Isabelle Dubus

Beta-adrenergic agonists stimulate the synthesis of noncontractile but not contractile proteins in cultured myocytes isolated from adult rat heart.

The effect of catecholamines on adult myocardial protein synthetic activity was studied by use of an experimental model of isolated adult rat cardiac myocytes maintained in culture for 1-6 days. During this period, the majority of myocytes retained their rod-shaped morphology, but the cell number decreased progressively (50% of the initial density after 2 days in culture). Between day 1 and day 3 in culture, the specific synthetic activities of total proteins and of electrophoretically purified myosin heavy chain and actin ([14C] phenylalanine incorporation into protein, in disintegrations per minute per microgram protein) decreased (-19%,-32%, and -73%, respectively). Addition of isoproterenol or norepinephrine (10 nM) from the onset of the culture for 3 days increased the specific activity of both total and noncontractile proteins (greater than 20%) but had no effect on the specific activity of myosin heavy chain and actin when compared with 3-day cultured control cells. beta-Adrenergic receptors are specifically required to mediate this increase in total protein synthesis. This finding was demonstrated by the inhibitory effects of propranolol; neither prazosin nor yohimbine showed any effect. The pattern of synthesized protein during adrenergic stimulation was qualitatively evaluated by use of [35S]methionine incorporation and gel electrophoresis. The general pattern of labeled proteins did not differ significantly from that of control cells; this occurrence suggests that isoproterenol harmoniously stimulates the synthesis of noncontractile proteins. These findings demonstrate that low doses of beta-adrenergic agonists have an anabolic effect on adult cardiac quiescent myocytes that do not affect the major contractile proteins. Regulation of myofibrillar protein synthesis may be more dependent on myocyte contractile activity.

The –308 G/A Tumor Necrosis Factor-α Gene Dimorphism: A Risk Factor for Unstable Angina

Abstract Since the inflammatory cytokine tumor necrosis factorα (TNF-α) may play a major role in the pathophysiology of acute coronary syndromes, 299 consecutive male patients hospitalized for coronary artery disease (i.e., lumen lost ≥50%) were genotyped for the functional −308G/A TNF-α polymorphism using restriction fragment length polymorphism method, in order to evaluate its potential association with the risk of unstable angina and/or myocardial infarction. A higher frequency of carriers of the A allele was observed in patients with unstable angina (n = 58) when compared to control patients with stable angina (n = 95) (39.66% vs. 23.16% respectively, p = 0.029, odds ratio = 2.2) but not in patients with myocardial infarction (n = 146) (23.97% vs. 23.16%, p = NS). Furthermore, we evidenced an interaction of the polymorphism studied with body mass index in patients with unstable angina. Thus, when stratified analysis was performed, results in patients with a body mass index ≤ 27 showed a more striking association between A allele carriage frequency and unstable angina (p = 0.012, odds ratio = 3.0). These results suggest the crucial role of TNF-α in the mechanisms responsible for unstable angina in accordance with the concept of vulnerable plaque. On the other hand, mechanisms controlling myocardial infarction appear more complex and heterogeneous.

Cadmium induces direct morphological changes in mesangial cell culture

The cadmium produced by industrial and agricultural practice represents a major environmental pollutant which may induce severe damage, especially in the kidney where cadmium accumulates. While cadmium is known to severely impair renal tubular functions, glomerular structures are also potential targets. The present study investigated the effects of cadmium on glomerular mesangial cell cultures after short- and long-term exposures, requiring for each endpoint specific culture conditions. After 30 min exposure to 1 microM CdCl(2), used as non-lethal concentration, 0.14 ng/microg proteins of cadmium was internalized by the cells as evaluated by atomic emision spectrometry and induced a significant, cell surface reduction (8.9+/-1.9%). These morphological changes could be correlated to smooth muscle alpha-actin disorganization, without quantitative change in its protein expression level as evaluated by Western-blot and Northern-blot analysis (SMAmRNA/28sRNA, 1.78 CdCl(2) vs. 1.42 control). For longer exposure times, in complex medium, cadmium uptake was efficient (0.36 ng/microg proteins) and induced changes in the actin cytoskeleton with no loss of cell membrane integrity. This study suggests that cultured mesangial cells provide an alternative model to study the effect of cadmium, and underlines the importance of using well-defined conditions to study further intracellular mechanisms.

Contractile protein gene expression in serum-free cultured adult rat cardiac myocytes.

The effects of two adhesion substrates (serum and laminin) and time in culture on the expression of genes encoding myosin heavy chain (MHC) isoforms and α-skeletal actin were analysed in myocytes isolated from adult rat heart and maintained in serum-free culture. Relative messenger ribonucleic acid (mRNA) abundances were quantitated by dot-blot analysis. Gene expression was not influenced by the substrate used. Time in culture induced a decrease in total mRNA abundance and an up-regulation of β-MHC and α-skeletal actin genes. It is proposed that atrophy of adult myocytes is associated with a pattern of gene expression similar to the fetal program.

Pyrimidine nucleotide synthesis is preferentially supplied by exogenous cytidine in adult rat cultured cardiomyocytes.

The metabolism of pyrimidine nucleotides was studied in non-contracting myocytes isolated from adult rat hearts and compared to that observed in freshly prepared myocardium. The myocytes were cultured for up to 96 hrs in a commercial medium containing 50 microM cytidine, uridine, adenosine and adenine; 20 microM guanosine, thymidine and D-ribose; and 5 microM hypoxanthine, xanthine, guanine, thymine and uracil. Nucleotide pool sizes were measured by HPLC. Nucleotide and RNA labelling were followed by incorporation of [U-14C]-cytidine or [U-14C]-uridine added in trace amounts to the medium. The adenine nucleotide pool was 2.4-fold larger than in situ after 7 hrs of incubation and then returned to values 30% higher than that found in the myocardium after 25 hrs. Cytosine and uracil nucleotide pools after 25 hrs of culture were respectively 2 and 4-fold larger than in situ and remained at these levels thereafter. Intracellular cytidylate and uridylate equilibrated very rapidly with exogenous [U-14C]-cytidine but not with [U-14C]-uridine. We conclude that, under the experimental conditions used here, the synthesis of pyrimidine nucleotides in isolated myocytes is mainly supplied by exogenous nucleosides. Furthermore, extracellular cytidine is rapidly converted to both uracil and cytosine nucleotides while uridine serves only as the precursor for uracil nucleotide synthesis.