistochemical techniques. Deposits of macular, papular and nodular PLCA showed potassium permanganate resistance of their affinity for Congo red dye, unlike amyloid A protein (AA) deposits, and did not bind antibodies to AA, prealbumin or fibronectin. Despite the frequent presence of immunoglobulins in deposits of macular and papular PLCA, there is no evidence that the amyloid fibrils are composed of protein AL. Although previous studies have identified keratin-like material in deposits of macular and papular PLCA, the exact nature of the amyloid fibril protein in these conditions, and the mechanism by which tonofilaments of necrotic keratinocytes are trans formed into amyloid material in the papillary dermis, remain uncertain.     

Amyloid P component binds to keratin bodies in human skin and to isolated keratin filament aggregates in vitro

Dermal keratin bodies, consisting mainly of keratin intermediate filament aggregates (KIFA) coated with IgM anti-KIF autoantibodies, are present in normal human skin and occur in increased quantities in certain skin diseases. Keratin bodies are normally rapidly removed, but in primary localized cutaneous amyloidosis (PLCA) they are converted by an unknown mechanism to amyloid. Amyloid P component (AP), a glycoprotein identical to, and derived from, the normal plasma protein serum amyloid P component (SAP), is present in all forms of amyloid including PLCA. We investigated the interaction between SAP, keratin bodies, and KIFA. Immunofluorescence staining of normal skin using fluoresceinated anti-SAP and rhodamine-conjugated anti-IgM, or AE-1/AE-3 anti-keratin antibodies followed by Texas Red-conjugated anti-mouse immunoglobulin, showed that 52% +/- 4 (mean +/- sem, n = 6) of keratin bodies bound anti-SAP. Similar findings were present in a biopsy from a patient with lichen planus. Isolated KIFA, prepared by 8M urea extraction of normal human epidermis or cultured keratinocytes, were preincubated with normal human serum as a source of SAP and then stained with fluoresceinated anti-SAP. Bright fluorescence seen when the incubation medium contained Ca++ was absent in the presence of ethylenediamine tetraacetic acid. Specific Ca++-dependent binding of SAP to KIFA was confirmed using immunoblotting. Binding of SAP to KIFA did not prevent their degradation following exposure to trypsin or alpha-chymotrypsin. Similarly, partial enzymatic digestion of KIFA did not abrogate their ability to bind SAP. Our findings, that SAP is associated with keratin bodies in skin and exhibits Ca++-dependent binding to KIFA in vitro, identify keratin filaments as a newly recognized ligand for SAP.     

Elastic globes: electron microscopic and immunohistochemical observations

Specimens from a patient with epidermolysis bullosa contained many elastic globes in the dermis. Ultrastructurally they were composed of (i) medium electron-dense amorphous substances, (ii) electron-dense round structures, and (iii) fine filaments. These various elements were seldom organized into typical normal elastic fiber and, therefore, it was difficult ultrastructurally to recognize them as such or components thereof. Immunohistochemically, elastic globes were strongly reactive with NKH-1, which stains elastic microfibrils, and antibody to serum amyloid P component (anti-SAP), which binds to elastic fiber microfibrils. However, elastic globes were negative with EKH-4 which recognizes 50 kd keratin of amyloid keratin and cytoid bodies. These findings suggested that elastic globes have a close immunologic profile to elastic fiber microfibrils, but not that of epidermal or epithelial keratin.     

Deficiency of tenascin-X causes abnormalities in dermal elastic fiber morphology

Deficiency of the extracellular matrix protein tenascin-X (TNX) was recently described as the molecular basis of a new, recessive type of Ehlers-Danlos syndrome. Here we report gross abnormalities of the elastic fibers and microfibrils in the dermis of these patients, and reduced dermal collagen content, as determined by quantitative image analysis. The ascending, fine elastic fibers in the papillary dermis were absent or inconspicuous and had few branches. The coarse elastic fibers of the reticular dermis were fragmented and clumped. At the ultrastructural level, irregular and immature elastin fibers and fibers devoid of microfibrils were observed. In TNX-deficient patients the dermal collagen density was reduced, but no structural abnormalities in the collagen fibrils were found. These findings suggest that both elastic fiber abnormalities and reduced collagen content contribute to the observed phenotype in TNX-deficient patients.     

A new c.1845A→T of oncostatin M receptor-β mutation and slightly enhanced oncostatin M receptor-β expression in a Chinese family with primary localized cutaneous amyloidosis

Primary localized cutaneous amyloidosis (PLCA) is a chronic itching skin disease with amyloid material deposited in the upper dermis. PLCA is more common in Southeast Asia and South America, where up to 10% of cases may be familial. Mutations of OSMR or IL31RA have been identified in PLCA. Here we detected a new OSMR mutation in a lichenoid PLCA family from north China. This is the first report of PLCA with gene mutation on the Chinese mainland. A heterozygous 1845A→T was found in exon 13 of the proband, causing p.Lys615Asn substitution, which was not found in screening 100 ethnically matched healthy controls. The particular mutated amino acid is well conserved throughout various evolutionary lineages, located within the second fibronectin III-like domain of oncostatin M receptor β subunit (OSMRβ), and in close vicinity to a previously reported mutation, p.Gly618Ala. Immunohistochemistry showed slightly enhanced OSMRβ expression in the lesion of the proband. This study extends the knowledge of PLCA gene mutation and further supports the pathogenic role of OSMRβ in PLCA.     

Elastic Fibers in Dermis of Juvenile Elastoma

To explore the ultrastructure of elastic fibers in juvenile elastoma, three patients (two without osteopoikilosis and one under examination of bones and joints) were studied by routine electron microscopy. In addition to normal elastic fibers, all the patients also exhibited alterations in elastic fibers. The altered ultrastructures showed lucent, homogenous matrix without peripheral microfibrils. The homogenous matrix were seen in various extensions from the small protrusions of the normal elastic fibers to the complete replacement of the entire fibers. Collagen fibrils occasionally showed twisted figures. Normal shapes of dermal glycosaminoglycans were increased in number. It seems likely that the lucent, homogenous matrix without peripheral microfibrils are the characteristic changes of elastic fibers in juvenile elastoma. The alteration could be nevoid in nature.     

Fibrillin immunoreactive fibers constitute a unique network in the human dermis: immunohistochemical comparison of the distributions of fibrillin, vitronectin, amyloid P component, and orcein stainable structures in normal skin and elastosis.

Fibrillin, a 350-kD glycoprotein, was recently localized to elastin-associated 10 nm microfibrils. Here, the distribution of fibrillin immunoreactivity was determined in normal skin in individuals of different ages and in lesions of solar elastosis or anetoderma. It was compared with the distribution of orcein-stainable fibers and with the immunoreactivities of vitronectin and amyloid P component. These glycoproteins are known to occur in conjunction with the orcein-stainable elastic fibers in adults, but not in the young. Fibrillin immunoreactivity was associated with orcein-stainable fibers in normal skin of both adults and the young. In addition, the fibrillin immunoreactive fiber network comprised fine fibers that were unstainable by orcein, anti-vitronectin, or anti-amyloid P component. Such fine fibers were especially abundant close to the dermal-epidermal junction zone. Immunoreactivities of anti-vitronectin and anti-amyloid P component were not always associated with fibrillin immunoreactivity but were consistently found to co-localize with orcein-stainable fibers in adults. This suggests vitronectin and amyloid P component to be associated with the amorphous elastin rather than with the microfibrils, although alternative interpretations are possible. In elastotic lesions, fibrillin immunoreactivity was generally fainter than that obtained using anti-vitronectin or anti-amyloid P component. In contrast, an extensive network of dermal fibers stained by anti-fibrillin, but not by anti-amyloid P component, anti-vitronectin, or orcein, was seen in an anetoderma lesion. In conclusion, fibrillin immunoreactivity is associated with a unique dermal network, which ultrastructurally is composed of microfibrils. These fibers are proposed to have an important structural and functional role in anchoring the dermal elastic fibers in the extracellular matrix and to the lamina densa.     

Altered erythrocyte membrane phosphorylation in psoriasis

Immunofluorescence staining of exposed skin from patients with erythropoietic protoporphyria (EPP) with antibodies to serum amyloid P component (SAP) and to fibronectin produced striking fluorescence of abnormal vascular structures in the upper dermis. An appearance of linear fluorescence along the dermo-epidermal junction with anti-SAP was the result of confluent staining of papillary oxytalan fibres. Amyloid P component (AP) was localized in ultrastructural immunoperoxidase studies to the peripheral (abluminal) regions of thickened dermal vessel walls, the site of maximum concentration of an amorphous matrix containing microfibrillar structures; antibodies to SAP did not bind to leaflets of the reduplicated vascular basal lamina. The characteristic thickening and reduplication of blood vessel walls seen with the electron microscope in EPP therefore involves increased local deposition of both AP and fibronectin.     

Middermal elastolysis. Report of a case and immunohistochemical studies on the dermal distribution of fibrillin, vitronectin and amyloid P component.

A 39-year-old woman with demarcated wrinkled areas, histologically characterized by absence of elastic fibers in the middle and upper reticular dermis, is described. Immunoreactivity of vitronectin and amyloid P component, present at the periphery of elastic fibers in normal skin in adults, was absent from the middermis of lesional skin as were orcein stained fibers. C9 neoantigen immunoreactivity, associated with elastic fibers in sun-exposed skin of middle-aged and elderly individuals, was present in conjunction with elastic fibers in papillary and lower reticular dermis in lesional skin but was absent in the middermis. In contrast, a fibrillin immunoreactive network was present throughout the dermis, indicating that the elastin-associated microfibrils are retained in the absence of amorphous elastin in lesional skin of middermal elastolysis.     

Colloid milium: a final degeneration product of actinic elastoid

Serum amyloid P component (SAP) is present not only in all types of cutaneous amyloidosis, but also in the normal dermal elastic fibers as well as abnormal elastic fibers, such as elastotic degeneration of elastic fibers in actinic keratosis. It was previously postulated that the colloid substance in colloid milium is a final degeneration stage of actinic elastosis. In a lesion of colloid milium SAP was intensely positive with an indirect immunofluorescence method using rabbit antiserum to human SAP. Electron microscopy of the colloid lesion revealed components of normal elastic fibers as well as those of actinic elastoid as seen in actinic elastosis. It is concluded that the colloid substance derives, at least in major part, from elastic fibers through actinic degeneration.     

Lichen amyloidosis,ankylosing spondylitis and autoimmune thyroiditis: coincidence or association?

Primary localized cutaneous amyloidosis (PLCA) is characterized by the deposition of amyloid in a previously apparently normal skin with the absence of other systemic or cutaneous disorder. Although ankylosing spondylitis may be associated with secondary systemic amyloidosis, no reports have been found showing the association of this disease with PLCA. In addition, the association of PLCA with autoimmune thyroiditis has not been previously reported. We report a concomitant occurrence of lichen amyloidosis, ankylosing spondylitis and autoimmune thyroiditis in a caucasian woman.     

Immunohistochemical demonstration of amyloid P component in skin of normal subjects and patients with cutaneous amyloidosis

The presence of amyloid P component (AP) in dermal deposits of cutaneous atnyloidosis was demonstrated by a direct immunofluorescence technique using an antibody to serum amyloid P component (SAP). AP was also shown, for the first time, to be a constituent of normal human skin. It was present at the periphery of dermal elastic tissue fibres, in basement membranes of dermal blood vessels and surrounding eccrine sweat glands but was absent from the dermo-epidermal basement membrane. The staining pattern in cutaneous amyloidosis was morphologically distinctive and readily distinguishable from staining of thickened vascular basement membranes in porphyria. Itnmunofluorescence with anti-SAP is simple and specific and may become the procedure of choice in the differential diagnosis of amyloidosis.     

弹性纤维与皮肤衰老

成熟的弹性纤维主要由弹性蛋白、原纤维蛋白微纤维及与弹性纤维有关的蛋白组成。内源性老化的皮肤弹性和柔韧度降低,弹性纤维网断裂和衰退。光老化皮肤不仅是富含原纤维蛋白的微纤维在表皮真皮交界处丢失,弹性蛋白变性,更重要的是在真皮深层混乱的弹性纤维蛋白物质的沉积,弹性蛋白的功能也受到影响。弹性纤维的修复可归纳为促进组成蛋白表达、改善组装条件、减少破坏因素3方面。     

Oxytalan, elaunin, and elastic fibers in the human skin.

The elastic system of normal human skin was studied by light and electron microscopy. By light microscopy three different types of fibers were observed: oxytalan, elaunin, and elastic. The most superficial ones (oxytalan fibers) are very thin and directed perpendicularly to the dermoepidermal junction. They start from a plexus with the tinctorial characteristics of elaunin fibers which is connected with the thicker elastic fibers of the reticular dermis. At the electron microscopic level the oxytalan fibers are formed by bundles of tubular microfibrils 10 to 12 nm in diameter. In the deepest layers of the dermis an amorphous material is seen in the core of these bundles. In the elaunin fibers the amorphous material is sparse, while in the elastic fibers it is abundant and compact.     

Dermatitis herpetiformis bodies. Ultrastructural study on the skin of patients using direct preembedding immunogold labeling

Skin samples from three adult patients with dermatitis herpetiformis (DH) and granular IgA deposits in the papillary tips were studied using ultrastructural immunogold technique. IgA positive, so-called DH bodies were identified as amorphous clumps--most probably immunocomplex aggregates--scattered throughout the upper papillary dermis. Dermatitis herpetiformis bodies were seen underneath the basement membrane, sometimes along microfibrillar bundles, as well as adjacent to the papillary collagen fibers and within the surface (microfibrillar) region of elastic tissue. Some DH bodies, however, were not related to any fibrillar components. The collagen and elastic fibers, microfibrillar bundles, anchoring fibrils, and elastic microfibrils themselves were unlabeled. Dermatitis herpetiformis bodies were not found in normal human skin. The results of our ultrastructural study indicate that DH bodies either are bound to a nonfibrillar component of dermal connective tissue or represent deposits of immune complexes trapped in DH skin.