We report on a functional human model to evaluate multi-organ toxicity in a 4-organ system under continuous flow conditions in a serum-free defined medium utilizing a pumpless platform for 14 days. Computer simulations of the platform established flow rates and resultant shear stress within accepted ranges. Viability of the system was demonstrated for 14 days as well as functional activity of cardiac, muscle, neuronal and liver modules. The pharmacological relevance of the integrated modules were evaluated for their response at 7 days to 5 drugs with known side effects after a 48 hour drug treatment regime. The results of all drug treatments were in general agreement with published toxicity results from human and animal data. The presented phenotypic culture model exhibits a multi-organ toxicity response, representing the next generation of in vitro systems, and constitutes a step towards an in vitro “human-on-a-chip” assay for systemic toxicity screening.
Apoptotic cell death is an essential process in the development of the central nervous system and in the pathogenesis of its degenerative diseases. Efflux of K þ and Cl À ions leads to the shrinkage of the apoptotic cell and facilitates the activation of caspases. Here, we present electrophysiological and immunocytochemical evidences for the activation of a voltage-dependent anion channel (VDAC) in the plasma membrane of neurons undergoing apoptosis. Anti-VDAC antibodies blocked the channel and inhibited the apoptotic process. In nonapoptotic cells, plasma membrane VDAC1 protein can function as a NADH (-ferricyanide) reductase. Opening of VDAC channels in apoptotic cells was associated with an increase in this activity, which was partly blocked by VDAC antibodies. Hence, it appears that there might be a dual role for this protein in the plasma membrane: (1) maintenance of redox homeostasis in normal cells and (2) promotion of anion efflux in apoptotic cells.
In vitro human skeletal muscle systems are valuable tools for the study of human muscular development, disease and treatment. However, published in vitro human muscle systems have so far only demonstrated limited differentiation capacities. Advanced differentiation features such as cross-striations and contractility have only been observed in co-cultures with motoneurons. Furthermore, it is commonly regarded that cultured human myotubes do not spontaneously contract, and any contraction has been considered to originate from innervation. This study developed a serum-free culture system in which human skeletal myotubes demonstrated advanced differentiation. Characterization by immunocytochemistry, electrophysiology and analysis of contractile function revealed these major features: A) well defined sarcomeric development, as demonstrated by the presence of cross-striations. B) finely developed excitation-contraction coupling apparatus characterized by the close apposition of dihydropyridine receptors on T-tubules and Ryanodine receptors on sarcoplasmic reticulum membranes. C) spontaneous and electrically controlled contractility. This report not only demonstrates an improved level of differentiation of cultured human skeletal myotubes, but also provides the first published evidence that such myotubes are capable of spontaneous contraction. Use of this functional in vitro human skeletal muscle system would advance studies concerning human skeletal muscle development and physiology, as well as muscle-related disease and therapy.
One of the earliest morphological changes occurring in apoptosis is cell shrinkage associated with an increased efflux of K(+) and Cl(-) ions. Block of K(+) or Cl(-) channels prevents cell shrinkage and death. Recently, we found evidences for the activation of a voltage-dependent anion channel in the plasma membrane (pl-VDAC) of a hippocampal cell line undergoing apoptosis. Nothing is known on pl-VDAC in apoptotic cell death of neural cells at different stages of differentiation. We have addressed this issue in primary cultures of differentiated hippocampal neurons and embryonic neural stem cells (NSCs). In control hippocampal neurons, pl-VDAC is closed but acts as an NADH-ferricyanide reductase, while in apoptotic neurons, pl-VDAC is opened and the enzymatic activity is increased. Anti-VDAC antibodies block pl-VDAC and prevent apoptosis, as well as the increase in enzymatic activity. Conversely, in NSCs, pl-VDAC is scarcely seen and there is no NADH-ferricyanide reductase activity. In agreement, anti-VDAC antibodies do not affect the apoptotic process. Instead, we find activation of a Na(+) channel that has low voltage dependency, a conductance of 26 pS, and is blocked by amiloride, which also prevents apoptosis. Thus, it appears that activation of pl-VDAC during apoptosis is a critical event in differentiated neurons, but not in NSCs.
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