A superfusion system to study border zones in confluent cultures of neonatal rat heart cells.

We present a new experimental method to study intracellular ion regulation in cultured cardiomyocytes at a border zone separating two different and distinct environments. Our system uses a dual-flow superfusion chamber to produce two different but adjacent environments over a monolayer of cardiomyocytes. Fluorescent microscopy of fluorescein showed that the transition between the two environments was nearly linear and was 220-320 micron wide depending on fluid viscosity and velocity. We superfused cultured monolayers on one side with a solution at pH 6.5 and on the other side with a solution at pH 7.4. We observed a sharply demarcated difference in intracellular pH (pHi) between the two halves of the cell monolayer as measured with the fluorescent pHi indicator carboxy-seminaphthorhodafluor-1. The demarcation of pHi corresponded well with the demarcation of the border measured with fluorescein. We conclude that our superfusion system will facilitate the study of intercellular communication and interactions across boundaries of cardiac tissue where different ionic or metabolic conditions are present, for example, between ischemic and nonischemic myocardium.

Phosphorylation-dependent power output of transgenic flies: an integrated study.

We examine how the structure and function of indirect flight muscle (IFM) and the entire flight system of Drosophila melanogaster are affected by phosphorylation of the myosin regulatory light chain (MLC2). This integrated study uses site-directed mutagenesis to examine the relationship between removal of the myosin light chain kinase (MLCK) phosphorylation site, in vivo function of the flight system (flight tests, wing kinematics, metabolism, power output), isolated IFM fiber mechanics, MLC2 isoform pattern, and sarcomeric ultrastructure. The MLC2 mutants exhibit graded impairment of flight ability that correlates with a reduction in both IFM and flight system power output and a reduction in the constitutive level of MLC2 phosphorylation. The MLC2 mutants have wild-type IFM sarcomere and cross-bridge structures, ruling out obvious changes in the ultrastructure as the cause of the reduced performance. We describe a viscoelastic model of cross-bridge dynamics based on sinusoidal length perturbation analysis (Nyquist plots) of skinned IFM fibers. The sinusoidal analysis suggests the high power output of Drosophila IFM required for flight results from a phosphorylation-dependent recruitment of power-generating cross-bridges rather than a change in kinetics of the power generating step. The reduction in cross-bridge number appears to affect the way mutant flies generate flight forces of sufficient magnitude to keep them airborne. In two MLC2 mutant strains that exhibit a reduced IFM power output, flies appear to compensate by lowering wingbeat frequency and by elevating wingstroke amplitude (and presumably muscle strain). This behavioral alteration is not seen in another mutant strain in which the power output and estimated number of recruited cross-bridges is similar to that of wild type.

Fourier analysis of wing beat signals: assessing the effects of genetic alterations of flight muscle structure in Diptera.

A method for determining and analyzing the wing beat frequency in Diptera is presented. This method uses an optical tachometer to measure Diptera wing movement during flight. The resulting signal from the optical measurement is analyzed using a Fast Fourier Transform (FFT) technique, and the dominant frequency peak in the Fourier spectrum is selected as the wing beat frequency. Also described is a method for determining quantitatively the degree of variability of the wing beat frequency about the dominant frequency. This method is based on determination of a quantity called the Hindex, which is derived using data from the FFT analysis. Calculation of the H index allows computer-based selection of the most suitable segment of recorded data for determination of the representative wing beat frequency. Experimental data suggest that the H index can also prove useful in examining wing beat frequency variability in Diptera whose flight muscle structure has been genetically altered. Examples from Drosophila indirect flight muscle studies as well as examples of artificial data are presented to illustrate the method. This method fulfills a need for a standardized method for determining wing beat frequencies and examining wing beat frequency variability in insects whose flight muscles have been altered by protein engineering methods.