Comparison of rat and mouse pulmonary tissue mechanical properties and histology.

The present study compares the dynamic mechanical properties and the contents of collagen and elastic fibers (oxytalan + elaunin + fully developed elastic fibers) of mice and rat lung strips. Resistance, elastance (E), and hysteresivity (eta) were obtained during sinusoidal oscillations. The relative amounts of blood vessel, bronchial, and alveolar walls, as well as the mean alveolar diameter were determined. In both species, resistance had a negative and E a positive dependence on frequency, whereas eta remained unchanged. Mice showed higher E and lower eta than rats. Although collagen and elastic fiber contents were similar in both groups, mice had more oxytalan and less elaunin and fully developed elastic fibers than rats. Rats showed less alveolar and more blood vessel walls and higher mean alveolar diameter than mice. In conclusion, mice and rats present distinct tissue mechanical properties, which are accompanied by specific extracellular fiber composition.     

Skin blood flowmotion and microvascular reactivity investigation in hypercholesterolemic patients without clinically manifest arterial diseases

Fourier spectral analysis of forearm skin laser Doppler flowmetry (LDF) signal was performed in fifteen hypercholesterolemic patients (HP), without clinically manifest arterial diseases, and in fifteen age-matched healthy control subjects (CS), in order to investigate skin blood flowmotion (SBF). The LDF frequency intervals studied were: 0.01-1.6 Hz total spectrum, as well as 0.01-0.02 Hz (endothelial), 0.02-0.06 Hz (sympathetic), 0.06-0.2 Hz (myogenic), 0.2-0.6 Hz (respiratory) and 0.6-1.6 Hz (cardiac). Skin microvascular reactivity (MVR) to acetylcholine (ACh) and to sodium nitroprusside (SNP) iontophoresis was also investigated. HP showed a lower post-ACh increase in power spectral density (PSD) of the 0.01-0.02 Hz SBF subinterval compared to CS (1.80+/-1.73 PU(2)/Hz vs 3.59+/-1.78 PU(2)/Hz, respectively; p<0.005), while they did not differ in MVR from CS. In eleven HP the 0.01-0.02 Hz SBF subinterval showed a higher post-ACh PSD increase near to the statistical significance after 10 weeks of rosuvastatin therapy (10 mg/day) compared to pretreatment test (3.04+/-2.95 PU(2)/Hz vs 1.91+/-1.94 PU(2)/Hz; p=0.07). The blunted post-ACh increase in PSD of the 0.01-0.02 Hz SBF subinterval in HP suggests a skin endothelial dysfunction in these patients. This SBF abnormality showed a tendency to improve after rosuvastatin therapy in eleven treated patients.     

Dissociation between hysteresivity and tension in constricted tracheal and parenchymal strips

The object of this study was to investigatehow changes in the contractile state of smooth muscle would modifyoscillatory mechanics of tracheal muscle and lung parenchyma duringagonist challenge. Guinea pig tracheal and parenchymal lung strips were suspended in an organ bath. Measurements of length(L) and tension (T) were recordedduring sinusoidal oscillations under baseline conditions and afterchallenge with 1 mM ACh. Measurements were also obtained in stripspretreated with the calmodulin inhibitor calmidazolium (Cmz) orstaurosporine (Stauro), a protein kinase C inhibitor. Elastance (E) andresistance (R) were calculated by fitting changes in T,L, andL/tto the equation of motion. Hysteresivity () was obtained from thefollowing equation: = (R/E)2f,where f is frequency. Finally, maximalunloaded shortening velocity during electrical field stimulation wasmeasured in Cmz-pretreated and control tracheal strips. In trachealstrips, pretreatment with Cmz caused a significant decrease in the  response to ACh challenge and in maximal unloaded shortening velocitymeasured during electrical field stimulation; Stauro decreased the T,E, and R response to ACh. In parenchymal strips, Cmz decreased the  response, whereas Stauro had no effect. These results suggest thatmodifications in the contractile state of the smooth muscle arereflected in changes in the hysteretic behavior and that T and  maybe controlled independently. Second, inasmuch as changes in  weresimilar in parenchymal and tracheal strips, the contractile element isimplicated as the structure responsible for constriction-induced changes in the mechanical behavior of the lung periphery.

     

Effect of CO₂ on the ventilatory sensitivity to rising body temperature during exercise

We examined the degree to which ventilatory sensitivity to rising body temperature (the slope of the regression line relating ventilation and body temperature) is altered by restoration of arterial PCO(2) to the eucapnic level during prolonged exercise in the heat. Thirteen subjects exercised for ~60 min on a cycle ergometer at 50% of peak O(2) uptake with and without inhalation of CO(2)-enriched air. Subjects began breathing CO(2)-enriched air at the point that end-tidal Pco(2) started to decline. Esophageal temperature (T(es)), minute ventilation (V(E)), tidal volume (V(T)), respiratory frequency (f(R)), respiratory gases, middle cerebral artery blood velocity, and arterial blood pressure were recorded continuously. When V(E), V(T), f(R), and ventilatory equivalents for O(2) uptake (V(E)/VO(2)) and CO(2) output (V(E)/VCO(2)) were plotted against changes in T(es) from the start of the CO(2)-enriched air inhalation (ΔT(es)), the slopes of the regression lines relating V(E), V(T), V(E)/VO(2), and V(E)/VCO(2) to ΔT(es) (ventilatory sensitivity to rising body temperature) were significantly greater when subjects breathed CO(2)-enriched air than when they breathed room air (V(E): 19.8 ± 10.3 vs. 8.9 ± 6.7 l·min(-1)·°C(-1), V(T): 18 ± 120 vs. -81 ± 92 ml/°C; V(E)/VO(2): 7.4 ± 5.5 vs. 2.6 ± 2.3 units/°C, and V(E)/VCO(2): 7.6 ± 6.6 vs. 3.4 ± 2.8 units/°C). The increase in Ve was accompanied by increases in V(T) and f(R). These results suggest that restoration of arterial PCO(2) to nearly eucapnic levels increases ventilatory sensitivity to rising body temperature by around threefold.     

Changes in viscoelastic properties of rat lung parenchymal strips with maturation.

The lung extracellular matrix changes rapidly with maturation. To further our understanding of the mechanisms underlying lung tissue mechanics, we studied age-related changes in mechanical properties in lung parenchymal strips from baby (10-15 days old), young ( approximately 3 wk old), and adult ( approximately 8 wk old) rats. Subpleural strips were cut and suspended in a fluid-filled organ bath. One end of the strip was attached to a force transducer and the other to a servo-controlled lever arm. Measurements of force (F) and length (L) were recorded during sinusoidal oscillations of various amplitudes and frequencies. Resistance modulus (R) and elastance modulus (E) were estimated by fitting the equation of motion to changes in stress (T) and stretch ratio (lambda). Hysteresivity (eta) was calculated as follows: eta = (R/E)2pif, where f is frequency. Slow-cycling T-lambda curves were measured by applying a constant slow length change. Finally, quasi-static T-lambda curves were measured as stress was increased from 0 to 6 kPa and back to 0 kPa in stepwise increments. Our results showed that lung tissue from immature rats was stiffer and less hysteretic than tissue from more mature animals. In addition, tissue from baby animals behaved in a manner compatible with an increased vulnerability to plastic change.     

Relation of effective arterial elastance to arterial system properties

Effective arterial elastance (E(a)), defined as the ratio of left ventricular (LV) end-systolic pressure and stroke volume, lumps the steady and pulsatile components of the arterial load in a concise way. Combined with E(max), the slope of the LV end-systolic pressure-volume relation, E(a)/E(max) has been used to assess heart-arterial coupling. A mathematical heart-arterial interaction model was used to study the effects of changes in peripheral resistance (R; 0.6-1.8 mmHg x ml(-1) x s) and total arterial compliance (C; 0.5-2.0 ml/mmHg) covering the human pathophysiological range. E(a), E(a)/E(max,) LV stroke work, and hydraulic power were calculated for all conditions. Multiple-linear regression analysis revealed a linear relation between E(a), R/T (where T is cycle length), and 1/C: E(a) = -0.13 + 1.02R/T + 0.31/C, indicating that R/T contributes about three times more to E(a) than arterial stiffness (1/C). It is demonstrated that different pathophysiological combinations of R and C may lead to the same E(a) and E(a)/E(max) but can result in differences of 10% in stroke work and 50% in maximal power.     

Light-induced conformational changes of cyanobacterial phytochrome Cph1 probed by limited proteolysis and autophosphorylation

Photoreceptor chromoproteins undergo light-induced conformational changes that result in a modulation of protein interaction and enzymatic activity. Bacterial phytochromes such as Cph1 from the cyanobacterium Synechocystis PCC 6803 are light-regulated histidine kinases in which the light signal is transferred from the N-terminal chromophore module to the C-terminal kinase module. In this study, purified recombinant Cph1 was subjected to limited proteolysis using trypsin and endoproteinase Glu-C (V8). Cleavage sites of chromopeptide fragments were determined by MALDI-TOF and micro-HPLC on-line with tandem mass spectrometry in an ion trap mass spectrometer. Trypsin produced three major chromopeptides, termed F1 (S56 to R520), F2 (T64 to R472), and F3 (L81 to R472). F1 was produced only in the far-red absorbing form Pfr within 15 min and remained stable up to >1 h; F2 and F3 were obtained in the red-light absorbing form Pr within ca. 5-10 min. When F1 was photoconverted to Pr in the presence of trypsin, this fragment degraded to F2 and F3 within 1-2 min. On size exclusion chromatography, F1 eluted as a dimer in the Pfr and as a monomer in the Pr form, whereas F2 and F3 behaved always as monomers, irrespective of the light conditions. These and other results are discussed in the context of light-dependent subunit interactions, in which amino acids 473-520 within the PHY domain are required for chromophore-module subunit interaction within the homodimer. V8 proteolysis yielded five major chromopeptides, F4 (T17 to N449), F5 (T17 to E335), F6 (T17 to E323), F7 (unknown sequence), and F8 (tentatively L121 to E323). F6 and F8 were formed in the Pr form, whereas F4, F5, and F7 were preferentially formed in the Pfr form. Three amino acids next to specific cleavage sites, R520, R472, and E323, were altered by site-directed mutagenesis. The mutants were analyzed by UV-vis spectroscopy, size exclusion chromatography, and autophosphorylation. Histidine kinase activity was low in R472A, R520P, and R520A; in all mutants, the ratio of phosphorylation intensity between Pr and Pfr was reduced. Thus, light regulation of autophosphorylation is negatively affected in all mutants. In R472P, E323P, and E323D, the phosphorylation intensity of the Pfr form exceeded that of the wild-type control. This result shows that the histidine kinase activity of Cph1 is actively inhibited by photoconversion into Pfr.     

Dynamic response of the isolated passive rat diaphragm strip.

To further our understanding of the mechanisms underlying chest wall mechanics, we investigated the dynamic response of the isolated passive rat diaphragm strip. Stress adaptation of the tissue was measured from 0.05 to 60 s after subjecting the strips to strain steps of normalized strain amplitudes from 0.005 to 0.04. The tissue resistance (R), elastance (E), and hysteresivity (eta) were measured in the same range of amplitudes by sinusoidally straining the strip at frequencies from 0.03125 to 10 Hz. The stress (T) depended exponentially on the strain (epsilon) and relaxed and recovered linearly with the logarithm of time. E increased linearly with the logarithm of frequency and decreased with increasing amplitude. R fell hyperbolically with frequency and showed an amplitude dependence similar to that of E. To interpret the strong nonlinear behavior, we extended the viscoelastic model of Hildebrandt (J. Appl. Physiol. 28: 365-372, 1970) to include an exponential stress-strain relationship. Accordingly, the step response was described by T - Tr = Tr(e alpha delta epsilon - 1)(1 - gamma log t), where delta epsilon is the strain amplitude, Tr is the initial operating stress, alpha is a measure of the stress-strain nonlinearity, and gamma is the rate of stress adaptation. The oscillatory response of the model was computed by applying Fung's quasi-linear viscoelastic theory. This quasi-linear viscoelastic model fitted the step and oscillatory data fairly well but only if alpha depended negatively on delta epsilon, as might be expected in a plastic material.     

Isometric contractile properties of diaphragm strips from alcoholic rats

Chronic ethanol consumption alters the structure and function of human respiratory muscle. We have examined its effect on the active and passive mechanical properties of rat diaphragm strips in vitro. We conditioned eight rats using a liquid diet containing ethanol as 36% of calories. Eight control rats were pair-fed an isocaloric, ethanol-free liquid diet. Rats were killed after 23 wk. Two strips from the left hemidiaphragm were suspended in Krebs-Ringers solution at 25 degrees C, equilibrated with 5% CO2-95% O2. Isometric stresses were calculated from force transducer measurements. Strips were stimulated directly at supramaximal voltage. Twitch stress (Pt), measured at optimal length (Lo), was greater in ethanol-conditioned strips: 5.1 vs. 3.8 N/cm2. Times to peak Pt and twitch half-relaxation times were equal. Tetanic stress at Lo (Po) was also greater after ethanol conditioning: 17.2 vs. 12.8 N/cm2. Pt/Po ratios were equal. Expressed as %Po, tetanic stress-stimulation frequency curves and tetanic stress-length curves were identical. Ethanol-conditioned strips were marginally less compliant when passively stretched to lengths between Lo and 130% Lo. We postulate that ethanol may have increased active stress development by reducing intracellular free water.     

Effects of age on the anisotropy of the descending human thoracic aorta determined by uniaxial tensile testing and digestion by NaOH under load

Strips of human thoracic aortic wall taken at autopsy from 23 individuals aged 15-81 years have been tested in two ways: in uniaxial loading and by digestion in 0.1 M NaOH at 75 degrees C under a load of 50 g. The circumferentially oriented strips were more extensible in loading and took a longer time to fail while being digested under load than the longitudinal strips from the same location. The stress versus strain curve was fitted to an exponential equation of the form, stress = A[exp(B strain)]. For circumferentially oriented strips from 19 subjects, parameter A was independent of age. Parameter B increased by a factor of 2.75 from 19 to 81 years. For longitudinally oriented strips for 14 subjects, A was also independent of age and B increased by 2.4 times from 25 to 81. With digestion under load for 11 matched pairs of strips aged from 32 to 75 the circumferential strips failed in 117 +/- 23 min (standard error), while the longitudinal ones failed in 20.3 +/- 3.2 min (standard error) (p less than 0.003). The results have important implications for vessel attachments to the aorta in heart transplantation and in vascular surgery.     

Latrunculin B increases force fluctuation-induced relengthening of ACh-contracted, isotonically shortened canine tracheal smooth muscle.

We hypothesized that differences in actin filament length could influence force fluctuation-induced relengthening (FFIR) of contracted airway smooth muscle and tested this hypothesis as follows. One-hundred micromolar ACh-stimulated canine tracheal smooth muscle (TSM) strips set at optimal reference length (Lref) were allowed to shorten against 32% maximal isometric force (Fmax) steady preload, after which force oscillations of +/-16% Fmax were superimposed. Strips relengthened during force oscillations. We measured hysteresivity and calculated FFIR as the difference between muscle length before and after 20-min imposed force oscillations. Strips were relaxed by ACh removal and treated for 1 h with 30 nM latrunculin B (sequesters G-actin and promotes depolymerization) or 500 nM jasplakinolide (stabilizes actin filaments and opposes depolymerization). A second isotonic contraction protocol was then performed; FFIR and hysteresivity were again measured. Latrunculin B increased FFIR by 92.2 +/- 27.6% Lref and hysteresivity by 31.8 +/- 13.5% vs. pretreatment values. In contrast, jasplakinolide had little influence on relengthening by itself; neither FFIR nor hysteresivity was significantly affected. However, when jasplakinolide-treated tissues were then incubated with latrunculin B in the continued presence of jasplakinolide for 1 more h and a third contraction protocol performed, latrunculin B no longer substantially enhanced TSM relengthening. In TSM treated with latrunculin B + jasplakinolide, FFIR increased by only 3.03 +/- 5.2% Lref and hysteresivity by 4.14 +/- 4.9% compared with its first (pre-jasplakinolide or latrunculin B) value. These results suggest that actin filament length, in part, determines the relengthening of contracted airway smooth muscle.     

Effect of graded hypoxic and acidotic stress on contractile force of heart muscle from hypoxia-tolerant and hypoxia-intolerant turtles

Previous studies have shown that isometric contractile force of in vitro cardiac muscle from the anoxia-tolerant painted turtle, Chrysemys picta bellii, decreases when anoxic and when acidotic. This study sought to define the thresholds for these responses in the isolated ventricular strips of the painted turtle and in the anoxia-intolerant softshell turtles, Apalone spinifera. The ventricular strips were exposed to HCO3- Ringer's solution equilibrated at P(O2) 156, 74, 37, 19, and 0 mmHg (45 min at each grade), at both pH 7.0 and at pH 7.8. Strips were also exposed to graded lactic acidosis with intervals between pH 6.8 and pH 7.8 at P(O2) 156 mmHg (softshell) or 37 mmHg (painted). In painted turtle strips at pH 7.8, force remained at control levels until it decreased by 30% at P(O2) 19 mmHg. No further significant decrease occurred at P(O2) 0. In contrast, softshell turtle muscle force did not fall significantly until P(O2) reached 0. When graded hypoxia was imposed at pH 7.0, strips from both species were more sensitive to hypoxia, but the softshell force decreased at a higher P(O2) than the painted turtle (P(O2) 156 mmHg vs. 37 mmHg), its force fell to a lower level at P(O2) 0 (22 % of control vs. 40 % of control), and unlike painted turtle heart muscle, softshell muscle did not recover fully. In summary, these data indicate that ventricular strips of the painted turtle are no more tolerant of hypoxia alone than strips from the softshell turtle, but that when hypoxia is combined with acidosis, the painted turtle heart muscle functions significantly better during the exposure and recovers more fully after exposure.     

Wood biomechanics and anatomy of PACHYCEREUS PRINGLEI

We report the longitudinal, biomechanical, and anatomical trends observed for tissue samples drawn from the parallel aligned, prismatic woody vascular bundles running the length of a Pachycereus pringlei plant measuring 5.22 m in height. The main vertical stem of this plant was cut into five segments (labeled A through E in the acropetal direction) measuring ～1.02 m in length. Four of the 14 vascular bundles in each segment were surgically removed to obtain 20 vascular bundle segments that were tested in bending to determine their stiffness measured in the radial E(R) and tangential E(T) direction. We also determined the lignin content of representative samples of wood.A nonlinear trend in stiffness was observed: E(R) and E(T) were highest in segments B or C (1.67 GN/m and 1.09 GN/m, respectively), lower in segment A (E(R) = 1.18 GN/m and E(T) = 0.35 GN/m), and lowest in segment E (E(R) = 0.03 GN/m and E(T) = 0.20 GN/m). Similar longitudinal trends were seen for axial tissue volume fraction and fiber wall thickness, which achieved their highest values in segment B (69.8% and 6.59 μm, respectively). Wood stiffness also correlated significantly with cell wall lignin content: with respect to segment B (which had the highest lignin content, and was thus used as the standard reference for percent lignin content), lignin content, was 15, 60, 85, and 43% in segments E, D, C, and A, respectively. Fiber cell length, which increased toward the base of the stem and toward the vascular cambium in the most proximal vascular bundle segment, did not correlate with E(R) or E(T).Basic engineering principles were used to calculate stem stresses resulting from self-loading and any wind-induced bending moment (produced by drag forces). Calculations indicated that the less stiff wood produced in segment A eliminates a rapid and potentially dangerous increase in stresses that would otherwise occur in segments B or C. The less stiff wood in segment A also reduces the probability of shear failure at the cellular interface between the wood and surrounding tissues in this portion of the stem.We conclude that P. pringlei wood stiffness is dependent on the volume fraction and lignification of axial tissues, less so on fiber wall thickness, and that wood development in this species is adaptively responsive to self-loading and differentially applied external mechanical forces.     

Quantitative evaluation of the genetic divergence of amphibian taxa of different rank by the spectra of total proteins and nonspecific esterases

Based on the PAAG disc-electrophoretic spectra of water-soluble total proteins (Pr) and non-specific esterases (Est) from several types of tissues in representatives of Urodela (Triturus vulgaris vulgaris, T. v. lantzi, T. cristatus, T. montandoni, T. dobrogicus) and Anura amphibians (Rana ridibunda, R. lessonae, R. temporaria, R. arvalis; Bufo bufo, B. viridis, Bombina bombina; Xenopus laevis, X. borealis; Hymenochirus boettgeri), mean genetic distances (D = -ln[2i/(2i + d)], where i is the number of fractions identical and d is the number of fractions different by Rf-bands, were estimated within and between taxa of intra-, inter-, and superspecific ranks. The most stable estimates were obtained for Pr and Est spectra of skeletal muscles and eyes. In most cases, the spectra of tissues of the digestive system gave higher D values than those of the other organs. The levels of intraspecific differentiation by D (both Pr and Est) were higher in the studied representatives of the order Urodela, probably due to their lower migration ability and more conservative choice of water-bodies for spawning than in the representatives of the other order; the same trend is true for the interspecific differentiation by Pr spectra. Est, on the contrary, gave lighter interspecific differentiation level in Anura than in Urodela, evidently due to the prevalence of sympatric species pairs able to hybridize among the studied representatives of the latter order.     

14-3-3eta is a novel regulator of parkin ubiquitin ligase

Mutation of the parkin gene, which encodes an E3 ubiquitin-protein ligase, is the major cause of autosomal recessive juvenile parkinsonism (ARJP). Although various substrates for parkin have been identified, the mechanisms that regulate the ubiquitin ligase activity of parkin are poorly understood. Here we report that 14-3-3eta, a chaperone-like protein present abundantly in neurons, could bind to parkin and negatively regulate its ubiquitin ligase activity. Furthermore, 14-3-3eta could bind to the linker region of parkin but not parkin with ARJP-causing R42P, K161N, and T240R mutations. Intriguingly, alpha-synuclein (alpha-SN), another familial Parkinson's disease (PD) gene product, abrogated the 14-3-3eta-induced suppression of parkin activity. alpha-SN could bind tightly to 14-3-3eta and consequently sequester it from the parkin-14-3-3eta complex. PD-causing A30P and A53T mutants of alpha-SN could not bind 14-3-3eta, and failed to activate parkin. Our findings indicate that 14-3-3eta is a regulator that functionally links parkin and alpha-SN. The alpha-SN-positive and 14-3-3eta-negative control of parkin activity sheds new light on the pathophysiological roles of parkin.     

Mitochondrial ATP synthase residue betaarginine-408, which interacts with the inhibitory site of regulatory protein IF1, is essential for the function of the enzyme

Mitochondrial ATP synthase (F(1)F(0)-ATPase) is regulated by an intrinsic ATPase inhibitor protein, IF(1). We previously found that six residues of the yeast IF(1) (Phe17, Arg20, Glu21, Arg22, Glu25, and Phe28) form an ATPase inhibitory site [Ichikawa, N. and Ogura, C. (2003) J. Bioenerg. Biomembr. 35, 399-407]. In the crystal structure of the F(1)/IF(1) complex [Cabezón, E. et al. (2003) Nat. Struct. Biol. 10, 744-750], the core residues of the inhibitory site interact with Arg408, Arg412 and Glu454 of the beta-subunit of F(1). In the present study, we examined the roles of the three beta residues by means of site-directed mutagenesis. A total of six yeast mutants were constructed: R408I, R408T, R412I, R412T, E454Q, and E454V. The betaArg412 and betaGlu454 mutants (R412I, R412T, E454Q, and E454V) could grow on a nonfermentable lactate medium, but the betaArg408 mutants (R408I and R408T) could not. The ATPase activity of isolated mitochondria was decreased in R412I, R412T, E454Q, and E454V mutant cells, and undetectable in R408I and R408T cells. The subunits of F(1) (alpha, beta, and gamma) were detected in mitochondria from each mutant on immunoblotting, and the F(1)F(0) complex was isolated from them. These results indicate that betaArg408 is essential not for assembly of the F(1)F(0) complex but for the catalytic activity of the enzyme. In the crystal structure of F(1), betaArg408 binds to alphaGlu399 in the alpha(DP)/beta(DP) pair and seems to be important for formation of the closed alpha(DP)/beta(DP) conformation. IF(1) seems to disrupt this alpha(DP)Glu399/beta(DP)Arg408 interaction by binding to beta(DP)Arg408, and to interfere with the change from the open alpha(DP)/beta(DP) conformation to the closed conformation that is required for catalysis by F(1)F(0)-ATPase.     

DNA polymerase eta contributes to strand bias of mutations of A versus T in immunoglobulin genes

DNA polymerase (pol) eta participates in hypermutation of A:T bases in Ig genes because humans deficient for the polymerase have fewer substitutions of these bases. To determine whether polymerase eta is also responsible for the well-known preference for mutations of A vs T on the nontranscribed strand, we sequenced variable regions from three patients with xeroderma pigmentosum variant (XP-V) disease, who lack polymerase eta. The frequency of mutations in the intronic region downstream of rearranged J(H)4 gene segments was similar between XP-V and control clones; however, there were fewer mutations of A:T bases and correspondingly more substitutions of C:G bases in the XP-V clones (p < 10(-7)). There was significantly less of a bias for mutations of A compared with T nucleotides in the XP-V clones compared with control clones, whereas the frequencies for mutations of C and G were identical in both groups. An analysis of mutations in the WA sequence motif suggests that polymerase eta generates more mutations of A than T on the nontranscribed strand. This in vivo data from polymerase eta-deficient B cells correlates well with the in vitro specificity of the enzyme. Because polymerase eta inserts more mutations opposite template T than template A, it would generate more substitutions of A on the newly synthesized strand.     

Antagonism of relaxation to isoproterenol caused by agonist interactions

The interaction of contractile agonists on the relaxation elicited with isoproterenol (ISO) was studied in 112 tracheal smooth muscle (TSM) strips from 20 dogs in vitro. Strips were contracted to the same active target tension (TT) with acetylcholine (ACh), histamine (HIS), serotonin (5-hydroxytryptamine, 5-HT), potassium chloride (KCl), or the combinations of ACh + HIS, ACh + 5-HT, HIS + KCl, HIS + 5-HT (50% TT from each agonist). Although a less potent agonist, adding HIS to cause 50% of the TT reduced the concentration of ACh to elicit the remaining 50% TT and substantially altered relaxation by ISO compared with HIS alone [concentration required to achieve 50% relaxation (RC50) = 9.2 +/- 2.4 X 10(-8) vs. 9.0 +/- 4.4 X 10(-9) M to HIS alone; P less than 0.003]. Relaxation for TSM strips contracted with ACh + HIS was comparable to that elicited from the same TT with ACh alone, although concentrations required in combination were lower than for either agonist alone. Trachealis strips contracted equivalently with KCl + HIS also had augmented contraction and attenuated relaxation (RC50 = 3.7 +/- 0.8 X 10(-8) M; P less than 0.015 vs. HIS alone). However, combinations of 5-HT + ACh and 5-HT + HIS did not alter relaxation to ISO from that elicited by the weaker agonist alone. We demonstrate that TSM relaxation depends on the combination of agonists eliciting contraction and may be inhibited substantially by interactions among contractile agonists.     

The influence of prostaglandin E2 (PGE2) on the acetylcholine-initiated contractions of isolated gastric muscularis muscle of Bufo marinus

Acetylcholine (ACh) (1.5 X 10(-5) M) elicited three different types of tonic and phasic contraction of muscularis muscle from different parts (cardiac, middle and pyloric) of the stomach of Bufo marinus. Prostaglandin E2 (PGE2) (10(-9)-10(-6) M) induced a concentration-dependent relaxation of tonic contractions elicited by ACh (1.5 x 10(-5) M) of strips from the cardiac part while potentiating the phasic contractions from the middle part of the stomach. PGE2 (10(-7) M) relaxed tonic contraction and potentiated phasic contraction concomitantly in preparations in which tonic and phasic contractions were elicited by ACh (1.5 x 10(-5) M). The effects of PGE2 on the preparation are related to the part of the stomach from where the strips are prepared and the muscle tone of the preparation.