Molecular basis of lipoid proteinosis in a Libyan family

Extracellular matrix protein 1 gene (ECM1) mutations in nine Iranian families with lipoid proteinosis

Background & objectives:

Lipoid proteinosis (LP) is an autosomal recessive disease. Clinical characteristics of this disease are hoarse voice, scarring of the skin, brain calcifications, and eyelid papules (moniliform blepharosis). Mutations in the ECM1 gene on 1q21.2 are responsible for this disease. This study was conducted to investigate the mutation spectrum of ECM1 gene in nine Iranian families having at least one LP patient diagnosed clinically.

Methods:

The entire ECM1 gene was screened using PCR and direct sequencing in nine Iranian families with 12 suspected LP patients who were referred to the clinic, along with their parents and siblings. Thirty healthy individuals were included as controls.

Results:

In only one patient a homozygous G>A transition at nucleotide c.806 in exon 7 was detected. A G>A substitution at nucleotide 1243 in exon 8 that changes glycine (GGT) to serine (AGT) was observed in most of our patients. Furthermore, in one patient there was a change in the sequence of intron 8, the A>T transition in nucleotide 4307. In addition, in two cases (one patient and one healthy mother with affected child) there was a C (4249) deletion in intron 8.

Interpretation & conclusions:

Our results indicate that although mutation in ECM1gene is responsible for lipoid proteinosis, it is likely that this is not the only gene causing this disease and probably other genes may be involved in the pathogenesis of the LP disease.

Identification of recurrent c.742G>T nonsense mutation in ECM1 in Pakistani families suffering from lipoid proteinosis

Lipoid proteinosis (LP) is one of the rare, recessive autosomal disorders clinically characterized by widespread deposition of hyaline-like material in the skin, mucosa and viscera. Classical features include beaded eyelid papules, laryngeal infiltration and hoarseness of voice caused by pathogenic mutations in the ECM1 gene located on 1q21.2. In present study ethnically different, three consanguineous Pakistani families with typical cutaneous features of LP were analysed to investigate the underlying molecular basis. PCR based linkage analysis using microsatellite markers localized the families to locus 1q21.2, harboring ECM1 gene. To identify the mutation in the candidate gene (ECM1), Sanger sequencing was carried out. All the families were found to carry c.742 G>T nonsense mutation in exon 7 of the ECM1 gene that resulted in a truncated ECM1 protein containing 247 amino acids instead of 540 (p.E248X). To further investigate the impact and importance of mutation in LP pathogenesis we applied different bioinformatics tools. In silico studies has predicted lack of functional domains and 65 % shorter ECM1 mutant protein. It is the first report of recurrence mutation from Pakistan as c.742G>T nonsense mutation was found in three ethnically different Pakistani families with LP. Study strengthens the conclusion that c.742G>T mutation is the pathological cause of LP. Furthermore, data also support the fact that exon 7 is one of the most common hot spots of pathological mutations in ECM1. The absence of functional domains and truncated sequence most likely contribute to the lack of ECM1 function and thereby influence several aspects of dermal homeostasis that leads to LP pathogenesis.

Lipoid proteinosis presenting with an unusual nonsense Q32X mutation in exon 2 of the extracellular matrix protein 1 gene

Lipoid proteinosis (LP) is a rare disorder characterized by extensive hyaline-like deposits on the skin, mucous membranes and various internal organs with varying clinical manifestations. The disorder has been recently shown to result from loss-of-function mutations in the extracellular matrix protein 1 gene (ECM1) on 1Q21. The two cases reported here had typical clinical and histological features consistent with LP. Direct sequencing of amplified DNA from the second patient showed a single nucleotide substitution (C > T) at nucleotide 94 within exon 2 of the ECM1 gene, nonsense mutation Q32X. This is the second case reported of LP with involvement of exon 2 of ECM1.

A novel missense mutation in exon 7 of the ECM1 gene in an Iranian lipoid proteinosis patient

Lipoid proteinosis (LP) is a rare autosomal recessive disorder. Classical clinical features include warty skin infiltration, papules on the eyelids, skin scarring, as well as extracutaneous abnormalities such as hoarseness of the voice, epilepsy, and neuropsychiatric abnormalities. A defect in the ECM1 gene is responsible for this disease. A 21-year-old female patient from consanguineous parents (first cousins) was referred to our clinic with many symptoms of LP, such as hoarse voice from infancy, diffuse acneiform scars on her face, and hyperkeratosis on her knees and elbows. The entire ECM1 gene was screened using PCR and sequencing. A novel missense mutation was found in exon 7 of this patient. We report a novel missense mutation in exon 7 of the ECM1 gene found in an Iranian LP patient that causes a C269Y amino acid exchange.

Molecular analysis of lipoid proteinosis: identification of a novel nonsense mutation in the ECM1 gene in a Pakistani family

Lipoid proteinosis is a rare autosomal recessive disease characterized by cutaneous and mucosal lesions and hoarseness appearing in early childhood that is caused by homozygous or compound heterozygous mutations in the ECM1 gene located on chromosome 1q21. The aim of the study was to investigate the molecular genetic defect underlying lipoid proteinosis in a consanguineous Pakistani family.

Lipoid proteinosis: a case series from Istanbul

BACKGROUND

Lipoid proteinosis (LP) is a very rare genodermatosis. The literature on LP consists of case reports only. As we have observed 14 LP patients belonging to nine different families in the last 15 years in our practice, we decided to review all reported Turkish LP patients in this 15-year period, and noted 37 diagnosed cases. The reasons for this relatively large number of cases, the clinical features of the patients, and the associations of LP with other clinical conditions are described in this article.

METHODS

Fourteen LP patients followed in our university clinic in Istanbul were scrutinized with regard to their demographic and clinical features. Diagnoses were established using clinical features, with histopathologic confirmation in 13 cases.

RESULTS

All but one of the patients had a history of consanguinity, or at least a marriage of parents from the same village. Typical cutaneous signs of LP and hoarseness of the voice were observed in all patients. Two patients of the same pedigree had insulin-dependent diabetes mellitus (IDDM), two patients from two different pedigrees had short stature, one patient had multinodular toxic goiter, and one patient had celiac disease.

CONCLUSION

LP is not rare in Turkey as consanguineous marriage is still a social problem, especially in some rural areas. The disease is not limited to a particular geographic region in Turkey. Short stature was observed in two cases from two different families, an association not reported previously; the association of LP with IDDM in one pedigree was thought to be coincidental.

Junctional basement membrane anomalies of skin and mucosa in lipoid proteinosis (hyalinosis cutis et mucosae)

BACKGROUND

Excessive basement membrane (BM) deposition in skin and mucosa is characteristic for lipoid proteinosis (LP; hyalinosis cutis et mucosae), an inherited disease caused by extracellular matrix protein 1 (ECM1) mutations. According to ultrastructure there are striking differences between junctional and microvascular BM.

OBJECTIVE

Distinct analysis of the junctional zone in epidermis and oral mucosa, contrasting concentric BM arrays in the microvasculature; evaluation of impact on epithelial histogenesis and differentiation, and specifically on adhesion structures to BM (hemidesmosomes).

METHODS

LP-epithelia were analyzed for alterations in differentiation, BM composition and texture, and hemidesmosomal components by indirect immunofluorescence (IIF), electron microscopy (EM), and immunoelectron microscopy (ImEM).

RESULTS

Most striking was the irregular deposition of collagen IV and VII, BM-laminin, and laminin-5 at the junctional zone, accompanied by lamellate or punctuated structures below BM (IIF), whereas integrin alpha6beta4 and bullous pemphigoid antigen-1 and -2 (BPAG-1/-2) were regularly aligned. Also integrins alpha2beta1 and alpha3beta1 remained restricted to the epidermal basal layer, while the tissue-specific differentiation markers keratin K1/10 (mucosa, additionally K4/13) appeared delayed indicating mild hyperplasia, further confirmed by focal K6/16 expression. Ultrastructure (EM) disclosed abundance of extended basal cell protrusions and junctional aberrations like exfoliating excessive BM material. Hemidesmosomes were complete, but ImEM indicated weakened interactions between their components (BPAG-1, -2, and HD1). Confirming IIF, collagen IV and VII, and laminin-5 appeared extensively scattered, the latter two probably remaining associated.

CONCLUSIONS

Subtle defects in anchorage assembly, spanning the entire BM zone, apparently compromise epithelial-matrix adhesion, which may provoke (mechanical stress-induced) erroneous BM repair.

Extracellular matrix protein 1 inhibits the activity of matrix metalloproteinase 9 through high-affinity protein/protein interactions

Extracellular matrix protein 1 (ECM1), an approximately 85-kDa glycoprotein with broad tissue distribution, harbors mutations in lipoid proteinosis (LP), a heritable disease characterized by reduplication of basement membranes and hyalinization of dermis, associated with neurologic disorders. The mechanisms leading from ECM1 mutations to LP phenotype are unknown. In this study, we explored ECM1 protein-protein interactions utilizing yeast two-hybrid genetic screen of human placental library, which identified nine interacting proteins, including matrix metalloproteinase 9 (MMP9). The interactions were confirmed by beta-galactosidase assay with isolated clones and by co-immunoprecipitation which narrowed the interacting segment in ECM1 to the C-terminal tandem repeat 2 (amino acids 236-361). This peptide segment also inhibited MMP9 activity in a gelatin-based ELISA assay. We propose that ECM1-mediated reduction in MMP9 proteolytic activity may have relevance to pathogenesis of LP.

Vascular anomalies in lipoid proteinosis (hyalinosis cutis et mucosae): basement membrane components and ultrastructure

BACKGROUND

In lipoid proteinosis (LP) vascular anomalies represent severe functional defects caused by excessive deposition of basement membrane (BM)-like matrix, particularly around small subepithelial blood vessels.

OBJECTIVE

Correlation of microvascular anomalies in morphology and ultrastructure with extracellular matrix composition and cell interactions for elucidating vascular involvement in LP-pathophysiology.

METHODS

Biopsies from non-related LP-patients were analyzed by indirect immunofluorescence (IIF), electron microscopy (EM), and immune-EM (ImEM).

RESULTS

In LP-skin and mucosa the thickened vessel walls stained strongly for the BM-components type IV collagen, laminin, perlecan, and nidogen (IIF). Integrin alpha6beta4 was regularly collocated with endothelial surface markers such as PECAM (CD31). Ultrastructure (EM) revealed highly ordered matrix deposits around microvessels, with frequently collapsed lumina, functionally compensated by increased vascular density (histology, IIF). Pericytes were trapped between these concentric BM-layers at varying distances towards the periphery (EM), contrasting their regularly close endothelial apposition. Periodic type IV collagen patterns (ImEM) corroborated the multiple BM-leaflet structure and the lack of a common 'fused' endothelial-pericyte BM, seen normally. Presumptive secretory vesicles, abundant in both cell types, implied an equal contribution to BM-synthesis, but also indicated partial loss of endothelial polarity.

CONCLUSIONS

In LP thickened vessel walls, composed of multiple BM, profoundly alter microvascular properties, also by interference with endothelial-pericyte interactions. The increased microvascular density reflects compensatory restoration for disabled function. Most remarkable was the exaggerated secretory activity (also at luminal surfaces) underlining the regulatory key role of extracellular matrix protein 1 (ECM1; mutated in LP) in export or turnover of all major BM-components.

"Free-floating" desmosomes in lipoid proteinosis: an inherent defect in keratinocyte adhesion?

The classic features of lipoid proteinosis - beadlike papules and hoarseness - result from the accumulation of hyaline material in the mucocutaneous dermis. However, the characteristic manifestation in children - erosive, crusted lesions that lead to scarring - is rarely discussed and poorly understood. Lipoid proteinosis results from mutations in extracellular matrix protein 1, but the function of this protein is largely unknown. We performed ultrastructural studies on lesional epidermis, cultured monolayer keratinocytes, and raft keratinocyte cultures from blistering lesions of a child with lipoid proteinosis. All sections showed the dissociation of relatively intact desmosomes from keratinocytes, with desmosomes that were "free-floating" in the intercellular spaces or attached by thin strands to the cell membrane. These changes were present in serial sections of both tissue and cultured keratinocytes, suggesting this observation to be an inherent feature of keratinocytes devoid of extracellular matrix protein 1, rather than an artifact. Although additional patients should be studied, the diminished appearance of the inner dense plaque - the region of attachment of keratin intermediate filaments to desmosomal proteins - provides preliminary evidence that extracellular matrix protein 1 may participate in attaching keratin intermediate filaments to desmosomal region protein(s).

A novel splice-site mutation in ECM-1 gene in a consanguineous family with lipoid proteinosis

Lipoid proteinosis (LP) (OMIM 247100) is a rare, autosomal recessive disorder. Recent studies have shown that LP is the result of reduced expression of the extracellular matrix protein gene (ECM-1), in which loss-of-function mutations have been described. In the present report, we describe a large consanguineous family with LP. We identified a homozygous splice-site mutation in intron 1 (IVS1 + 1G-->C) in three clinically affected patients. This is the first splice-site mutation reported in LP and is the most 5' of all ECM-1 mutations described thus far. It is predicted to result in the removal of the translation initiation site, thus ablating all three known ECM-1 isoforms (ECM-1a, ECM-1b, and ECM-1c). In addition, we found a novel splicing variant that is not associated with the disease (DQ010946) and results in the generation of a short, prematurely terminating transcript. This case further emphasizes the role of ECM-1 in LP and highlights the unresolved genotype-phenotype correlation in this disease.

Three-dimensional imaging reveals major changes in skin microvasculature in lipoid proteinosis and lichen sclerosus

BACKGROUND

Lipoid proteinosis is a rare autosomal recessive disorder characterized by deposition of hyaline-like material in several organs, including skin. Pathogenic mutations have been found in the extracellular matrix protein 1 gene (ECM1). Recent studies have disclosed that ECM1 is also a target antigen for autoantibodies in patients with the acquired disease, lichen sclerosus. Both conditions have been reported to show abnormalities in dermal blood vessels but these changes have not been fully assessed.

OBJECTIVE

The purpose of this study was to investigate the architecture of the cutaneous microvasculature in lipoid proteinosis and lichen sclerosus to better determine the role of ECM1 in the skin pathology observed in these disorders.

METHODS

Labeling of skin biopsies (lipoid proteinosis, lichen sclerosus and control skin) with antibodies to type IV collagen and laminin-1 and reconstruction of the dermal blood vessels using laser confocal microscopy and computer imaging.

RESULTS

In both lipoid proteinosis and lichen sclerosus there was reduplication of the basement membranes surrounding blood vessel walls. There were enlarged vessels in the mid and deep dermis that were orientated parallel to the dermal-epidermal junction. In addition, the normal capillary loop network in the dermal papillae, as well as the subcutaneous plexus and transverse connecting vessels were lacking in both disorders.

CONCLUSION

This study demonstrates that skin microvasculature is grossly altered when ECM1 is targeted by inherited mutations (lipoid proteinosis) or acquired autoantibodies (lichen sclerosus) and that this glycoprotein appears to have an important role in regulating blood vessel physiology and anatomy in the skin.

Clinical and molecular characterization of lipoid proteinosis in Namaqualand, South Africa

BACKGROUND

Lipoid proteinosis (LiP) is a rare autosomal recessive disorder characterized by a hoarse voice, warty skin infiltration and scarring. Mutations within the extracellular matrix protein 1 (ECM1) gene cause LiP. Since the early 1970s it has been recognized that South Africa has one of the largest groups of LiP patients worldwide, suggesting a probable founder effect. As LiP patients present with considerable clinical variability, this group of patients offers a unique opportunity for genotype-phenotype correlation.

OBJECTIVES

To assess the clinical features and the molecular basis of LiP in patients from the Namaqualand area of the Northern Cape province of South Africa and to examine molecular evidence for a founder effect.

SUBJECTS AND METHODS

The LiP patient cohort consisted of 29 Coloured patients from Namaqualand and a further seven Caucasoid patients from other areas of South Africa. The control group included 100 healthy geographically and ethnically matched individuals from Namaqualand. Samples were collected after informed consent and with ethics committee approval from the University of the Witwatersrand. LiP patients were examined clinically and a structured recording sheet was completed. A brief neurological evaluation was also performed. The LiP founder effect was investigated at the molecular level by ECM1 mutation detection and haplotype analysis.

RESULTS

The most consistent clinical signs for a diagnosis of LiP in this group were a hoarse voice and thickened sublingual frenulum leading to restricted tongue movement. Homozygosity for a nonsense mutation in exon 7 of the ECM1 gene, Q276X, was identified in all patients (Coloured and Caucasoid). Despite this genetic homogeneity, considerable clinical variability in skin presentation and psychiatric involvement was observed. Haplotype analysis using markers from a 9.98-Mb region around the ECM1 locus confirmed the founder effect with a founder core haplotype, 19-Q276X-12 (ND1-ECM1-D1S2343), in all but four LiP-associated alleles (n = 58). A LiP carrier rate of 1 in 9 was observed among the 100 Namaqualand controls, predicting a LiP incidence of 1 in 324 in this community.

CONCLUSIONS

Although several consistent clinical features in LiP patients homozygous for the Q276X mutation in the ECM1 gene were observed, there remains considerable clinical variability. This suggests the action of genetic and environmental modifiers of disease severity. Strong molecular evidence supports a single founder effect for the high prevalence of LiP in South Africans, both Coloured and Caucasoid.

The role of extracellular matrix protein 1 in human skin

Extracellular matrix protein 1 (ECM1) was first identified in 1994 as an 85-kDa glycoprotein secreted by a mouse osteogenic stromal cell line. Subsequently, the human homologue has been found to regulate endochondral bone formation, and to stimulate proliferation of endothelial cells and induce angiogenesis. However, a role for ECM1 in skin physiology and homeostasis has also emerged. Specifically, in 2002, loss-of-function mutations in the ECM1 gene were discovered to be the cause of the rare autosomal recessive genodermatosis, lipoid proteinosis. This inherited disorder is characterized clinically by skin and mucosal infiltration and scarring and histologically by disruption/duplication of basement membrane and widespread deposition of hyaline material in the dermis. Moreover, other recent studies have identified circulating autoantibodies against the ECM1 protein in most patients with lichen sclerosus, a common chronic inflammatory condition that shares some clinicopathological features with lipoid proteinosis. ECM1 thus serves as a target antigen in both an inherited and an acquired skin disorder. Within the epidermis, ECM1 has a role in the control of keratinocyte differentiation. Within the dermis, ECM1 binds to the major heparan sulphate proteoglycan, perlecan. In this way, ECM1 may act as a "biological glue" in the dermis, helping to regulate basement membrane and interstitial collagen fibril macro-assembly and growth factor binding. ECM1 may also have a role in other acquired skin disorders and physiological skin changes including scarring, wound healing and skin ageing, although this remains to be determined.