Telemetric monitoring of blood pressure in freely moving mice: a preliminary study.

This paper describes for the first time the possibility for recording the systolic pressure (SP), diastolic pressure (DP), and the mean arterial pressure (MAP) as well as the heart rate (HR) and locomotor activity (LA) in freely moving mice, using a commercially available telemetry and data acquisition system. The system comprises a new, small radio-telemetry transmitter implanted in the peritoneal cavity, a receiver board placed underneath the home cage, a multiplexer and a computer-based data acquisition system. The signals from the receiver were consolidated by the multiplexer and were stored and analysed by the computer. The telemetered pressure signals (absolute pressure) were corrected automatically for changes in atmospheric pressure measured by an ambient pressure monitor. The effects of implantation on animal behaviour, and, after the animals had recovered, the effects of handling on the SP, DP, MAP and HR were examined. The radio-telemetry system for recording the SP, DP, MAP and HR provides an accurate and reliable method for monitoring the direct effects of handling on SP, DP, MAP and HR. In addition, by using this new blood pressure (BP) transmitter, we maintain that BP measurements in freely moving mice are more efficient, reliable, and less labour-intensive than the measurement techniques described in the literature thus far.

A new method for measurement of blood pressure, heart rate, and activity in the mouse by radiotelemetry.

A simple and reliable means for accurate, chronic measurement of pulsatile blood pressure (BP) from conscious, freely moving laboratory mice was developed and validated. The newly developed device consists of a small (1.9 ml, 3.4 g), fully implantable radiotelemetry transmitter. Initial frequency response tests showed an adequate dynamic response; the average -3-dB point found in five transmitters was 145 +/- 14 (SD) Hz. BP, heart rate, and locomotor activity were recorded from 16 chronically (30-150 days) implanted mice. Mean arterial and pulse pressure, checked at regular intervals, ranged from 90-140 mmHg and from 30-50 mmHg, respectively, throughout the study. Transmitter BP measurements were validated against a Millar 1.4-Fr. transducer-tipped catheter. The mean error of the transmitters for diastolic pressures was +1.1 +/- 6.9 mmHg (n = 7). The error for systolic pressures was, on average, 2.7 +/- 3.9 mmHg larger. This new device accurately monitors BP, heart rate, and locomotor activity in conscious, untethered, freely moving mice living in their home cages for periods of at least 150 days.

GTP gammaS removal of D-600 block of skeletal muscle excitation-contraction coupling.

G proteins interacting with dihydropyridine receptors (DHPR) in transverse tubules (TT) of skeletal muscle may have a role in skeletal excitation-contraction (EC) coupling. The aim of this study was to determine the effects of G protein-specific nucleotides [guanosine 5'-O-(3-thiotriphosphate) (GTP gammaS) and guanosine 5'-O-(2-thiodiphosphate) (GDP betaS)] on the EC coupling mechanism in the presence of D-600, an agent that blocks EC coupling by immobilizing the voltage-sensing subunit of the DHPR in its inactivated state. By use of the mechanically peeled single-fiber preparation from rabbit adductor magnus skeletal muscle, 50 microM GTP gammaS and 500 microM GDP betaS were applied with the fiber in a D-600-induced state of blocked EC coupling. Neither nucleotide served as an independent stimulus for sarcoplasmic reticulum (SR) Ca2+ release when added to the TT polarizing bath under conditions of D-600 block. The presence of GTP gammaS or GDP betaS during a complete EC coupling cycle removed the D-600 block of EC coupling, despite continuous bath D-600. After the nucleotides were washed out, in the continued presence of D-600, the D-600 block of EC coupling was reestablished. In contrast, GTP gammaS added only during the period of TT depolarization under D-600 block did not remove the D-600 block of EC coupling, even though GTP gammaS did stimulate SR Ca2+ release. GTP gammaS had no effect on submaximum (0.5-1.0 mM) caffeine contractures and thus is unlikely to be acting through the Ca2+-induced Ca2+ release mechanism of the SR. These data suggest that the molecular binding site for GTP gammaS and GDP betaS is likely to be in the TT near the DHPR, perhaps on a G protein.

Skeletal muscle excitation-contraction coupling. I. Transverse tubule control of peeled fiber Ca2+-induced Ca2+ release in normal and malignant hyperthermic muscles.

Porcine skeletal muscle fibers were studied to determine if the defect in malignant hyperthermia involves transverse tubule (TT) to sarcoplasmic reticulum (SR) communication. Peeled (mechanically skinned) skeletal muscle fibers from normal and malignant hyperthermia susceptible (MHS) pigs were stimulated with Cl- to ionically depolarize transverse tubules and thereby trigger Ca2+ release from SR. Caffeine was used to directly stimulate the Ca2+-induced Ca2+ release mechanism (CaIR) of the sarcoplasmic reticulum. Calcium released from internal fiber stores was monitored as Ca2+-activated isomeric force generation in the form of tension transients. Cl- -induced tension transients result from a primary component of Ca2+ release which triggers a secondary CaIR component; CaIR and caffeine contractures were eliminated by procaine. The primary component of Cl- -induced SR Ca2+ release was indistinguishable for MHS and normal skeletal peeled fibers at all TT resting and Cl- stimulation conditions. Only the magnitude of the secondary CaIR component was significantly larger in MHS fibers. The [Ca2+] threshold for secondary CaIR was lowered by resting TT depolarization in both normal and MHS fibers. Conditions for resting TT hyperpolarization selectively reduced the magnitude of the secondary CaIR component of MHS fibers, making them indistinguishable from normal.

Voltage dependence of inositol 1,4,5-trisphosphate-induced Ca2+ release in peeled skeletal muscle fibers.

Excitation-contraction coupling in skeletal muscle is known to be under absolute control of plasmalemma voltage, but the steps from transverse (T)-tubule depolarization to Ca2+ release from the sarcoplasmic reticulum have not been elucidated. The effect of changing T-tubule membrane potential on inositol 1,4,5-trisphosphate (InsP3) stimulation of Ca2+ release from the sarcoplasmic reticulum was studied to explore a possible role for InsP3 as a chemical signal in excitation-contraction coupling. InsP3 was microinjected into peeled rabbit skeletal muscle fibers at a pipette concentration of 0.5 microM; Ca2+ release from the sarcoplasmic reticulum was monitored as an isometric tension transient. The response to 0.5 microM InsP3 was significantly larger when T-tubules were in a depolarized state than when they were in a polarized state, and this difference in response was independent of the ionic composition of the bathing solutions or the method for depolarizing the T-tubules. Thus, T-tubule depolarization may sensitize the sarcoplasmic reticulum to a preexisting low concentration of InsP3 and greatly reduce the need for InsP3 production. Plasmalemma voltage control of the stimulatory effects of InsP3 may have relevance for mechanisms in excitable nonmuscle cells.

Inositol trisphosphate stimulates calcium release from peeled skeletal muscle fibers.

The effects of inositol phosphates (tris (InsP3), bis (InsP2), mono (InsP)) on rabbit adductor magnus and soleus muscles were determined using mechanically peeled fibers (sarcolemma removed). Isometric force generation of each fiber was continuously monitored and was used along with 45Ca to detect calcium release from internal fiber stores. All experiments were conducted at a physiological Mg2+ concentration (10(-3) M) of the bathing solutions. The inositol phosphates did not directly activate the contractile apparatus. At bath concentrations of 100-300 microM, only InsP3 was capable of stimulating Ca2+ release. In contrast, 1 microM InsP3 maximally and selectively stimulated Ca2+ release when microinjected into the myofilament lattice. Calcium releasing effects of InsP2 and InsP were manifested at 10 microM when they were microinjected. The end-to-end internal Ca2+ release and subsequent fiber force generation stimulated by the locally applied microinjected InsP3 suggests that the InsP3-induced Ca2+ release mechanism may involve propagation, but not via the Ca2+-induced Ca2+ release, since procaine did not inhibit this response. These findings support the possibility that InsP3 plays a role in skeletal muscle excitation-contraction coupling.