Genetic control of differential baseline breathing pattern

Tankersley, Clarke G., Robert S. Fitzgerald, Roy C. Levitt,Wayne A. Mitzner, Susan L. Ewart, and Steven R. Kleeberger. Genetic control of differential baseline breathing pattern. J. Appl. Physiol. 82(3): 874-881, 1997.The purpose of the present study was to determine the geneticcontrol of baseline breathing pattern by examining the mode ofinheritance between two inbred murine strains with differentialbreathing characteristics. Specifically, the rapid, shallow phenotypeof the C57BL/6J (B6) strain is consistently distinct from theslow, deep phenotype of the C3H/HeJ (C3) strain. The responsedistributions of segregant and nonsegregant progeny were compared withthe two progenitor strains to determine the mode of inheritance foreach ventilatory characteristic. The BXH recombinant inbred (RI)strains derived from the B6 and C3 progenitors were examined toestablish strain distribution patterns for each ventilatory trait. Toestablish the mode of inheritance, baseline breathing frequency (f),tidal volume, and inspiratory time(TI) were measured five timesin each of 178 mature male animals from the two progenitor strains andtheir progeny by using whole body plethysmography. With respect to fand TI, the two progenitor strains were consistently distinct, and segregation analyses of theinheritance pattern suggest that the most parsimonious genetic modelfor response distributions of f andTI is a two-loci model. Insimilar experiments conducted on 82 mature male animals from 12 BXH RIstrains, each parental phenotype was represented by one or more of theRI strains. Intermediate phenotypes emerged to confirm the likelihoodthat parental strain differences in f andTI were determined by more thanone locus. Taken together, these studies suggest that the phenotypicdifference in baseline respiratory timing between male B6 and C3 miceis best explained by a genetic model that considers at least two locias major determinants.

     

Differential lung mechanics are genetically determined in inbred murine strains.

Genetic determinants of lung structure and function have been demonstrated by differential phenotypes among inbred mice strains. For example, previous studies have reported phenotypic variation in baseline ventilatory measurements of standard inbred murine strains as well as segregant and nonsegregant offspring of C3H/HeJ (C3) and C57BL/6J (B6) progenitors. One purpose of the present study is to test the hypothesis that a genetic basis for differential baseline breathing pattern is due to variation in lung mechanical properties. Quasi-static pressure-volume curves were performed on standard and recombinant inbred strains to explore the interactive role of lung mechanics in determination of functional baseline ventilatory outcomes. At airway pressures between 0 and 30 cmH2O, lung volumes are significantly (P < 0.01) greater in C3 mice relative to the B6 and A/J strains. In addition, the B6C3F1/J offspring demonstrate lung mechanical properties significantly (P < 0.01) different from the C3 progenitor but not distinguishable from the B6 progenitor. With the use of recombinant inbred strains derived from C3 and B6 progenitors, cosegregation analysis between inspiratory timing and measurements of lung volume and compliance indicate that strain differences in baseline breathing pattern and pressure-volume relationships are not genetically associated. Although strain differences in lung volume and compliance between C3 and B6 mice are inheritable, this study supports a dissociation between differential inspiratory time at baseline, a trait linked to a putative genomic region on mouse chromosome 3, and differential lung mechanics among C3 and B6 progenitors and their progeny.     

Physiological and Genomic Consequences of Intermittent Hypoxia: Selected Contribution: Variation in acute hypoxic ventilatory response is linked to mouse chromosome 9

Genetic determinants confervariation among inbred mouse strains with respect to the magnitude andpattern of breathing during acute hypoxic challenge. Specifically,inheritance patterns derived from C3H/HeJ (C3) and C57BL/6J (B6)parental strains suggest that differences in hypoxic ventilatoryresponse (HVR) are controlled by as few as two genes. The present studydemonstrates that at least one genetic determinant is located on mousechromosome 9. This genotype-phenotype association was established byphenotyping 52 B6C3F₂ (F₂) offspring for HVRcharacteristics. A genome-wide screen was performed usingmicrosatellite DNA markers (n = 176) polymorphicbetween C3 and B6 mice. By computing log-likelihood values (LODscores), linkage analysis compared marker genotypes with minuteventilation (E), tidal volume (VT), andmean inspiratory flow (VT/TI, whereTI is inspiratory time) during acute hypoxic challenge(inspired O₂ fraction = 0.10, inspired CO₂fraction = 0.03 in N₂). A putative quantitative traitlocus (QTL) positioned in the vicinity of D9Mit207 wassignificantly associated with hypoxic E (LOD = 4.5), VT (LOD = 4.0), andVT/TI (LOD = 5.1). For each of the threeHVR characteristics, the putative QTL explained more than 30% of thephenotypic variation among F₂ offspring. In conclusion,this genetic model of differential HVR characteristics demonstratesthat a locus ~33 centimorgans from the centromere on mouse chromosome9 confers a substantial proportion of the variance inE, VT, and VT/TIduring acute hypoxic challenge.

     

Interactions in hypoxic and hypercapnic breathing are genetically linked to mouse chromosomes 1 and 5.

The genetic basis for differences in the regulation of breathing is certainly multigenic. The present paper builds on a well-established genetic model of differences in breathing using inbred mouse strains. We tested the interactive effects of hypoxia and hypercapnia in two strains of mice known for variation in hypercapnic ventilatory sensitivity (HCVS); i.e., high gain in C57BL/6J (B6) and low gain in C3H/HeJ (C3) mice. Strain differences in the magnitude and pattern of breathing were measured during normoxia [inspired O(2) fraction (Fi(O(2))) = 0.21] and hypoxia (Fi(O(2)) = 0.10) with mild or severe hypercapnia (inspired CO(2) fraction = 0.03 or 0.08) using whole body plethysmography. At each level of Fi(O(2)), the change in minute ventilation (Ve) from 3 to 8% CO(2) was computed, and the strain differences between B6 and C3 mice in HCVS were maintained. Inheritance patterns showed potentiation effects of hypoxia on HCVS (i.e., CO(2) potentiation) unique to the B6C3F1/J offspring of B6 and C3 progenitors; i.e., the change in Ve from 3 to 8% CO(2) was significantly greater (P < 0.01) with hypoxia relative to normoxia in F1 mice. Linkage analysis using intercross progeny (F2; n = 52) of B6 and C3 progenitors revealed two significant quantitative trait loci associated with variable HCVS phenotypes. After normalization for body weight, variation in Ve responses during 8% CO(2) in hypoxia was linked to mouse chromosome 1 (logarithm of the odds ratio = 4.4) in an interval between 68 and 89 cM (i.e., between D1Mit14 and D1Mit291). The second quantitative trait loci linked differences in CO(2) potentiation to mouse chromosome 5 (logarithm of the odds ratio = 3.7) in a region between 7 and 29 cM (i.e., centered at D5Mit66). In conclusion, these results support the hypothesis that a minimum of two significant genes modulate the interactive effects of hypoxia and hypercapnia in this genetic model.     

Selected contribution: variation in acute hypoxic ventilatory response is linked to mouse chromosome 9.

Genetic determinants confer variation among inbred mouse strains with respect to the magnitude and pattern of breathing during acute hypoxic challenge. Specifically, inheritance patterns derived from C3H/HeJ (C3) and C57BL/6J (B6) parental strains suggest that differences in hypoxic ventilatory response (HVR) are controlled by as few as two genes. The present study demonstrates that at least one genetic determinant is located on mouse chromosome 9. This genotype-phenotype association was established by phenotyping 52 B6C3F2 (F2) offspring for HVR characteristics. A genome-wide screen was performed using microsatellite DNA markers (n = 176) polymorphic between C3 and B6 mice. By computing log-likelihood values (LOD scores), linkage analysis compared marker genotypes with minute ventilation (&Vdot;E), tidal volume (VT), and mean inspiratory flow (VT/TI, where TI is inspiratory time) during acute hypoxic challenge (inspired O2 fraction = 0.10, inspired CO2 fraction = 0.03 in N2). A putative quantitative trait locus (QTL) positioned in the vicinity of D9Mit207 was significantly associated with hypoxic VE (LOD = 4.5), VT (LOD = 4.0), and VT/TI (LOD = 5.1). For each of the three HVR characteristics, the putative QTL explained more than 30% of the phenotypic variation among F(2) offspring. In conclusion, this genetic model of differential HVR characteristics demonstrates that a locus approximately 33 centimorgans from the centromere on mouse chromosome 9 confers a substantial proportion of the variance in VE, VT, and VT/TI during acute hypoxic challenge.     

Genetic analysis of nonhistone chromosomal protein inheritance in recombinant inbred mouse strains using two-dimensional electrophoresis

Analysis of hepatic nonhistone chromosomal protein (NHCP) expression in male mice from progenitor strains (C3H/HeN, C57BL/6N), their F₁ hybrid (B6C3), and seven recombinant inbred strains (RIs) (B6N×C3N) by high-resolution two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) detected 16 NHCPs whose expression in RIs could be correlated to each other and with strain distribution patterns (SDP) of 20 genetic markers differing in the progenitors. Of the 400₊ NHCP spots detected in RI 2D-PAGE maps, 172 were common to progenitors and all RIs. There was a characteristic absence of five NHCPs in one RI, Y. Ten C3H-specific and six C57-specific NHCP inherited in B6C3 also appeared in RIs. The SDP of C3H-specific NHCP 2 matched the SDP of beta-glucuronidase on chromosome 5 and carbonic anhydrase on chromosome 3, and C57-specific NHCP 5 SDP corresponded to that for nonagouti trait on chromosome 2. These 16 NHCP genetic marker inheritance differences detected in RIs add to the 23 previously established genetic marker differences between the progenitors.This study was supported in part by funds from NIH Grants CA 33305 and CA 16672 and Exxon Corporation, USA.     

The Heritability of Abscisic Acid Accumulation in Water-stressed Leaves of Pearl Millet [Pennisetum americanum (L.) Leeke]

Using detached leaves, two cultivars of pearl millet [Pennisetumamericanum (L.) Leeke], B282 and Serere 39, were assessed forvariation in the capacity to accumulate ABA in response to waterstress. Significant differences in ABA accumulation were detectedbetween cultivars and between different inbred lines withina cultivar, but within lines there was much less variation inthis character. In crosses between individual lines of B282(low ABA) and Serere 39 (high ABA), ABA accumulation in theF₁ was mid-way between parental values, indicating additivegenetic control and lack of dominance. Selfed progeny of a B282 x Serere 39 cross were selected forcontrasting ABA accumulation in the F₂ to F₄ generations. Asixfold range in ABA accumulation was found amongst 207 F₂ progeny.This increased to nearly ninefold at F₃ and F₄. Regression analysisindicated high heritability of ABA accumulation and rapid approachto homozygosity. As the cross studied involved a dwarf (B282) and a tall (Serere39) parent, segregation occurred for height as well as for ABA,though not entirely independently. Tall F₃ progeny had significantlyhigher ABA contents than dwarf progeny and high ABA was thereforeassociated with other traits (e.g. large leaves, high leaf percent d. wt) characteristic of tall plants. Nevertheless, therewas a substantial range of ABA content within both groups whichwas uncorrelated with height and other characters. The potential use of the selections in studies on drought responseis briefly discussed. Pennisetum americanum (L.), Leeke, pearl millet, abscisic acid accumulation, water stress, genetic differences, inheritance     

Polygenic determination of quinine aversion among mice

There are substantial differences among inbred mouse strainsin avoidance of quinine solutions in two-bottle preference tests.x A Mendelian cross-breeding experiment was conducted to testthe hypothesis that a single locus Qui has a major influenceon quinine aversion. Inbred strains C57B1/6J (B6, avoider) andC3HeB/FeJ (C3, indifferent) were progenitors of two segregatinggenerations. Phenotypic ratios for 100 µM and 30 µMquinine sulfate (QSO4) in these generations were not consistentwith ratios expected for a single gene. Frequency distributionsfor individual preference ratios were more characteristic ofa polygenic trait. An outbred strain (CFW/Crl) which displayssegregation for the Soa locus was tested for both QSO4 and sucroseocta-acetate (SOA) avoidance. Correlated avoidance patternsfor the two bitter compounds were found in these mice. A Soaeffect might not have been seen in the C3.B6 cross because bothstrains are relatively poor SOA avoiders. A second Mendeliancross was made between strains C3 and SWR/J (SW, SOA and QSO4avoider). One segregating generation was tested with both compounds.In these mice, as in the CFW population, QSO4 aversion was correlatedwith SOA aversion. These results suggest that quinine aversionis polygenic, that there is a relationship between SOA sensitivityand quinine sensitivity, and that this association may be theresult of variation at the Soa locus.     

Quantitative trait locus mapping of genes regulating pulmonary PKC activity and PKC-alpha content

Strain A/J mice, which are predisposed to experimentally induced asthma and adenocarcinoma, have the lowest pulmonary protein kinase (PK) C activity and content among 22 inbred mouse strains. PKC in neonatal A/J mice is similar to that in other strains, so this difference reflects strain-dependent postnatal regulation. PKC activity is 60% higher in C57BL/6J (B6) than in A/J lungs, and the protein and mRNA concentrations of PKC-alpha, the major pulmonary PKC isozyme, are two- to threefold higher in B6 mice. These differences result from more than a single gene as assessed in F(1), F(2), and backcross progeny of B6 and A/J parents. Quantitative trait locus (QTL) analysis of 23 AxB and BxA recombinant inbred strains derived from B6 and A/J progenitors indicates a major locus regulating lung PKC-alpha content that maps near the Pkcalpha structural gene on chromosome 11 (D11MIT333; likelihood ratio statistic = 12.5) and a major locus controlling PKC activity that maps on chromosome 3 (D3MIT19; likelihood ratio statistic = 15.4). The chromosome 11 QTL responsible for low PKC-alpha content falls within QTLs for susceptibilities to lung tumorigenesis and ozone-induced toxicity.     

H-Y antigen: No evidence for alleles in wild strains of mice

H-Y antigen(s) coded or controlled by the Y chromosome in a variety of wild mouse strains have been compared with those of the inbred laboratory strains C57BL/6 (B6) and C57BL/10 (B10). H-Y antigen(s) were detected by H-2-restricted cytotoxic T cells from B6 and B10 female mice primed in vivo and boosted in vitro with syngeneic male spleen cells: There was no difference in the degree of H-Y specific lysis of male cells from the C57BL strains and of F₁ hybrids or B6 congenic mice carrying the Y chromosome from the wild mouse strains examined. This result indicated that at the level of target cell specificity the H-Y antigen(s) from wild and laboratory strains were indistinguishable. H-Y antigen(s) were also found to be indistinguishable at the level of the in vitro induction of the anti H-Y cytotoxic response: F₁ female mice, primed in vivo and boosted in vitro with homologous F₁ male cells, all made H-Y-specific responses and where it could be examined, the target cell specificity of the anti-H-Y cytotoxic cells showed that B10 male cells as well as the homologous F₁ male cells (where the Y chromosome was derived from the wild strain) were good targets. Finally, possible differences in H-Y transplantation antigens between the wild strains and the B10 laboratory strain were examined by grafting F₁ male mice, the progeny of B10 females, and wild strain males with B10 male skin. These grafts were not rejected during an observation period of more than 9 months. Taken together, neither the cytotoxic data nor the skin graft data provide any evidence for allelism of H-Y even though the mouse strains examined were collected from widely disparate geographical locations.     

甜菜夜蛾抗高效氯氟氰菊酯近等基因系的构建

将甜菜夜蛾Spodoptera exigua抗性种群雄成虫与敏感种群雌成虫杂交,杂交后代再自交后,用高效氯氟氰菊酯杀死敏感和部分杂合个体的剂量(50 μg/mL)处理4龄幼虫,对1天后存活的幼虫再用250 μg/mL汰选,将存活幼虫发育成的雄成虫与敏感种群的雌成虫回交,再经自交和选育,如此循环6次,获得了甜菜夜蛾抗高效氯氟氰菊酯近等基因系。对该基因系构建过程中各代幼虫的抗性水平和相关生物学特性进行了监测和比较,结果表明获得的抗高效氯氟氰菊酯近等基因系抗性种群的抗药性仍保持较高水平;酯酶同工酶的电泳分析表明抗高效氯氟氰菊酯近等基因系抗性种群与敏感种群图谱相近,而与亲本抗性种群之间存在明显差异。     

Genetic determinants of acute hypoxic ventilation: patterns of inheritance in mice.

Acutely lowering ambient O(2) tension increases ventilation in many mammalian species, including humans and mice. Inheritance patterns among kinships and between mouse strains suggest that a robust genetic influence determines individual hypoxic ventilatory responses (HVR). Here, we tested specific genetic hypotheses to describe the inheritance patterns of HVR phenotypes among two inbred mouse strains and their segregant and nonsegregant progeny. Using whole body plethysmography, we assessed the magnitude and pattern of ventilation in C3H/HeJ (C3) and C57BL/6J (B6) progenitor strains at baseline and during acute (3-5 min) hypoxic [mild hypercapnic hypoxia, inspired O(2) fraction (FI(O(2))) = 0.10] and normoxic (mild hypercapnic normoxia, FI(O(2)) = 0.21) inspirate challenges in mild hypercapnia (inspired CO(2) fraction = 0.03). First- and second-filial generations and two backcross progeny were also studied to assess response distributions of HVR phenotypes relative to the parental strains. Although the minute ventilation (VE) during hypoxia was comparable between the parental strains, breathing frequency (f) and tidal volume were significantly different; C3 mice demonstrated a slow, deep HVR relative to a rapid, shallow phenotype of B6 mice. The HVR profile in B6C3F(1)/J mice suggested that this offspring class represented a third phenotype, distinguishable from the parental strains. The distribution of HVR among backcross and intercross offspring suggested that the inheritance patterns for f and VE during mild hypercapnic hypoxia are consistent with models that incorporate two genetic determinants. These results further suggest that the quantitative genetic expression of alleles derived from C3 and B6 parental strains interact to significantly attenuate individual HVR in the first- and second-filial generations. In conclusion, the genetic control of HVR in this model was shown to exhibit a relatively simple genetic basis in terms of respiratory timing characteristics.     

Cl- currents activated via purinergic receptors in Xenopus follicles

Ionic currents elicited via purinergic receptors located in themembrane of Xenopus follicles werestudied using electrophysiological techniques. Follicles responded toATP-activating inward currents with a fast time course(F_in). InRinger solution, reversal potential (E_rev) ofF_in was 22mV, which did not change with external substitutions ofNa⁺ orK⁺, whereas solutions containing50 or 5% of normal Clconcentration shiftedE_rev to about +4and +60 mV, respectively, and decreasedF_in amplitude,indicating thatF_in was carriedby Cl.F_in had an onsetdelay of ~400 ms, measured by application of a brief jet of ATP froma micropipette positioned near the follicle (50 µm).F_in was inhibitedby 50% in follicles pretreated with pertussis toxin. This suggests a Gprotein-mediated receptor channel pathway.F_in was mimickedby 2-MeSATP and UTP, the potency order (half-maximal effectiveconcentration) was 2-MeSATP (194 nM) > UTP (454 nM) > ATP(1,086 nM). All agonists generatedCl currents and displayedcross-inhibition on the others.F_in activation byacetylcholine also cross-inhibitedF_in-ATPresponses, suggesting that all act on a common channel-activationpathway.

     

Age-dependent response of the electrocardiogram to K(+) channel blockers in mice

Developmental changes in electrocardiogram (ECG) andresponse to selective K⁺ channelblockers were assessed in conscious, unsedated neonatal (days 1, 7, 14) and adult male mice(>60 days of age). Mean sinus R-R interval decreased from 120 ± 3 ms in day 1 to 110 ± 3 ms inday 7, 97 ± 3 ms inday 14, and 81 ± 1 ms in adultmice (P < 0.001 by ANOVA; all 3 groups different from day 1). Inparallel, the mean P-R interval progressively decreased duringdevelopment. Similarly, the mean Q-T interval decreased from 62 ± 2 ms in day 1 to 50 ± 2 ms inday 7, 47 ± 8 ms inday 14 neonatal mice, and 46 ± 2 ms in adult mice (P < 0.001 byANOVA; all 3 groups are significantly different fromday 1).Q-T_c was calculated asQ- interval.Q-T_c significantly shortened from179 ± 4 ms in day 1 to 149 ± 5 ms in day 7 mice(P < 0.001). In addition, the J junction-S-T segment elevation observed in day1 neonatal mice resolved by day14. Dofetilide (0.5 mg/kg), the selective blocker ofthe rapid component of the delayed rectifier(I_Kr) abolished S-T segment elevation and prolonged Q-T andQ-T_c intervals in day 1 neonates but not in adult mice.In contrast, 4-aminopyridine (4-AP, 2.5 mg/kg) had no effect onday 1 neonates but in adults prolongedQ-T and Q-T_c intervals andspecifically decreased the amplitude of a transiently repolarizingwave, which appears as an r' wave at the end of the apparent QRSin adult mice. In conclusion, ECG intervals and configuration changeduring normal postnatal development in the mouse.K⁺ channel blockers affect themouse ECG differently depending on age. These data are consistent withthe previous findings that the dofetilide-sensitiveI_Kr is dominantin day 1 mice, whereas 4-AP-sensitivecurrents, the transiently repolarizingK⁺ current, and the rapidlyactivating, slowly inactivating K⁺current are the dominant K⁺currents in adult mice. This study provides background information useful for assessing abnormal development in transgenic mice.

     

Two-photon molecular excitation imaging of Ca2+ transients in Langendorff-perfused mouse hearts

The ability to image calciumsignals at subcellular levels within the intact depolarizing heartcould provide valuable information toward a more integratedunderstanding of cardiac function. Accordingly, a system combiningtwo-photon excitation with laser-scanning microscopy was developed tomonitor electrically evoked [Ca²⁺]_itransients in individual cardiomyocytes within noncontracting Langendorff-perfused mouse hearts. [Ca²⁺]_itransients were recorded at depths 100 µm from the epicardial surface with the fluorescent indicators rhod-2 or fura-2 in the presence of the excitation-contraction uncoupler cytochalasin D. Evoked[Ca²⁺]_i transients were highly synchronizedamong neighboring cardiomyocytes. At 1 Hz, the times from 90 to 50%(t_90-50%) and from 50 to 10%(t_50-10%) of the peak[Ca²⁺]_i were (means ± SE) 73 ± 4 and 126 ± 10 ms, respectively, and at 2 Hz, 62 ± 3 and94 ± 6 ms (n = 19, P < 0.05 vs.1 Hz) in rhod-2-loaded cardiomyocytes.[Ca²⁺]_i decay was markedly slower infura-2-loaded hearts (t_90-50% at 1 Hz,128 ± 9 ms and at 2 Hz, 88 ± 5 ms;t_50-10% at 1 Hz, 214 ± 18 ms and at2 Hz, 163 ± 7 ms; n = 19, P < 0.05 vs. rhod-2). Fura-2-induced deceleration of[Ca²⁺]_i decline resulted from increasedcytosolic Ca²⁺ buffering, because the kinetics of rhod-2decay resembled those obtained with fura-2 after incorporation of theCa²⁺ chelator BAPTA. Propagating calcium waves and[Ca²⁺]_i amplitude alternans were readilydetected in paced hearts. This approach should be of general utility tomonitor the consequences of genetic and/or functional heterogeneity incellular calcium signaling within whole mouse hearts at tissue depthsthat have been inaccessible to single-photon imaging.

     

登革Ⅱ型病毒经白纹伊蚊滞育卵的传递

采用C6/36细胞培养分离病毒的方法检测感染登革Ⅱ型病毒的白纹伊蚊Aedes albopictus滞育卵孵化的F₁代蚊虫感染率,从第一个生殖营养周期子代蚊虫中未分离到病毒,第二与第三生殖营养周期子代蚊虫最低感染率没有显著性差异（χ²=0.01,P＞0.0 5）,感染子代的批阳性率为9.1%,最低感染率为1∶330;间接免疫荧光检测结果表明感染登革Ⅱ型病毒的白纹伊蚊滞育卵孵化的子代成蚊能通过叮咬将登革病毒传播给敏感乳鼠。这些研究结果表明登革病毒能在媒介滞育卵内存活并传至子代,子代蚊虫能通过叮咬敏感宿主水平传播病毒。     

Effect of prior O2 breathing on ventilatory response to sustained isocapnic hypoxia in adult humans

Honda, Y., H. Tani, A. Masuda, T. Kobayashi, T. Nishino, H. Kimura, S. Masuyama, and T. Kuriyama. Effect of priorO₂ breathing on ventilatoryresponse to sustained isocapnic hypoxia in adult humans.J. Appl. Physiol. 81(4):1627-1632, 1996.Sixteen healthy volunteers breathed 100%O₂ or room air for 10 min in random order, then their ventilatory response to sustained normocapnic hypoxia (80% arterial O₂saturation, as measured with a pulse oximeter) was studied for 20 min.In addition, to detect agents possibly responsible for the respiratorychanges, blood plasma of 10 of the 16 subjects was chemically analyzed.1) Preliminary O₂ breathing uniformly andsubstantially augmented hypoxic ventilatory responses.2) However, the profile ofventilatory response in terms of relative magnitude, i.e., biphasichypoxic ventilatory depression, remained nearly unchanged.3) Augmented ventilatory incrementby prior O₂ breathing wassignificantly correlated with increment in the plasma glutamine level.We conclude that preliminary O₂administration enhances hypoxic ventilatory response without affectingthe biphasic response pattern and speculate that the excitatory aminoacid neurotransmitter glutamate, possibly derived from augmentedglutamine, may, at least in part, play a role in this ventilatoryenhancement.

     

Mast cell activation is not required for induction of airway hyperresponsiveness by ozone in mice

Exposure to ambient ozone(O₃) is associated withincreased exacerbations of asthma. We sought to determine whether mastcell degranulation is induced by in vivo exposure toO₃ in mice and whether mast cellsplay an essential role in the development of pulmonarypathophysiological alterations induced byO₃. For this we exposed mastcell-deficientWBB6F₁-kit^W/kit^W-v(kit^W/kit^W-v)mice and the congenic normalWBB6F₁ (+/+) mice to air or to 1 or 3 parts/million O₃ for 4 h andstudied them at different intervals from 4 to 72 h later. We foundevidence of O₃-induced cutaneous,as well as bronchial, mast cell degranulation. Polymorphonuclear cellinflux into the pulmonary parenchyma was observed after exposure to 1 part/milllion O₃ only in mice thatpossessed mast cells. Airway hyperresponsiveness to intravenousmethacholine measured in vivo under pentobarbital anesthesia wasobserved in bothkit^W/kit^W-vand +/+ mice after exposure to O₃.Thus, although mast cells are activated in vivo byO₃ and participate inO₃-induced polymorphonuclear cellinfiltration into the pulmonary parenchyma, they do not participate detectably in the development ofO₃-induced airwayhyperresponsiveness in mice.

     

Genotype-specific environmental impact on the variance of blood values in inbred and F1 hybrid mice

Mice are important models for biomedical research because of the possibility of standardizing genetic background and environmental conditions, which both affect phenotypic variability. Inbred mouse strains as well as F₁ hybrid mice are routinely used as genetically defined animal models; however, only a few studies investigated the variance of phenotypic parameters in inbred versus F₁ hybrid mice and the potential interference of the genetic background with different housing conditions. Thus, we analyzed the ranges of clinical chemical and hematologic parameters in C3H and C57BL/6 inbred mice and their reciprocal F₁ hybrids (B6C3F1, C3B6F1) in two different mouse facilities. Two thirds of the blood parameters examined in the same strain differed between the facilities for both the inbred strains and the F₁ hybrid lines. The relation of the values between inbred and F₁ hybrid mice was also affected by the facility. The variance of blood parameters in F₁ hybrid mice compared with their parental inbred strains was inconsistent in one facility but generally smaller in the other facility. A subsequent study of F₁ hybrid animals derived from the parental strains C3H and BALB/c, which was done in the latter housing unit, detected no general difference in the variance of blood parameters between F₁ hybrid and inbred mice. Our study clearly demonstrates the possibility of major interactions between genotype and environment regarding the variance of clinical chemical and hematologic parameters.     

Identity of esterase-22 and egasyn,the protein which complexes with microsomal β-glucuronidase

Recent experiments have demonstrated that egasyn not only sequesters -glucuronidase in microsomes by forming high molecular weight complexes with -glucuronidase, but also has carboxyl esterase activity. We have found several new phenotypes of egasyn-esterase after electrophoresis and isoelectric focusing of liver homogenates and purified egasyn of inbred and wild mouse strains. Several phenotypes corresponded in relative mobility and relative isoelectric point among inbred strains to that recently reported for esterase-22 by Eisenhardt and von Deimling [(1982). Comp. Biochem. Physiol. 73B:719]. This genetic evidence, plus a wide variety of comparative biochemical and physiological data, indicates that egasyn is identical to esterase-22. Both parental types of egasyn isozymes are expressed in heterozygous F₁ progeny, suggesting that alterations in the egasyn structural gene are responsible for the altered isoelectric points. Also, egasyn is a monomer since no new esterase bands appear in F₁ progeny. The variants in isoelectric point of egasyn map at or near the egasyn (Eg) gene within the esterases of cluster 1 near Es-9 on chromosome 8.This work was supported by Grant GM-33559 from the National Institutes of Health.