MAB2499 Sigma-AldrichAnti-Fibrillin-1 Antibody, CT, clone 69

We recently demonstrated aberrant staining of fibrillin-1 in lung tissue specimens with emphysematous lesions. In this study, we have extended this observation by an elaborate analysis of the elastic fibre. Using domain-specific antibodies to fibrillin-1, and to other elastin fibre-associated molecules, lung tissue derived from patients without obvious clinical emphysema, but harbouring various degrees of microscopical emphysematous lesions, was analysed. In addition, the fibrillin-regulated growth factor TGF-beta was studied. Electron microscopy and biochemical analysis of desmosine (a marker for elastin) were also performed. Results were compared with lung tissue derived from patients with clinical emphysema. Domain-specific antibodies recognizing the C-terminal, N-terminal, and middle part of fibrillin-1 showed aberrant staining patterns associated with increasing degrees of microscopical emphysema. Staining for elastin, emilin-1, and fibulin-2 was, however, not aberrant. TGF-beta staining was markedly increased. On the electron microscopic, but not light microscopical, level, initial elastic fibre degradation was noticed in specimens with microscopical emphysema. Lung specimens from patients with clinical emphysema also displayed fragmented fibrillin-1 staining and, in addition, displayed extensive degradation of the elastic fibre. The results suggest that fibrillin-1 anomalies and TGF-beta overexpression are associated with initial events occurring during the emphysematous process. Based on these and other data, a mechanism for emphysematogenesis is proposed.

OBJECTIVES: Transforming growth factor-beta (TGF-beta), a potent regulator of wound healing and scar formation, is thought to have a key role in the response to arterial injury. Latent TGF-beta binding proteins (LTBPs), members of the fibrillin superfamily, govern TGF-beta1 release, targeting and activation in vitro and also play a role as structural components of fibrillin-rich microfibrils. Despite the potential of LTBPs to modulate the response to arterial injury through either or both of these mechanisms, as yet their expression and function in the injured vasculature remain poorly defined. METHODS: In this study, a porcine model of coronary angioplasty was used to investigate LTBP-1 and LTBP-2 synthesis and their association with TGF-beta 1 and fibrillin-1. RESULTS: After angioplasty, increased LTBP-1 and LTBP-2 immunostaining was detected in a similar distribution to increased TGF-beta 1 expression in the neointima and in the neoadventitia. Overnight organ cultures revealed the formation of large latent TGF-beta 1 complexes containing LTBP-1. Increased LTBP-1 proteolysis after arterial injury correlated with increased active and latent TGF-beta levels. LTBP-2 synthesis increased in response to arterial injury but was neither present in large latent complexes nor proteolytically processed. LTBP-1 and LTBP-2 both co-localised to fibrillin-rich fibrillar structures in the neointima and adventitia. CONCLUSIONS: These data suggest that LTBP-1 may have a TGF-beta 1 binding role in the arterial response to injury, and that LTBP-1 and LTBP-2 may have a structural role in association with microfibrils within the developing neointimal lesion. LTBP-1 proteolysis is potentially an important regulatory step for TGF-beta activation in the vasculature and inhibition of proteolysis could represent a novel therapeutic modality for controlling the arterial injury response.

The molecular basis for Marfan's syndrome (MS), a heritable disorder of connective tissue, is now known to reside in mutations in FBN1, the gene for fibrillin-1. Classic phenotypic manifestations of MS include several skeletal abnormalities associated primarily with overgrowth of long bones. As a first step towards understanding how mutations in FBN1 result in skeletal abnormalities, the developmental expression of fibrillin-1 (Fib-1) in human skeletal tissues is documented using immunohistochemistry and monoclonal antibodies demonstrated here to be specific for Fib-1. At around 10-11 weeks of fetal gestation, Fib-1 is limited in tissue distribution to the loose connective tissue surrounding skeletal muscle and tendon in developing limbs. By 16 weeks, Fib-1 is widely expressed in developing limbs and digits, especially in the perichondrium, but it is apparently absent within cartilage matrix. Fib-1 appears as a loose meshwork of fibers within cartilage matrix by 20 weeks of fetal gestation. Until early adolescence, Fib-1 forms loose bundles of microfibrils within cartilage. However, by late adolescence, broad banded fibers composed of Fib-1 are found accumulated pericellularly within cartilage. Because these fibers can be extracted from cartilage using dissociative conditions, we postulate that they are laterally packed and crosslinked microfibrils. On the basis of these findings, we suggest that the growth-regulating function of Fib-1 may reside persistently within the perichondrium. In addition, the accumulation of special laterally crosslinked Fib-1 microfibrils around chondrocytes during late adolescence suggests that growth-regulating activities may also be performed by Fib-1 at these sites.