Relationship of serum neutral endopeptidase E.C.3.4.24.11 activity to alcohol consumption.

Neutral endopeptidase (NEP) is an ubiquitous enzyme that inactivates numerous endogenous peptides in the brain, kidney, and lung in vivo. The origin of the circulating soluble form and its determinants are largely unknown. The relationships of smoking habits and alcohol consumption to serum NEP activity have been explored in a longitudinal epidemiological study conducted in 204 Lorraine coal miners. At both surveys, 4 years apart, NEP activity was significantly related to alcohol consumption (in grams/day) reported by questionnaire, with correlation coefficients of 0.26 (p = 0.001) in 1990 and 0.23 (p = 0.001) in 1994. The correlations of gamma-glutamyltransferase to NEP activity were even stronger with correlation coefficients of 0.71 (p = 0.0001) in 1990 and 0.79 (p = 0.0001) in 1994. Longitudinally, the change in NEP activity between the first and the second surveys was significantly correlated with change in alcohol consumption (r = to 0.18, p = 0.02) and with change in gamma-glutamyltransferase level (r = 0.60, p = 0.0001). Serum NEP activity was unrelated to smoking habits. Results support the hypothesis of a causal role of alcohol on serum NEP activity.

Expression of 72-kDa gelatinase (MMP-2), collagenase (MMP-1), and tissue metalloproteinase inhibitor (TIMP) in primary pig skin fibroblast cultures derived from radiation-induced skin fibrosis.

In addition to producing matrix degradation for normal tissue remodeling and repair, matrix metalloproteinases (MMPs) are also involved in various pathologic processes. MMPs and the tissue inhibitor of MMPs (TIMP) were investigated in primary cultures of pig fibroblasts from radiation-induced dermal fibrosis and compared to normal dermal fibroblasts. The free gelatinolytic, collagenolytic, and caseinolytic activities secreted into the culture medium were evaluated against specific 3H denatured collagen type I, native helical collagen, and casein alpha, respectively. The 72- and 68-kilodalton (kDa) forms of type IV collagenase were investigated by protease zymography and quantified by semi-automated image analysis. Transcription of the interstitial collagenase (MMP-1) and TIMP genes was studied by Northern hybridization analysis. Results revealed that in fibrotic fibroblasts, the amount of MMP-1 mRNA was greatly reduced to undetectable levels whereas the amount of TIMP mRNA was increased fourfold compared to controls. Functional assays using specific 3H substrates demonstrated an overall decrease in free MMP activities. Concomitantly, catheptic collagenolytic activity decreased in fibrotic fibroblast extracts compared to controls. These results indicate that in addition to accumulating large amounts of collagen, proteoglycans, and fibronectin, pig fibroblasts from radiation-induced dermal fibrosis also promote connective tissue matrix formation by repressing MMP-1 and stimulating TIMP expression at the transcriptional level, and by reducing overall free MMP and catheptic collagenolytic activities at the post-transcriptional level. In contrast, enzymography assays and automated image analysis demonstrated no significant change in the 72-kDa type IV collagenase activity of fibrotic pig skin fibroblasts. This opposite regulation of 72-kDa collagenase type IV to that of MMP-1 seems to indicate that it has a specific role in remodeling the extracellular matrix during wound healing, fibrogenesis, and angiogenesis.

Biological markers as indicators of exposure and pneumoconiotic risk: prospective study.

This research is designed to evaluate a number of biological markers to estimate harmful exposure on coal miners from different mining regions in France and to relate the outcome to differences in prevalence of coal worker pneumoconiosis (CWP) between these regions. Eight epidemiological groups of active and ex-miners (smokers and non-smokers) have been selected in the French collieries (North, Lorraine and Provence) according to their occupational and pneumoconiotic status. The following biomarkers have been evaluated: cellularity of sputum, elementary analysis of particles in TEM/EDAX, plasma neutral metalloendo-peptidase elastase type (NMEP), leucocyte elastase (HLE), fibronectin (FN) and elastin peptides. Pulmonary alveolitis, expressed by sputum cellularity, is different between active workers groups but not related to the general background of pneumoconiosis prevalence in the French collieries. In the plasma parameters, fibronectin, HLE and NMEP significantly increased in all groups of coal mine workers as compared to the control group, except for fibronectin parameter in Lorraine collierie. The degree of increase of these parameters allow us to discriminate the different groups and suggest that plasma FN, HLE and NMEP may be considered as biological markers of chronic inhalation of coal mine dust particles. The decrease of elastin peptides level in the Lorraine group alone suggests a specific alteration of elastin metabolism. These parameters were not related to the development of pneumoconiosis and its degree of severity.

Fibronectin and collagen gene expression during in vitro ageing of pig skin fibroblasts.

The fibronectin, collagen type I, and collagen type III genes code for three major proteins of the cell matrix. The age-related alterations in their expression were measured during the in vitro lifespan of pig skin fibroblasts. We observed changes in the transcription rate of these specific genes during ageing. The levels of fibronectin and type III collagen mRNA rose markedly during the senescence phase. The level of collagen type I mRNA decreased during cell ageing, while that of beta-actin did not change. As regards proteins, we observed a sharp increase in the secreted noncollagenous proteins and in the total proteins of the cell layer during senescence. On the contrary, the secretion of the collagenous proteins decreased during senescence. Moreover, most of the newly synthesized molecules of collagen were immediately degraded in the cells, before their extracellular secretion. The terminal phenotype of pig senescent cells was therefore characterized by overexpression of fibronectin and type III collagen genes and reduced expression of the type I collagen gene. Surprisingly, for fibronectin and type III collagen, that terminal phenotype resembled the one normally found in the fibroblasts during the processes of tissue repair, cicatrization, and development.

Collagen synthesis and deposition in cultured fibroblasts from subcutaneous radiation-induced fibrosis. Modification as a function of cell aging.

Acute local gamma-irradiation of porcine skin induces, as in human skin, extensive mutilating sclerosis, characterized by continuous expansion of the fibrosis invading the adjacent muscle and by accumulation of extracellular matrix macromolecules. Collagen synthesis, content, and types were studied by measuring the incorporation of the radiolabeled precursor [3H]-proline into confluent primary cultures and subcultures of porcine fibroblasts obtained from normal and irradiated fibrotic dermis. A significant increase in collagen biosynthesis and deposition, with a preferential enhancement of type III collagen, was observed in primary cultures of fibrotic fibroblasts when compared to those of normal dermis. However, the percentage (36%) of neosynthesized collagen in relation to the total neosynthesized non-collagenous and collagenous proteins remained unchanged. In subcultures of normal cells, collagen synthesis and content remained constant until about the 10th passage and then progressively declined until death of the fibroblasts, at around the 15th passage. During the senescence phase, normal fibroblasts acquired the capacity to synthesize higher levels of non-collagenous proteins. On the contrary, collagen synthesis and content diminished in subcultures of fibrosis-induced fibroblasts from the second passage, and then progressively declined as a function of aging; particularly the ratio of type III to type I collagen returned to normal values from the second passage. Moreover, these fibroblasts did not become senescent, persisted in synthesizing low levels of collagen, and acquired later (around the 40th passage) a higher capacity to synthesize non-collagenous proteins. These results demonstrate that primary cultures of porcine fibroblasts obtained from normal or radiation-induced fibrotic dermis reproduce the in vivo situation. The results strongly suggest that: 1) the modification of collagen synthesis, content, and types observed in primary cultures of fibroblasts might be due to factors causing long-lasting changes in phenotypic expression and/in stimulation of the expansion of some fibroblast clones engaged in the accelerated synthesis of extracellular matrix macromolecules, such as collagen or non-collagenous proteins. 2) the rapid decrease in this active capacity to synthesize and accumulate collagen, observed in subcultures of fibrosis-induced fibroblasts, might be related to the loss of some activation factors or to the dedifferentiation of the cells. 3) the switch from collagen to non-collagenous protein synthesis during later subcultures of fibroblasts obtained from radiation-induced fibrosis, might be due to molecular modification at the transcriptional or DNA level.

Heparin fragments modulate the collagen phenotype of fibroblasts from radiation-induced subcutaneous fibrosis.

Acute local gamma irradiation of porcine skin induces, as in human skin, an extensive and mutilating sclerosis characterized by continuous expansion of the fibrosis invading the adjacent muscle and by accumulation of the macromolecular components of the extracellular matrix. Collagen synthesis, content, and types were studied in the presence of heparin fragments (100 micrograms/10(6) cells) in the culture medium, by measuring the incorporation of the radiolabeled precursor [3H]proline into confluent primary cultures of porcine fibroblasts obtained from normal and irradiated fibrotic dermis. Enhancement in collagen biosynthesis and deposition and preferential increase in collagen type III synthesis were observed in fibrotic fibroblast cultures when compared to those in normal dermis fibroblasts. The total collagen synthesis and the rate of collagen hydroxylation appear unmodified by heparin fragments both in normal and in fibrotic fibroblast cultures. But heparin fragments induce a 10- and 2-fold decrease, respectively, in collagen type III and type V syntheses by fibrosis fibroblasts. As only minor effects upon collagen type III and V are observed in cultures of normal dermis fibroblasts, these results highly suggest that heparin fragments are capable of specifically modulating the collagen phenotype of fibroblasts derived from radiation-induced dermis fibrosis and thus are able to regulate the fibrotic process.