Ca(2+) -activated K(+) current is essential for maintaining excitability and gene transcription in early embryonic cardiomyocytes.

AIM: Activity of early embryonic cardiomyocytes relies on spontaneous Ca(2+) oscillations that are induced by interplay between sarcoplasmic reticulum (SR) - Ca(2+) release and ion currents of the plasma membrane. In a variety of cell types, Ca(2+) -activated K(+) current (IK(Ca) ) serves as a link between Ca(2+) signals and membrane voltage. This study aimed to determine the role of IK (Ca) in developing cardiomyocytes. METHODS: Ion currents and membrane voltage of embryonic (E9-11) mouse cardiomyocytes were measured by patch clamp; [Ca(2+) ]i signals by confocal microscopy. Transcription of specific genes was measured with RT-qPCR and Ca(2+) -dependent transcriptional activity using NFAT-luciferase assay. Myocyte structure was assessed with antibody labelling and confocal microscopy. RESULTS: E9-11 cardiomyocytes express small conductance (SK) channel subunits SK2 and SK3 and have a functional apamin-sensitive K(+) current, which is also sensitive to changes in cytosolic [Ca(2+) ]i . In spontaneously active cardiomyocytes, inhibition of IK (Ca) changed action and resting potentials, reduced SR Ca(2+) load and suppressed the amplitude and the frequency of spontaneously evoked Ca(2+) oscillations. Apamin caused dose-dependent suppression of NFAT-luciferase reporter activity, induced downregulation of a pattern of genes vital for cardiomyocyte development and triggered changes in the myocyte morphology. CONCLUSION: The results show that apamin-sensitive IK (Ca) is required for maintaining excitability and activity of the developing cardiomyocytes as well as having a fundamental role in promoting Ca(2+) - dependent gene expression.

Endothelin-1 signalling controls early embryonic heart rate in vitro and in vivo.

AIM: Spontaneous activity of embryonic cardiomyocytes originates from sarcoplasmic reticulum (SR) Ca(2+) release during early cardiogenesis. However, the regulation of heart rate during embryonic development is still not clear. The aim of this study was to determine how endothelin-1 (ET-1) affects the heart rate of embryonic mice, as well as the pathway through which it exerts its effects. METHODS: The effects of ET-1 and ET-1 receptor inhibition on cardiac contraction were studied using confocal Ca(2+) imaging of isolated mouse embryonic ventricular cardiomyocytes and ultrasonographic examination of embryonic cardiac contractions in utero. In addition, the amount of ET-1 peptide and ET receptor a (ETa) and b (ETb) mRNA levels were measured during different stages of development of the cardiac muscle. RESULTS: High ET-1 concentration and expression of both ETa and ETb receptors was observed in early cardiac tissue. ET-1 was found to increase the frequency of spontaneous Ca(2+) oscillations in E10.5 embryonic cardiomyocytes in vitro. Non-specific inhibition of ET receptors with tezosentan caused arrhythmia and bradycardia in isolated embryonic cardiomyocytes and in whole embryonic hearts both in vitro (E10.5) and in utero (E12.5). ET-1-mediated stimulation of early heart rate was found to occur via ETb receptors and subsequent inositol trisphosphate receptor activation and increased SR Ca(2+) leak. CONCLUSION: Endothelin-1 is required to maintain a sufficient heart rate, as well as to prevent arrhythmia during early development of the mouse heart. This is achieved through ETb receptor, which stimulates Ca(2+) leak through IP3 receptors.

A note on the reproductive success of primiparous blue fox vixens in social groups.

Our aim was to compare traditional breeding system, i.e. artificial insemination with singly-housing, to alternative breeding systems in farmed blue fox (Alopex lagopus or Vulpes lagopus) vixens. At the age of 7 weeks (i.e. at weaning), 48 randomly selected female blue fox cubs were divided into four experimental groups: (1) artificially inseminated singly-housed vixens in cages (AI-SC), (2) artificially inseminated pair-housed vixens in double-cages (AI-PC), (3) naturally bred pair-housed vixens with a male in triple-cages (NB-PC), and (4) naturally bred pair-housed vixens with a male in outdoor enclosures (NB-PE). The cubs were counted on days 1, 2, 3, 7, 14 and 49 postpartum and the reproductive performance per breeding (RPB) and per mated vixens (RPM) with its subcomponents were formed from these data. RPB was zero in both NB groups. In AI-PC and AI-SC, RPB was 1.3+/-2.5 and 4.1+/-4.7 cubs, respectively. RPB and the percentage of vixens that weaned cubs were lower in NB-PC and NB-PE than in AI-PC. In AI groups, both RPB and RPM at weaning tended to be better in singly-housed than in pair-housed blue fox vixens. No statistically significant differences were found between AI groups in the percentage of vixens without oestrus, barren vixens, vixens that lost all cubs or weaned at least one cub. Only in one pair (AI-PC) both vixens displayed communal breeding and weaned cubs. The present results show that vixens in traditional breeding system had better RPM than in any of the studied pair-housing systems. The current blue fox population has been effectively selected for cage-breeding and artificial reproduction, and therefore blue foxes generally reproduce well with artificial insemination after careful detection of oestrus in traditional breeding conditions.

Group housing in row cages: an alternative housing system for juvenile mink.

We studied a group housing system as an alternative to the traditional pair housing of juvenile mink. The focus was on both the welfare and production of mink. The pairs were housed in standard mink cages, whereas the groups were in row cage systems consisting of three standard mink cages connected to each other. The welfare of the mink was evaluated by behavioural observations (stereotypies and social contacts), evaluation of the incidence of scars assumed to be caused by biting, and adrenal function (serum cortisol level after adrenocorticotropic hormone (ACTH) administration and adrenal mass). Feed consumption, pelt length, quality and price were used for comparing the two housing systems from the economic point of view. Although the incidence of scars showed that there might have been more aggressive behaviour among the group-housed than among the pair-housed mink, this was not observed unambiguously in behavioural observations, and, at least, aggression did not cause mortality or serious injuries to the animals as has been observed in some earlier studies. In addition, the housing system did not affect pelt size, and, although the quality of the pelts was slightly lower in the group than in pair-housed mink, there was only a tendency for lower pelt prices. The lower pelt prices in the group-housed mink might even be partially compensated for by the group-housed mink eating 10% to 20% less in the late autumn, due to thermoregulatory benefits, than their pair-housed conspecifics. The results on the frequency of stereotypic behaviour (but not adrenal function) suggest that the group-housed animals were possibly less stressed than the pair-housed animals. Group housing of juvenile farmed mink in a row cage system cannot be recommended before the effects on welfare and production are clarified in further studies.

The effect of a combination of permanent breeding cage and low housing density on the reproductive success of farmed blue foxes.

Social factors are known to affect the reproduction of many canids both in the wild and in farms. For example, reproduction in farmed silver foxes is regulated by social stress; foxes seem to benefit from noncramped housing conditions and permanent breeding cages. However, no comparable studies have been carried out in farmed blue foxes. The aim of our experiment was to create an alternative, improved, economically viable and practical housing solution for blue foxes. Therefore, we compared reproductive performance of blue foxes in permanent breeding cages with low animal densities (L group, N=79) and traditional housing with its changing social environment with high animal density (H group, N=74). The reproductive data from the L and H groups were compared separately for primiparous and multiparous vixens because the reproductive performance in primiparous vixens was substantially lower (P<0.001) than in multiparous vixens. Altogether, 41 and 39% of the primiparous vixens in the H and L group whelped (P>0.05), but only 28 and 34%, respectively, weaned at least one cub (P>0.05), i.e., 72 and 66% of the primiparous vixens did not reproduce in the H and L group, respectively (P>0.05). The total reproductive performance, expressed as cubs at weaning per breeding female, was 1.7+/-3.5 for the H and 1.6+/-2.9 for the L group (P>0.05). In the primiparous vixens, the only statistically significant difference observed between the two housing systems was that the onset of oestrus occurred five days earlier in the H than in the L group (P<0.05). All multiparous vixens in the L group exhibited oestrus compared to 94% in the H group (P>0.05). Furthermore, there was a nonsignificant (ns) trend for fewer barren females (9% versus 17%), more successfully reproducing vixens (83% versus 74%) and a higher number of live-born cubs (10.9+/-4.7 versus 9.4+/-3.9) in the L than in H group in the multiparous vixens (for all P>0.05). This resulted in 1.7 and 1.4 cubs more per breeding and per mated vixen, respectively, at weaning in the L group (7.3+/-5.0) compared to the H group (5.6+/-4.2), but also this difference was nonsignificant. Although our present results lack statistical significance, they are promising enough to encourage field experiments with sufficiently large number of animals to prove or disprove these preliminary findings that lower housing density and permanent breeding cage, together or separately, may enhance reproduction particularly in multiparous blue fox vixens.