A Scoping Review of the Role of Metalloproteinases in the Pathogenesis of Autoimmune Pemphigus and Pemphigoid.

Pemphigus and pemphigoid diseases are potentially life-threatening autoimmune blistering disorders that are characterized by intraepithelial and subepithelial blister formation, respectively. In both disease groups, skin and/or mucosal blistering develop as a result of a disruption of intercellular adhesion (pemphigus) and cell-extracellular matrix (ECM) adhesion (pemphigoid). Given that metalloproteinases can target cell adhesion molecules, the purpose of the present study was to investigate the role of these enzymes in the pathogenesis of these bullous dermatoses. Studies examining MMPs (matrix metalloproteinases) and the ADAM (a disintegrin and metalloproteinase) family of proteases in pemphigus and pemphigoid were selected from articles published in the repository of the National Library of Medicine (MEDLINE/PubMed) and bioRxiv. Multiple phases of screening were conducted, and relevant data were extracted and tabulated, with 29 articles included in the final qualitative analysis. The majority of the literature investigated the role of specific components of the MMP family primarily in bullous pemphigoid (BP) whereas studies that focused on pemphigus were rarer. The most commonly studied metalloproteinase was MMP-9 followed by MMP-2; other MMPs included MMP-1, MMP-3, MMP-8, MMP-12 and MMP-13. Molecules related to MMPs were also included, namely, ADAM5, 8, 10, 15, 17, together with TIMP-1 and TIMP-3. The results demonstrated that ADAM10 and MMP-9 activity is necessary for blister formation in experimental models of pemphigus vulgaris (PV) and BP, respectively. The data linking MMPs to the pathogenesis of experimental BP were relatively strong but the evidence for involvement of metalloproteinases in PV was more tentative. These molecules represent potential candidates for the development of mechanism-based treatments of these blistering diseases.

The evolution of ADAM gene family in eukaryotes.

The ADAM (A Disintegrin And Metalloprotease) gene family encodes proteins with adhesion and proteolytic functions. ADAM proteins are associated with diseases like cancers. Twenty ADAM genes have been identified in humans. However, little is known about the evolution of the family. We analyzed the repertoire of ADAM genes in a vast number of eukaryotic genomes to clarify the main gene copy number expansions. For the first time, we provide compelling evidence that early-branching green algae (Mamiellophyceae) have ADAM genes, suggesting that they originated in the last common ancestor of eukaryotes, before the split of plants, fungi and animals. The ADAM family expanded in early metazoans, with the most significative gene expansion happening during the first steps of vertebrate evolution. We concluded that most of mammal ADAM diversity can be explained by gene duplications in early bone fish. Our data suggest that ADAM genes were lost early in green plant evolution.

The roles of ADAMTS in angiogenesis and cancer.

Angiogenesis is an indispensable mechanism involved in both physiological processes and various pathological conditions, such as inflammation, aberrant wound healing, tumor progression, and metastasis. Among many angiogenic stimulators and inhibitors, vascular endothelial growth factor (VEGF) is regarded as one of the most important members of the signaling protein family involved in blood vessel formation and maturation. The a disintegrin and metalloproteinase with thrombospondin motifs (ADAMTSs) proteins are a family of multifunctional proteinases. Such proteolytic enzymes are associated with various physiological processes, such as collagen maturation, organogenesis, angiogenesis, and reproduction. Importantly, deficiency or overexpression of certain ADAMTS proteinases has been shown to be directly involved in a number of serious diseases, including tumor progression and metastasis. This review explores in-depth the connections between ADAMTS proteinases as positive/negative mediators during angiogenesis and VEGF.

Positive selection in the adhesion domain of Mus sperm Adam genes through gene duplications and function-driven gene complex formations.

BACKGROUND: Sperm and testes-expressed Adam genes have been shown to undergo bouts of positive selection in mammals. Despite the pervasiveness of positive selection signals, it is unclear what has driven such selective bouts. The fact that only sperm surface Adam genes show signals of positive selection within their adhesion domain has led to speculation that selection might be driven by species-specific adaptations to fertilization or sperm competition. Alternatively, duplications and neofunctionalization of Adam sperm surface genes, particularly as it is now understood in rodents, might have contributed to an acceleration of evolutionary rates and possibly adaptive diversification. RESULTS: Here we sequenced and conducted tests of selection within the adhesion domain of sixteen known sperm-surface Adam genes among five species of the Mus genus. We find evidence of positive selection associated with all six Adam genes known to interact to form functional complexes on Mus sperm. A subset of these complex-forming sperm genes also displayed accelerated branch evolution with Adam5 evolving under positive selection. In contrast to our previous findings in primates, selective bouts within Mus sperm Adams showed no associations to proxies of sperm competition. Expanded phylogenetic analysis including sequence data from other placental mammals allowed us to uncover ancient and recent episodes of adaptive evolution. CONCLUSIONS: The prevailing signals of rapid divergence and positive selection detected within the adhesion domain of interacting sperm Adams is driven by duplications and potential neofunctionalizations that are in some cases ancient (Adams 2, 3 and 5) or more recent (Adams 1b, 4b and 6).

A brief history of tumor necrosis factor α--converting enzyme: an overview of ectodomain shedding.

Many membrane-bound molecules are cleaved at the cell surface, thereby releasing their extracellular domains. This process, often referred to as ectodomain shedding, has emerged as a critical post-translational mechanism for various membrane-bound ligands, receptors, and adhesion molecules. Tumor necrosis factor α (TNFα)-converting enzyme (TACE/ADAM17) was originally identified as an enzyme responsible for releasing the membrane-bound TNFα precursor. However, subsequent studies found an exceptionally large number of target molecules of TACE, including the ligands for epidermal growth factor receptor, L-selectin, CD44, and vascular growth factor receptor 2. Furthermore, in vivo studies using TACE-conditional knockout mice demonstrated the crucial roles of TACE and ectodomain shedding under both physiological and pathological conditions. However, the potential clinical application of the manipulation of TACE activity remains to be investigated.

The secreted AdamTS-A metalloprotease is required for collective cell migration.

Members of the ADAMTS family of secreted metalloproteases play crucial roles in modulating the extracellular matrix (ECM) in development and disease. Here, we show that ADAMTS-A, the Drosophila ortholog of human ADAMTS 9 and ADAMTS 20, and of C. elegans GON-1, is required for cell migration during embryogenesis. AdamTS-A is expressed in multiple migratory cell types, including hemocytes, caudal visceral mesoderm (CVM), the visceral branch of the trachea (VBs) and the secretory portion of the salivary gland (SG). Loss of AdamTS-A causes defects in germ cell, CVM and VB migration and, depending on the tissue, AdamTS-A functions both autonomously and non-autonomously. In the highly polarized collective of the SG epithelium, loss of AdamTS-A causes apical surface irregularities and cell elongation defects. We provide evidence that ADAMTS-A is secreted into the SG lumen where it functions to release cells from the apical ECM, consistent with the defects observed in AdamTS-A mutant SGs. We show that loss of the apically localized protocadherin Cad99C rescues the SG defects, suggesting that Cad99C serves as a link between the SG apical membrane and the secreted apical ECM component(s) cleaved by ADAMTS-A. Our analysis of AdamTS-A function in the SG suggests a novel role for ADAMTS proteins in detaching cells from the apical ECM, facilitating tube elongation during collective cell migration.

Caracterização funcional das isoformas de splicing do gene ADAM23 / Functional characterization of ADAM23 gene splicing isoforms

A ADAM23 é uma glicoproteína transmembrana pertencente à família ADAM (A Disintegrin and Metalloprotease) que apresenta a estrutura protéica típica dos membros desta família, mas não possui atividade de metaloprotease. O gene ADAM23 apresenta três isoformas de splicing, α, ß e γ, que codificam proteínas com porções C-terminais distintas. As isoformas α e ß codificam proteínas com domínios transmembranas diferentes, enquanto γ provavelmente consiste em uma isoforma secretada ou citoplasmática de ADAM23. Foi demonstrado que o gene ADAM23 está epigeneticamente silenciado em tumores de mama de estágios mais avançados e que seu silenciamento está associado a um maior risco de desenvolvimento de metástases e a um pior prognóstico. Recentemente, foi descrito que a proteína ADAM23 interage diretamente com a integrina αVß3 na linhagem tumoral de mama MDA-MB-435, sendo capaz de modular seu estado conformacional, controlando sua ativação. Utilizando RNAi, observou-se que o silenciamento completo do gene ADAM23 (i.e., as três isoformas) aumenta os níveis de αVß3 em conformação ativa na superfície das células MDA-MB-435, promovendo um incremento de sua capacidade migratória e adesiva. No presente trabalho, avaliamos por reações de amplificação em tempo real o perfil de expressão das três isoformas de splicing do gene ADAM23 em cinco tecidos normais (mama, cólon, cérebro, próstata e pâncreas) e em doze linhagens tumorais derivadas destes tecidos. Observamos diferenças nos níveis de expressão das isoformas em todas as amostras avaliadas, tanto dentro de uma determinada amostra, como quando comparamos tecidos normais entre si ou com linhagens tumorais. A isoforma γ é a mais expressa em todos os tecidos normais (exceto em cérebro) e em todas as linhagens tumorais. Em tecido normal de mama e de próstata e nas doze linhagens tumorais, ADAM23α é a segunda isoforma mais expressa, sendo ß a menos expressa. Constatamos também que a fração representada por cada isoforma, em relação à expressão total do gene ADAM23, está alterada nas linhagens tumorais, em comparação aos tecidos normais correspondentes. Com o intuito de elucidar a função das isoformas de ADAM23 separadamente, utilizamos shRNAs (short hairpin RNAs) para reduzir a expressão de cada isoforma de modo individual e específico na linhagem tumoral MDA-MB-435, e avaliamos seu efeito na proliferação, na morfologia, na adesão e no espraiamento celular. Verificamos que a redução da expressão da isoforma γ aumentou significativamente a taxa de proliferação das células MDA-MB-435 cultivadas em modelo tridimensional. Demonstramos também que ADAM23γ participa da regulação da morfologia e da capacidade de espraiamento das células MDA-MB-435 em condições padrão de cultivo (i.e., meio de cultura completo e placas não-sensibilizadas com substratos) e em componentes específicos da matriz extracelular, como fibronectina, colágeno I e matrigel. A isoforma α também está envolvida no controle da morfologia e do espraiamento da linhagem MDA-MB-435, porém, de modo distinto da isoforma γ. Já ADAM23ß não interfere na morfologia das células MDA-MB-435 e tem efeito marginal no espraiamento celular apenas em condições padrão de cultivo. Em conjunto, nossos resultados demonstram que as isoformas de ADAM23 são diferencialmente expressas em tecidos normais e tumorais, e exercem funções biológicas distintas

ADAM23 is a transmembrane glycoprotein that belongs to the ADAM (A Disintegrin and Metalloprotease) family of proteins and exhibits the typical protein structure of the family members, but it doesn't have metalloprotease activity. The ADAM23 gene has three splicing isoforms, α, ß and γ, that code for proteins with different C-terminal regions. Isoforms α and ß code for proteins with different transmembrane domains, while γ probably constitute a secreted or cytoplasmatic isoform of ADAM23. It has been demonstrated that the ADAM23 gene is epigenetically silenced in advanced stage breast tumors and that its silencing is associated with a higher risk of developing metastases and with a worse prognosis. Recently, it was described that ADAM23 protein interacts directly with αVß3 integrin in the breast tumor cell line MDA-MB-435, modulating its conformational state and controlling its activation. Using RNAi, it was observed that the complete silencing of ADAM23 gene (the three isoforms) raises the levels of αVß3 in its active conformation in the surface of MDA-MB-435 cells, promoting an increase in its migratory and adhesive capacity. In the present work, we evaluated by real time PCR the expression pattern of the three splicing isoforms of ADAM23 gene in five normal tissues (breast, colon, brain, prostate and pancreas) and in twelve tumor cell lines derived from these tissues. We observed differences in the expression levels of the three isoforms in all samples, either within a specific sample or comparing normal tissues among them or with tumor cell lines. Isoform γ has the highest expression in all normal tissues (except for brain) and in all tumor cell lines evaluated. In breast and prostate normal tissues and in all tumor cell lines, ADAM23α is the second most expressed isoform, while ß is the less expressed. We also noticed that the ratio represented by each isoform, relative to the total expression of ADAM23 gene, is altered in the tumor cell lines, compared to the corresponding normal tissues. With the aim to elucidate the function of ADAM23 isoforms separately, we used shRNAs (short hairpin RNAs) to reduce the expression of each isoform specifically in the MDA-MB-435 tumor cell line, and studied its effects in proliferation, morphology, adhesion and cell spreading. We observed that the reduced expression of isoform γ significantly increased the proliferation rate of MDA-MB-435 cells cultivated in tridimensional system. Also, we demonstrated that ADAM23γ participates in the regulation of cell morphology and spreading of MDA-MB-435 cells, both in standard culture conditions (cell culture media with fetal serum and in plates not sensitized with substrates) and in specific components of extracellular matrix, such as fibronectin, collagen type I and matrigel. Isoform α is also involved in the control of morphology and spreading of MDA-MB-435 cell line, although in a distinct manner from isoform γ. ADAM23ß doesn't interfere in the morphology of MDA-MB-435 cells and plays a discrete role in cell spreading only under standard culture conditions. Together, our results demonstrate that ADAM23 isoforms are differently expressed in normal and tumoral tissue, and play distinct biological roles

Molecular characterization and functional analysis of a protease-related protein in Chang-liver cells.

In this study, the cDNA library of Chang-liver cells was immunoscreened using common ADAMs antibody to obtain ADAM related genes. We found one positive clone that was confirmed as a new gene by Blast, which is an uncharacterized helical and coil protein and processes protease activity, and named protease-related protein 1 (ARP1). The submitted GenBank accession number is AY078070. Molecular characterizations of ARP1 were analyzed with appropriate bioinformatics software. To analyse its expression and function, ARP1 was subcloned into glutathione S-transferase fusion plasmid pGEX-2T and expressed by E. coli system. The in vitro expression product of ARP1 was recognized by common ADAMs antibody with western blot. Interestingly, ARP1 cleaves gelatine at pH9.5, which suggests it is an alkaline protease. Semi-quantitative RT-PCR result indicates that ARP1 mRNA is strongly transcribed in the liver and the treated Chang-liver cells.

A review of the ADAMTS family, pharmaceutical targets of the future.

The disintegrin and metalloproteinase with thrombospondin motifs (ADAMTS) family of metalloproteases consists of 19 members. These enzymes play an important role in the turnover of extracellular matrix proteins in various tissues and their altered regulation has been implicated in diseases such as cancer, arthritis and atherosclerosis. Unlike other metalloproteinases, ADAMTS members demonstrate a narrow substrate specificity due to the various exosites located in the C-terminal regions of the enzymes, which influence protein recognition and matrix localization. The tight substrate specificity exhibited by ADAMTS enzymes makes them potentially safe pharmaceutical targets, as selective inhibitors designed for each member will result in the inhibition or cleavage of only a limited number of proteins. With the recent elucidation of crystal structures for ADAMTS-1, -4 and -5, the design of potent and selective small molecule inhibitors is underway and will lead to drug candidates for evaluation in clinical trials in the next 5-10 years.

All-trans retinoic acid-induced ADAM28 degrades proteoglycans in human chondrocytes.

In order to elucidate the mechanism of cartilage degradation in osteoarthritis (OA), we established a cell assay system. Under the stimulation of all-trans retinoic acid (ATRA), the human chondrosarcoma cell line HCS-2/8 increased proteoglycan release from inactivated bovine nasal cartilage (BNC) and the results suggested the involvement of membrane-bound metalloproteinase(s). Therefore, we focused on the induction of a disintegrin and metalloproteinase (ADAM) superfamily upon ATRA stimulation. Of all ADAMs tested, only ADAM28 was induced by ATRA in HCS-2/8 cells and also in human primary chondrocytes. We found that transfection of ADAM28 or its alternatively spliced soluble form augmented proteoglycan release in the cell assay; however, a mutant soluble form in which a portion of the disintegrin domain was deleted did not have proteoglycan-releasing activity, implying the importance of the domain for enzyme localization and substrate recognition for cartilage degradation in OA.

The "a disintegrin and metalloprotease" (ADAM) family of sheddases: physiological and cellular functions.

There is an exciting increase of evidence that members of the disintegrin and metalloprotease (ADAM) family critically regulate cell adhesion, migration, development and signalling. ADAMs are involved in "ectodomain shedding" of various cell surface proteins such as growth factors, receptors and their ligands, cytokines, and cell adhesion molecules. The regulation of these proteases is complex and still poorly understood. Studies in ADAM knockout mice revealed their partially redundant roles in angiogenesis, neurogenesis, tissue development and cancer. ADAMs usually trigger the first step in regulated intramembrane proteolysis leading to activation of intracellular signalling pathways and the release of functional soluble ectodomains.

ADAM function in embryogenesis.

Cleavage of proteins inserted into the plasma membrane (shedding) is an essential process controlling many biological functions including cell signaling, cell adhesion and migration as well as proliferation and differentiation. ADAM surface metalloproteases have been shown to play an essential role in these processes. Gene inactivation during embryonic development have provided evidence of the central role of ADAM proteins in nematodes, flies, frogs, birds and mammals. The relative contribution of four subfamilies of ADAM proteins to developmental processes is the focus of this review.

Differential expression of five members of the ADAM family in the developing chicken brain.

ADAMs (a disintegrin and metalloprotease) are a family of trans-membrane multi-domain metalloproteases with multiple functions. So far, more than 35 ADAM family members have been identified from mammalian and nonmammalian sources. Although some functions of ADAMs have been elucidated, their expression patterns remain poorly investigated, especially during CNS development. Here, we cloned the open reading frames or full-length cDNAs of ADAM9, ADAM10, ADAM12, ADAM22 and ADAM23 from chicken embryonic brain, analyzed their evolutionary relationship, and mapped their expression in the embryonic chicken brain by in situ hybridization for the first time. In general, each of the five ADAMs shows a spatially restricted and temporally regulated expression profile. However, the types of tissues and cells, which express each of the five ADAMs, differ from each other. ADAM9 is predominantly expressed in the choroid plexus and in the ventricular layer. ADAM10 is expressed by developing blood vessels, oligodendrocytes, and subsets of neurons and brain nuclei. ADAM12 is expressed by very few brain nuclei, cerebellar Purkinje cells, restricted regions of the neuroepithelium, and some neurons in the deep tectal layers. ADAM22 expression is strong in some brain nuclei and in the pineal gland. ADAM23 is expressed by most gray matter regions and the choroid plexus. The differential expression patterns suggest that the five ADAMs play multiple and versatile roles during brain development.

The ADAM metalloproteinases.

The ADAMs (a disintegrin and metalloproteinase) are a fascinating family of transmembrane and secreted proteins with important roles in regulating cell phenotype via their effects on cell adhesion, migration, proteolysis and signalling. Though all ADAMs contain metalloproteinase domains, in humans only 13 of the 21 genes in the family encode functional proteases, indicating that at least for the other eight members, protein-protein interactions are critical aspects of their biological functions. The functional ADAM metalloproteinases are involved in "ectodomain shedding" of diverse growth factors, cytokines, receptors and adhesion molecules. The archetypal activity is shown by ADAM-17 (tumour necrosis factor-alpha convertase, TACE), which is the principal protease involved in the activation of pro-TNF-alpha, but whose sheddase functions cover a broad range of cell surface molecules. In particular, ADAM-17 is required for generation of the active forms of Epidermal Growth Factor Receptor (EGFR) ligands, and its function is essential for the development of epithelial tissues. Several other ADAMs have important sheddase functions in particular tissue contexts. Another major family member, ADAM-10, is a principal player in signalling via the Notch and Eph/ephrin pathways. For a growing number of substrates, foremost among them being Notch, cleavage by ADAM sheddases is essential for their subsequent "regulated intramembrane proteolysis" (RIP), which generates cleaved intracellular domains that translocate to the nucleus and regulate gene transcription. Several ADAMs play roles in spermatogenesis and sperm function, potentially by effecting maturation of sperm and their adhesion and migration in the uterus. Other non-catalytic ADAMs function in the CNS via effects on guidance mechanisms. The ADAM family are thus fundamental to many control processes in development and homeostasis, and unsurprisingly they are also linked to pathological states when their functions are dysregulated, including cancer, cardiovascular disease, asthma, Alzheimer's disease. This review will provide an overview of current knowledge of the human ADAMs, discussing their structure, function, regulation and disease involvement.

[Cloning and structure analysis of sheep fertilin beta coding region].

Fertilin beta may play an important role in sperm-egg plasma membrane adhesion and fusion. To explore the effects of fertilin beta, the sperm membrane protein subunit, in the sheep fertilization process, we used RACE technique for cloning the full length cDNA of the coding region (CDS) of fertilin beta. The coding region was 2, 217 bp, which consists of 738 amino acids. The fertilin beta in the sperm membrane of sheep shares 79.4%, 66.7%, and 58.1% sequence identity with that in bovine, pig and human, respectively. The phylogenetic analysis of the fertilin beta gene family indicated the fertilin beta was clustered with bovine, and is closest to the one of bovine. This result is consistent with the result of the traditional classification. The protein structure analysis showed the disintegrin domain of sheep fertilin beta contains a TDE. Besides the above tripeptide sequence, the family member of ADAM (A Disintegrin and A Metalloprotease) follow the conserved sequence of ECD of X-D/E-E, and formed the conserved sequence of X-D/E-ECD. The pentapeptide sequence of the sheep fertilin beta is TDECE.

Metalloproteinases are enriched in microglia compared with leukocytes and they regulate cytokine levels in activated microglia.

Microglia are resident immune cells within the central nervous system (CNS). They become activated following neurological insults and increase their expression of cytokines. Also elevated in CNS injuries are proteases, including matrix metalloproteinases (MMPs) and A disintegrin and metalloproteinases (ADAMs). The spectrum of metalloproteinase members expressed by microglia and by the systemic leukocytes that infiltrate the injured CNS is unknown, as are their functions. We determined the levels of transcripts encoding all 24 MMPs, nine ADAMs, and their four physiological antagonists, tissue inhibitor of metalloproteinases (TIMPs), in human microglia, B and T cells, monocytes, and neutrophils. We found a distinct pattern for each immune subset and an enrichment of metalloproteinases in microglia compared with leukocytes. When microglia were activated, there was an upregulation of transcripts for nine metalloproteinases, and reduction of TIMP3. Activation of microglia also resulted in increased levels of tumor necrosis factor (TNF)-alpha, interleukin (IL)-1beta, and IL-10 protein in the conditioned media of cells. The amount of secreted TNF-alpha, but not IL-1beta or IL-10, was suppressed by BB94, a broad spectrum metalloproteinase inhibitor, and by TIMP3 but not TIMP1 or TIMP2. This inhibitory profile suggests the involvement of an ADAM member in TNF-alpha secretion. We conclude that microglia bear a metalloproteinase signature distinct from systemic cells, and that following activation, microglia upregulate TNF-alpha protein levels through a combination of elevated cytokine transcripts, increased metalloproteinase level and activity, and through the decrease of TIMP3. The results have implications for the regulation of neuroinflammation and its outcomes following CNS injuries.