Pemphigus vulgaris antigen, a desmoglein type of cadherin, is localized within keratinocyte desmosomes.

Pemphigus vulgaris antigen (PVA) is a member of the desmoglein subfamily of cadherin cell adhesion molecules. Because autoantibodies in this disease cause blisters due to loss of epidermal cell adhesion, and because desmoglein is found in the desmosome cell adhesion junction, we wanted to determine if PVA is also found in desmosomes. By immunofluorescence, PV IgG bound, in a dotted pattern, to the cell surface of cultured human keratinocytes induced to differentiate with calcium, suggesting junctional staining. However, by preembedding, immunogold electron microscopic studies only slight labeling could be detected in desmosomes, presumably because of difficulty in gold penetration of intact desmosomes. We therefore treated the keratinocytes with 0.01% trypsin in 1 mM calcium, conditions known to preserve cadherin antigenicity but that caused slight separation of desmosomes, before immunogold staining. In this case there was extensive labeling of the extracellular part of desmosomes but not of the interdesmosomal cell membrane which was stained with anti-beta 2-microglobulin antibodies. To confirm the specificity of this binding we showed that antibodies raised in rabbits against the extracellular portions of PVA also bound desmosomes in these cultures. In intact mouse epidermis we could also show slight, but specific, immunogold desmosomal labeling with PV IgG. Furthermore, neonatal mice injected with PV IgG affinity purified on PVA showed desmosomal separation with the IgG localized to desmosomal cores. These results indicate that PVA is organized and concentrated within the desmosome where it presumably functions to maintain the integrity of stratifying epithelia.

Production of rabbit antibodies against carboxy-terminal epitopes encoded by bullous pemphigoid cDNA.

A partial cDNA clone (called BP cDNA) with coding sequences for the carboxy-terminal region of bullous pemphigoid (BP) antigen has been recently isolated and sequenced. In order to determine whether specific peptides encoded by the cDNA could be used to raise antibodies against BP antigen, fusion proteins derived from fragments of the BP cDNA and 17-mer or 19-mer synthetic peptides, corresponding to its deduced amino acid sequence, were used to generate rabbit antibodies. Three restriction enzyme fragments, 1179 bp (5' end), 264 bp (middle), and 546 bp (3' end), of the 1992 open reading frame (ORF) of BP cDNA were subcloned in frame into pEX plasmids to make beta-galactosidase fusion proteins FP1, FP2, and FP3, respectively. Fusion proteins of the predicted molecular weight, and which bound anti-beta-galactosidase antibodies, were produced, confirming the length of the predicted ORF. Rabbits immunized with FP1, but not FP3, produced antibodies, similar to authentic antibodies from BP patients, which: 1) bound the epidermal basement membrane at titers over 10,000, as determined by indirect immunofluorescence; 2) bound the basement membrane on the roof of 1 M NaCl-split skin; 3) immunoprecipitated the 230-kD BP antigen; and 4) bound the hemidesmosome, as determined by immunoelectron microscopy. Rabbits immunized with FP2 also produced lower titer BP-like antibodies. We further showed that short hydrophilic synthetic peptides, contained in FP1, could induce similar BP-like antibodies in rabbits at immunofluorescence titers up to 2560. These rabbit antibodies should prove useful for further studies on the function and structure of particular epitopes of BP antigen as well as on the pathophysiology of disease.

C3d,g is present in normal human epidermal basement membrane.

mAb as well as polyclonal anti-human C3d antibodies were found to specifically bind to the epidermal basement membrane zone of normal human adult and neonatal skin in a linear continuous pattern on direct immunofluorescence microscopy. No such binding was found in dermal microvascular basement membranes. Studies of normal adult human skin using a rat mAb specific for C3g revealed the same pattern of epidermal basement membrane staining. Control polyclonal antibodies directed against C3, C3c, C5, IgG, IgA, or IgM showed no evidence of epidermal basement membrane binding or in situ deposits of immune complexes in samples of normal human skin that were all positive for C3d and C3g. Pre-adsorption of monoclonal or polyclonal anti-human C3d with purified human C3d completely blocked these reagents' epidermal basement membrane reactivity. Anti-human C3d epidermal basement membrane binding was not diminished by pre-treatment of substrate with antibodies directed against C3, C3c, C5, laminin, fibronectin, or type IV collagen as well as bullous pemphigoid, KF-1, or epidermolysis bullosa acquisita Ag. Direct immunofluorescence microscopy studies on 1 M NaCl split human skin showed that C3d and C3g were found in the base of the cleavage plane created within the lamina lucida. By immunoelectron microscopy, C3d was found along the base of the lamina densa and in the sublamina densa region of normal human epidermal basement membrane. Although anti-human C3d epidermal basement membrane binding was not altered by treatment of 6 micron skin sections with buffers of varying pH and ionic concentration, binding was abolished by treating dermal portions of salt split skin with 0.1 M dithiothreitol in 8 M urea. Studies of a patient with congenital C3 deficiency revealed that there was no binding of anti-human C3d or anti-human C3g to this subject's epidermal basement membrane. Moreover, treatment of this patient's skin with aged human serum containing C3d,g or purified human C3 did not restore epidermal basement membrane anti-human C3d binding. These studies demonstrate that C3d,g or a closely related C3 fragment is present in the epidermal basement membrane zone of normal human skin.

The human loricrin gene.

Loricrin is the major protein component of the cornified cell envelope of terminally differentiated mammalian epidermal (stratum corneum) cells. Using a specific human cDNA clone, we have isolated and characterized the human loricrin gene. We show that it has a very simple structure of a single intron of 1188 base pairs (bp) in the 5'-untranslated region; there are no introns in coding sequences. By use of rodent-human somatic cell hybrids, followed by in situ hybridization with a biotin-labeled genomic DNA clone, the single-copy gene maps to chromosome location 1q21. Polymerase chain reaction analyses of genomic DNAs from different individuals show that human loricrin consists of two allelic size variants, due to sequence variations in its second glycine loop domain, and these variants segregate in the human population by normal Mendelian mechanisms. Furthermore, there are multiple sequence variants within these two size class alleles due to various deletions of 12 bp (4 amino acids) in the major loop of this glycine loop domain. By use of a specific loricrin antibody, we show by immunogold electron microscopy that loricrin initially appears in the granular layer of human epidermis and forms composite keratohyalin granules with profilaggrin, but localizes to the cell periphery (cell envelope) of fully differentiated stratum corneum cells.

Human neutrophil-specific granule deficiency: a model to assess the role of neutrophil-specific granules in the evolution of the inflammatory response.

It has been suggested that neutrophil (PMN) specific granules are important in cell aggregation, locomotion, hydroxyl radical formation, and in extracellular functions such as the generation of complement-related inflammatory mediators (C5a) and the feedback regulation of myelopoiesis. In the current studies, a 9-yr-old boy with a history of recurrent infections and specific granule deficiency (absent lactoferrin, B-12 binding proteins, and characteristic specific granules on sucrose gradient centrifugation of cell homogenates) was studied to assess some of these concepts. In vivo, the patient had decreased PMN and monocyte accumulation into Rebuck skin windows but an expected febrile episode with an associated neutropenia (PMN margination) and neutrophilia (mobilization of marrow reserves) in response to intravenous endotoxin. In vitro, the patient's resting PMN showed increased ruffling, increased surface-to-volume ratio, and increased numbers of centriole-associated microtubules. His PMN showed a significant decrease in cell negative surface charge (which may relate to aggregation) in response to several stimuli and adhered better than normally to plastic. In addition, his PMN aggregated normally in response to the chemoattractant f-met-leu-phe, although the subsequent disaggregation normally seen with PMN did not occur with the patient's cells. Chemotaxis of the patient's PMN to several stimuli was abnormal, and specific saturable and displaceable binding of the chemoattractant f-met-leu-[3H]phe was decreased. Similarly, following incubation with secretagogues, there was a less than normal increase in f-met-leu-[3H]phe binding and an absence of the normal increases in PMN surface area. The patient's PMN bactericidal activity, stimulated oxygen metabolism (cytochrome-c reduction, chemiluminescence, and NBT reduction), and elicited changes in membrane potential were also abnormal. Studies assessing the mechanism for the abnormal monocyte accumulation into skin windows indicated the patient's monocyte chemotaxis was better than normal in vitro. However, the patient's PMN homogenates lacked a stimulus of monocyte locomotion and did not generate chemotactic activity normally from serum. Thus, the data indicate that specific granule constituents are not required for neutrophil margination in vivo or aggregation in vitro. However, the data support the concept that PMN-specific granules are important for PMN locomotion and oxidative metabolism. In addition, extracellular release of specific granule constituents appears to be important for amplification of the initial and subsequent phases of the inflammatory response.