The effects of Ins2(Akita) diabetes and chronic angiotensin II infusion on cystometric properties in mice.

AIMS: Diabetes is associated with both dysfunction of the lower urinary tract (LUT) and overactivity of the renin-angiotensin system (RAS). Although it is well known that the RAS affects normal LUT function, very little is known about RAS effects on the diabetic LUT. Accordingly, we investigated the effects of chronic angiotensin II (AngII) treatment on the LUT in a model of type 1 diabetes. METHODS: Ins2(Akita) diabetic mice (20 weeks old) and their age-matched background controls underwent conscious cystometric evaluation after 4 weeks of chronic AngII treatment (700 ng/kg/min by osmotic pump) or vehicle (saline). RESULTS: Diabetic mice had compensated LUT function with bladder hypertrophy. Specifically, micturition volume, residual volume, and bladder capacity were all increased, while voiding efficiency and pressure generation were unchanged as bladder mass, contraction duration, and phasic urethral function were increased. AngII significantly increased voiding efficiency and peak voiding pressure and decreased phasic frequency irrespective of diabetic state and, in diabetic but not normoglycemic control mice, significantly decreased residual volume and increased contraction duration and nonphasic contraction duration. CONCLUSIONS: The Ins2(Akita) diabetic mice had compensated LUT function at 20 weeks of age. Even under these conditions, AngII had beneficial effects on LUT function, resulting in increased voiding efficiency. Future studies should therefore be conducted to determine whether AngII can rescue the decompensated LUT function occurring in end-stage diabetic uropathy.

Sprouting of substance P-expressing primary afferent central terminals and spinal micturition reflex NK1 receptor dependence after spinal cord injury.

The primary afferent neurotransmitter triggering the spinal micturition reflex after complete spinal cord injury (SCI) in the rat is unknown. Substance P detected immunohistochemically in the sacral parasympathetic nucleus was significantly higher in 12 SCI rats than in 12 spinally intact rats (P = 0.008), suggesting substance P as a plausible candidate for the primary afferent neurotransmitter. The effects of the tachykinin NK1 receptor antagonist L-733060 on the spinal micturition reflex were then determined by performing conscious cystometry in an additional 14 intact rats and 14 SCI rats with L-733060 (0.1-100 microg) administered intrathecally at L6-S1. L-733060 was without effect in intact rats, but blocked the spinal micturition reflex in 10 of 14 SCI rats and increased the intermicturition interval in 2 of 4 others at doses ranging from 10 to 100 microg. Both phasic and nonphasic voiding contractions, differentiated according to the presence of phasic external urethral sphincter (EUS) activity, were present in most SCI rats. Both types of contractions were blocked by high doses of L-733060. Interestingly, there was a relative decline in phasic voiding contractions at high doses as well as a decline in contraction amplitude in nonphasic voiding contractions. In other respects, cystometric variables were largely unaffected in either spinally intact or SCI rats. L-733060 did not affect tonic EUS activity at any dose except when the spinal micturition reflex was blocked and tonic activity was consequently lost. These experiments show that tachykinin action at spinal NK1 receptors plays a major role in the spinal micturition reflex in SCI rats.

Voltage-dependent potassium currents of urethral afferent neurons in diabetes mellitus.

Urethra-to-bladder and urethra-to-urethra reflexes appear to be important for coordination of proper voiding. Diabetes mellitus (DM) is known to result in afferent neuropathy. Neuropathic alterations in electrophysiological properties of urethral afferent neurons may therefore contribute to voiding dysfunction seen in diabetes mellitus. Accordingly, we studied urethral afferent neuronal somata in streptozotocin-induced DM or age-matched vehicle controls by whole-cell patch clamp at 5- or 10-week time points. One week prior to study, Fast Blue was injected into the proximal urethra to label urethral afferent neurons. A previously undescribed diminution of afferent neuronal voltage-dependent potassium currents was a prominent feature of urethral afferent neuropathy in DM, acting to increase neuronal excitability. Thus, unlike bladder afferent neurons, urethral afferent neurons may be hyperexcitable well into DM progression.

Cardiac troponin T forms a tetramer in vitro.

Cardiac troponin T (cTnT) is a myofibrillar protein essential for calcium-dependent contraction. This property has led to functional studies of developmentally expressed cTnT isoforms and mutants identified in patients with hypertrophic cardiomyopathy. The release of cTnT into the serum following myocardial infarction has led to the development of antibody-based assays for measuring cTnT serum concentration. We examined the behavior of cTnT in solution. Recombinant human cTnT3, the dominant isoform in the adult human heart, was used. The protein was pure and functional, as demonstrated by SDS-PAGE and surface plasmon resonance. cTnT3 was found to bind specifically and in a concentration-dependent manner to cTnC. Routine size exclusion chromatography suggested a higher-than-expected MW for cTnT. Using analytical ultracentrifugation, we found cTnT3 in solution to be mainly in the form of a tightly bound tetramer at concentrations as low as 4 micromol/L. Our sedimentation velocity and transmission electron microscopy results indicate that the tetramer's shape is elongated rather than globular. CTnT's self-association in solution is an important consideration in the design and interpretation of experiments with the aim of understanding the biochemical and biophysical properties of cTnT, its isoforms, and its mutants.

Complement factor 1 inhibitor improves cardiopulmonary function in neonatal cardiopulmonary bypass.

BACKGROUND: The inflammatory insult associated with cardiopulmonary bypass (CPB) continues to result in morbidity for neonates undergoing complex repair of congenital cardiac defects. Complement and contact activation are important mediating processes involved in this injury. Complement factor 1 esterase inhibitor (C1-inh), a natural inhibitor of complement, kallikrein, and coagulation pathways, may be decreased in children undergoing cardiac operations requiring CPB. We tested the hypothesis that C1-inh supplementation will ameliorate the cardiac and pulmonary dysfunction in a model of neonatal CPB. METHODS: Fifty-two neonatal pigs were randomly assigned to receive 0 IU (n = 22), 500 IU (n = 15), 1,000 IU (n = 8), or 1,500 IU (n = 7) of C1-inh. Doses were delivered 5 minutes before starting 90 minutes of normothermic CPB. Pulmonary and cardiovascular measures were taken before and 5, 30, and 60 minutes after CPB. RESULTS: Five animals did not survive CPB. The C1-inh concentration post-CPB increased monotonically with increasing dose (p < 0.001). Weight gain was significantly less in the 1,500 IU group (0.24 +/- 0.10 kg versus 0.38 +/- 0.09 kg, p = 0.001). Dynamic compliance increased with C1-inh dose from 0 to 500 IU by 23% +/- 4% (p < 0.001), but the increase leveled off at the higher doses. Alveolar-arterial O2 gradient decreased with C1-inh dose (p = 0.009). Time derivative of left ventricular pressure (dP/dt(max)) increased significantly with increasing dose (p = 0.016). At the highest dose of C1-inh, the time constant of isovolumic relaxation was increased (p = 0.018). CONCLUSIONS: The C1-inh supplementation results in improved pulmonary and systolic cardiac function in a model of neonatal CPB. The negative effect on diastolic function requires further investigation.

Development and cardiac contractility: cardiac troponin T isoforms and cytosolic calcium in rabbit.

Cardiac contractility depends on calcium sensitivity of the myofilaments and cytosolic free calcium concentration ([Ca(2+)](i)) during activation. During development, the cardiac troponin T isoform cTnT(1) is replaced by shorter cTnT isoforms, including cTnT(4), and changes occur in other myofibrillar proteins and in calcium regulation. We expressed rabbit recombinant (r)cTnT(1) and rcTnT(4) in Spodoptera frugiperda cells and determined their effect on calcium binding to TnC in solution and on the calcium sensitivity of myofilaments in skinned rabbit ventricular fibers in vitro. We measured [Ca(2+)](i) and L-type calcium current (I(Ca)) in ventricular myocytes from 3-wk-old and adult rabbits. The dissociation constant (K(d)) of Ca-Tn(cTnT1) in solution was smaller than that of Ca-Tn(cTnT4) (mean +/- SE: 0.52 +/- 0.08 mumol/L versus 0.83 +/- 0.09 mumol/L). The Ca(2+) sensitivity of force development was greater in fibers reconstituted with rcTnT(1) (pCa(50) 6.07 +/- 0.04) than those reconstituted with rcTnT(4) (pCa(50) 5.75 +/- 0.07). Systolic [Ca](i) was lower in 3-wk-old than adult cells (443 +/- 35 nmol/L versus 882 +/- 88 nmol/L) as was I(Ca) (5.8 +/- 0.9 pA/pF versus 14.2 +/- 1.6 pA/pF). The higher calcium sensitivity of Tn-Ca binding and of force development conferred by rcTnT(1) suggest that higher neonatal cTnT(1) expression may partially compensate for the lower systolic [Ca(2+)](i).

cTnT1, a cardiac troponin T isoform, decreases myofilament tension and affects the left ventricular pressure waveform.

Four isoforms of cardiac troponin T (cTnT), a protein essential for calcium-dependent myocardial force development, are expressed in the human; they differ in charge and length. Their expression is regulated developmentally and is affected by disease states. Human cTnT (hcTnT) isoform effects have been examined in reconstituted myofilaments. In this study, we evaluated the modulatory effects of overexpressing one cTnT isoform on in vitro and in vivo myocardial function. A hcTnT isoform, hcTnT(1), expressed during development and in heart disease but not in the normal adult heart, was expressed in transgenic (TG) mice (1-30% of total cTnT). Maximal active tension measured in skinned myocardium decreased as a function of relative hcTnT(1) expression. The pCa at half-maximal force development, Hill coefficient, and rate of redevelopment of force did not change significantly with hcTnT(1) expression. In vivo maximum rates of rise and fall of left ventricular pressure decreased, and the half-time of isovolumic relaxation increased, with hcTnT(1) expression. Substituting total cTnT charge for hcTnT(1) expression resulted in similar conclusions. Morphometric analysis and electron microscopy revealed no differences between wild-type (non-TG) and TG myocardium. No differences in isoform expression of tropomyosin, myosin heavy chain, essential and regulatory myosin light chains (MLC), TnI, or in posttranslational modifications of mouse cTnT, cTnI, or regulatory MLC were observed. These results support the hypothesis that cTnT isoform amino-terminal differences affect myofilament function and suggest that hcTnT(1) expression levels present during human development and in human heart disease can affect in vivo ventricular function.

Pharmacokinetics and safety of TP10, soluble complement receptor 1, in infants undergoing cardiopulmonary bypass.

BACKGROUND: Increase in vascular permeability and multiorgan dysfunction after cardiopulmonary bypass (CPB) are barriers to successful cardiac surgery in infants. Complement inhibition with TP10, a C3/C5 convertase inhibitor (AVANT Immunotherapeutics, Needham, Mass), blunts post-CPB organ dysfunction in the neonatal pig. Methods and results The pharmacokinetics and safety of TP10 in infants (age <1 year, n = 15) undergoing CPB were examined in a phase I/II open-label prospective trial. TP10 (10 mg/kg) was given intravenously before CPB and also added (10 mg/100 mL prime volume) to the CPB circuit. TP10 plasma levels correlated with C3a levels and measures of clinical course. All infants survived. No adverse events were attributed to TP10. TP10 plasma concentration fell to < or =60 microg/mL 12 hours after CPB. A 2-compartment model was fit to the TP10 blood levels as a function of time. Based on this model, an initial dose of 10 mg/kg over 0.5 hours followed by 10 mg/kg over 23.5 hours is the most appropriate for maintaining TP10 concentration between 100 microg/mL and 160 microg/mL for 24 hours after CPB. C3a was lower 12 hours after CPB than before CPB and still lower 24 hours after CPB. TP10 concentration was inversely correlated with the 12-hour post-CPB to pre-CPB ratio of C3a (Spearman rho -0.76, P = -.016), and with total (rho -0.56, P =.047) and net (rho -0.85, P =.0016) fluid and blood product administration/kg >24 hours after CPB. CONCLUSIONS: TP10 administration to infants appears safe. Pharmacokinetic analysis generated an optimal dosing strategy to achieve effective TP10 levels for 24 hours after CPB. In the infant, TP10 appears to decrease CPB-induced complement activation and protect vascular function. These results support a phase III trial of TP10 in infants requiring CPB.