Development of an immunomagnetic separation-polymerase chain reaction (IMS-PCR) assay specific for Enterocytozoon bieneusi in water samples.

AIMS: Microsporidia have become widely recognized as important human pathogens. Among Microsporidia, Enterocytozoon bieneusi is responsible for severe gastrointestinal disease. To date, no current therapy has been proven effective. Their mode of transmission and environmental occurrence are poorly documented because of the lack of detection methods that are both species-specific and sensitive. In this study, we developed a sensitive and specific molecular method to detect E. bieneusi spores in water samples. METHODS AND RESULTS: The molecular assay combined immunomagnetic separation (IMS) and polymerase chain reaction (PCR) amplification to detect E. bieneusi spores. A comparison was made of IMS magnetic beads coated with two different monoclonal antibodies, one specific for the Encephalitozoon genus that cross-reacts with E. bieneusi and the other specific only for the E. bieneusi species itself. CONCLUSIONS: Immunotech beads coated with the antibody specific for E. bieneusi were found to be the most effective combination. SIGNIFICANCE AND IMPACT OF THE STUDY: The highly specific IMS-PCR assay developed in this study provides a rapid and sensitive means of screening water samples for the presence of E. bieneusi spores.

Rescue of contractile parameters and myocyte hypertrophy in calsequestrin overexpressing myocardium by phospholamban ablation.

Cardiac-specific overexpression of murine cardiac calsequestrin results in depressed cardiac contractile parameters, low Ca(2+)-induced Ca(2+) release from sarcoplasmic reticulum (SR) and cardiac hypertrophy in transgenic mice. To test the hypothesis that inhibition of phospholamban activity may rescue some of these phenotypic alterations, the calsequestrin overexpressing mice were cross-bred with phospholamban-knockout mice. Phospholamban ablation in calsequestrin overexpressing mice led to reversal of the depressed cardiac contractile parameters in Langendorff-perfused hearts or in vivo. This was associated with increases of SR Ca(2+) storage, assessed by caffeine-induced Na(+)-Ca(2+) exchanger currents. The inactivation time of the L-type Ca(2+) current (I(Ca)), which has an inverse correlation with Ca(2+)-induced SR Ca(2+) release, and the relation between the peak current density and half-inactivation time were also normalized, indicating a restoration in the ability of I(Ca) to trigger SR Ca(2+) release. The prolonged action potentials in calsequestrin overexpressing cardiomyocytes also reversed to normal upon phospholamban ablation. Furthermore, ablation of phospholamban restored the expression levels of atrial natriuretic factor and alpha-skeletal actin mRNA as well as ventricular myocyte size. These results indicate that attenuation of phospholamban function may prevent or overcome functional and remodeling defects in hypertrophied hearts.

Structure and expression of the mouse cardiac calsequestrin gene.

Calsequestrin is a sarcoplasmic reticulum protein, which plays a predominant role in diastolic Ca2+-storage in the mammalian heart. The present study was designed to define the gene structure, developmental and tissue specific expression of the murine, cardiac isoform of calsequestrin. Two sets of genomic libraries (lambda phage and PAC) were screened using the mouse cardiac calsequestrin cDNA, and several overlapping clones were isolated. These clones were characterized using restriction enzyme digestion, Southern blotting and partial sequencing. The cardiac calsequestrin gene consists of 11 exons and its 5' flanking region is characterized by the presence of a TATA-like box, muscle specific promoter elements such as 7 E-boxes, 1 MEF-2, 1 MCBF and 1 Repeat (musS) motifs, as well as several muscle non-specific transcriptional elements (AP-2A, NRE1, NRE2, p53, Spel and TFI-IIA). Expression of the cardiac isoform of calsequestrin was first detected on day 11 pre-birth and approached adult levels by day 4 post-birth. Expression of cardiac calsequestrin was also detected in adult fast-twitch skeletal muscle, thyroid, testis and epididymis tissues. This genomic characterization of cardiac calsequestrin may form the basis for further evaluation of its regulatory role in Ca2+ homeostasis and contractility in the murine heart.

Troponin T mRNA and protein isoforms in the human left ventricle: pattern of expression in failing and control hearts.

We and others have previously cloned several cDNAs of human cardiac troponin T (cTnT), demonstrating the multiplicity of cTnT isoforms in the human heart. Four of them named cTnT1, 2, 3 and 4 result from a combinatorial alternative inclusion of 30- and 15-nucleotides in the 5' coding region of the cDNAs. In failing human ventricles, increased expression of cTnT4 has been reported at the protein level. More recent RT-PCR experiments showed increased expression of fetal-type splicing products in the 5' region, one of them corresponding to cTnT1. To clarify this issue, we examined the accumulation of the 4 cTnT mRNA and protein species in left ventricular specimens at the time of heart transplantation, and in control left ventricular samples using RNase protection and Western blotting. In all samples, cTnT3 was the major mRNA isoform, cTnT4 a minor isoform while cTnT1 and cTnT2 mRNAs were present but barely detectable. At the protein level, cTnT3, 4 and 1 were detected with the same relative abundance as that seen at the mRNA level. In addition, we detected a fourth TnT species of very low abundance corresponding either to a skeletal or to a "short" cardiac TNT isoform. Compared to controls, increased levels of cTnT4 mRNA and protein were detected in only half the failing ventricles independently of the cause of failure, suggesting that this increase may not be a general characteristic of left ventricular failure but instead could be related to stress. Unexpectedly, we found a decrease in cTnT1 protein expression in all failing ventricular samples studied, compared to controls.