Strain-specific immunomodulatory effects of Lactobacillus plantarum strains on birch-pollen-allergic subjects out of season.

BACKGROUND: Allergic diseases are increasing world-wide, and according to the hygiene hypothesis may be related to a decreased exposure to environmental bacteria. Probiotic bacteria are recognized for their immunomodulating properties, and may benefit allergy patients. In vitro studies reveal immunomodulatory effects that are strain dependent. Differential immunomodulatory in vitro capacities cannot be extrapolated directly to in vivo efficacy. Thus, in vitro screening should preferably be followed by a comparative analysis of the selected immunomodulatory strains in an in vivo setting. OBJECTIVE: We selected five Lactobacillus strains on their IL-10-inducing capacity, and evaluated the immunomodulatory properties in birch-pollen-allergic subjects outside the hayfever season, with a reduction of IL-13 as the primary outcome. METHODS: A double-blind, placebo-controlled parallel study was performed in which 62 subjects with a proven birch-pollen allergy consumed one of five different probiotic yoghurts containing four Lactobacillus plantarum strains and one Lactobacillus casei strain or a placebo yoghurt. Blood samples were collected at the start and after 4 weeks. Several immune parameters were determined in serum and peripheral blood mononuclear cell cultures (PBMC) derived from these subjects. Results A decrease in birch-pollen-specific IgE was found for four probiotic strains. L. casei Shirota reduced the number of CD16(+) /CD56(+) cells in peripheral blood mononuclear cells. For strain L. plantarum CBS125632, the decrease in IgE coincided with significant decreases in IL-5 and IL-13 production by αCD3/αCD28-stimulated PBMC cultures. CONCLUSION AND CLINICAL RELEVANCE: Subjects with seasonal allergy can be used to determine immunomodulatory responses outside the pollen season within a 4-week study period. L. plantarum CBS125632 decreased several immune markers related to allergy, and may have the potential to alleviate the severity of seasonal allergy symptoms.

Role of Rho-associated protein kinase in tone and calcium sensitivity of cannulated rat mesenteric small arteries.

The regulation of vascular tone includes modulation of contractile element calcium sensitivity. We tested the involvement of the Rho-associated protein kinase p160ROCK in tone and calcium sensitivity of cannulated rat mesenteric small arteries. These vessels developed basal tone and showed myogenic responses upon pressure steps, resulting from an increase in calcium in combination with a high contractile element calcium sensitivity. Y-27632, believed to be a specific p160ROCK inhibitor, caused concentration-dependent inhibition of basal tone, with near full inhibition at 3 microM. At this concentration, myogenic responses were absent and stepwise pressure elevation resulted in severe vascular distension. Y-27632 did not affect pressure-induced changes in intracellular calcium but rather reduced pressure-induced as well as phenylephrine-induced calcium sensitisation. Thus in the presence of the blocker, for a given calcium concentration, tone was greatly reduced, and the divergence in sensitivity between pressure and phenylephrine as stimuli on the one hand and potassium on the other disappeared. K+ (125 mM) and ionomycin still caused contraction in the presence of the p160ROCK blocker. These data show that in pressurised small arteries the Rho-p160ROCK pathway is active in the absence of vasoconstrictors, keeping the vessels in a state of high calcium sensitivity and basal tone.

Role of protein kinase C in myogenic calcium-contraction coupling of rat cannulated mesenteric small arteries.

1. The present study was designed to determine the role of protein kinase C (PKC) in the myogenic response of small arteries. In particular, we tested whether inhibition of PKC reverses the previously found pressure-induced elevation of contractile element calcium sensitivity. 2. Rat mesenteric small arteries were cannulated and pressurized. The internal diameter was continuously monitored with a video camera and intracellular calcium levels were measured by means of fura-2. Myogenic responses were observed when the pressure was raised stepwise from 20 to 60 and then to 100 mmHg in physiological saline solution and during application of phenylephrine (0.1 or 1 micromol/L) or potassium (36 mmol/L). 3. The PKC inhibitors H-7 (20 micromol/L), staurosporine (100 nmol/L) and calphostin C (10 nmol/L) all completely abolished the myogenic response. Whereas staurosporine caused an ongoing reduction in intracellular calcium, pressure-induced calcium transients were not affected by either H-7 or calphostin C. In particular, the slope of the wall tension-calcium relationship remained similar in the presence of both H-7 and calphostin C, despite an upward shift of this relationship to higher calcium levels in the case of calphostin C. 4. These results show that activity of PKC isoform(s) is essential for myogenic calcium-contraction coupling.

Organoid culture of cannulated rat resistance arteries: effect of serum factors on vasoactivity and remodeling.

We developed an organoid culture technique to study the mechanisms involved in arterial remodeling. Resistance arteries were isolated from rat cremaster muscle and mounted in a pressure myograph at 75 mmHg. Vessels were studied during a 4-day culture period in DMEM with either 2% albumin, 10% heat-inactivated FCS (HI-FCS) or 10% dialyzed HI-FCS (12 kDa cut off) added to the perfusate. The albumin group showed a gradual loss of endothelial function and integrity, whereas smooth muscle agonist and myogenic responses were retained. No remodeling was observed. Vessels cultured in the presence of serum showed a progressive constriction. Smooth muscle responses and substance P-induced endothelium-dependent dilation were maintained. An inward remodeling of 17 +/- 4% in the HI-FCS group and 26 +/- 3% in the dialyzed HI-FCS group was found, while media cross-sectional areas were unchanged. These data show that pressurized resistance arteries can be maintained in culture for several days and undergo eutrophic remodeling in vitro in the presence of high molecular weight serum factors.

PKC-dependent preconditioning with norepinephrine protects sarcoplasmic reticulum function in rat trabeculae following metabolic inhibition.

The authors have previously shown that norepinephrine (NE) pretreatment attenuates Ca2+ overloading in cardiac rat trabeculae during metabolic inhibition, and improves contractile function during a subsequent recovery period. The present study investigated: (i) whether protection of sarcoplasmic reticulum (SR) function during metabolic inhibition (MI) is involved in the preconditioning-like effect of NE-pretreatment, and (ii) whether or not this process is PKC-dependent. A 15 min preincubation period was used with 1 micromol/l exogenous NE to precondition isolated, superfused rat trabeculae against contractile dysfunctioning following 40 min of MI in 2 mmol/l NaCN containing Tyrode (gassed with 95% O2/5% CO2; pH 7.4, 24 degrees C) without glucose at 1-Hz stimulation frequency. Contractile recovery was studied during a subsequent 60 min recovery period (RP) in glucose containing Tyrode at 0.2 Hz. Force and intracellular free calcium ([Ca2+]ii) were monitored throughout the experimental protocol. Pretreatment of trabeculae with NE (group NE) substantially diminished the Ca2+ rise from the onset of rigor development during MI, compared to preparations which were pretreated with NE, in the presence of specific PKC blocker chelerythrine (2 micromol/l; group NE+CHEL). After 40 min of MI, resting [Ca2+]i in group NE and NE+CHEL was increased to 0.50+/-0.03 and 2.08+/-0.20 micromol/l, respectively (P<0.05), whereas total intracellular ATP levels were similar in both groups (approximately 0.20 micromol/g dry wt). This corresponded with an increase in active force development (119%) and a decrease in twitch force relaxation time (77%) during subsequent RP in group NE, compared to pre-MI values of the same group. In contrast, a significant decrease in force recovery (54%) and an increase in twitch force relaxation time (123%) was observed in group NE+CHEL. Values for [Ca2+]i, contractile recovery, and twitch force relaxation time in untreated controls as well as CHEL preparations corresponded to those measured in the NE+CHEL group. Rapid cooling contractures (RCCs), which provide information on both SR-Ca2+ loading and Ca2+ re-uptake activity, revealed a 2-fold higher SR Ca2+ content during RP in group NE compared to controls and group NE+CHEL. In addition, kinetic analysis of the RCC rewarming spike (RWS) showed that this was accompanied by greater than a 28% increase in the maximum rate of RWS relaxation (-dF/dt/rws) in group NE compared to group NE+CHEL. The change of -dF/dt/rws in the NE group during RP following MI persisted after SR Ca2+-release channel blockade by ryanodine treatment (100 micromol/l), which suggests involvement of NE-induced, PKC-dependent protection of SR Ca2+-ATPase activity. The results of the present study point to an inverse relationship between the Ca2+ rise during MI and SR functioning, in which PKC appears to play a key role. It is concluded that the preconditioning-like effect of NE-pretreatment on contractile recovery is at least partly mediated by protection of SR function.

Differential effects of norepinephrine on contractile recovery of rat trabeculae following metabolic inhibition.

We have recently shown that norepinephrine (NE) pretreatment attenuates Ca2+ overloading in cardiac rat trabeculae during metabolic inhibition (MI) with NaCN (2 mmol/l), and improves contractile recovery during a subsequent recovery period (RP). In the present study, we investigated the effects of the continuous presence of NE (1 micro mol/l), i.e. before, during and after MI, on Ca2+ homeostasis maintenance and contractile recovery in the same model at 24 degrees C. In addition, we tested the effects of NE when only present in the rigor period during MI. The continuous presence of NE both before (30 min) and during MI (120 min)+RP (60 min) (group NE-I) significantly increased the proportion of trabeculae that resumed to contract during RP from 46+/-4% (mean+/-s.e.m.) in controls to 82+/-8%. The Ca2+ rise at the end of MI in failing control trabeculae (1.85+/-0.04 micro mol/l) was more than doubled compared to recovering control preparations (0.78+/-0.02 micro mol/l). However, the time-course of the Ca2+ rise during MI in recovering and failing NE-I preparations was similar, and eventually of the same magnitude as observed in failing control preparations (1.6+/-0. 02 and 1.85+/-0.07 micro mol/l, respectively). In contrast, when NE was present only in the rigor period during MI (group NE-II) the proportion of recovering preparations decreased significantly to 27+/-9%. Similar to the control group, recovering and failing preparations in group NE-II could be distinguished by a differential course in the Ca2+ rise during MI. The results show that when NE is present both before and during MI+RP, (i) recovery probability following MI is still improved, in spite of the deleterious effect on contractile recovery of the presence of NE in the rigor during MI, and (ii) there is no relationship between the magnitude of Ca2+ overload during MI and recovery probability during RP.

Norepinephrine pretreatment attenuates Ca2+ overloading in rat trabeculae during subsequent metabolic inhibition: improved contractile recovery via an alpha 1-adrenergic, PKC-dependent signaling mechanism.

The present study was designed in order to investigate more precisely the role of calcium homeostasis maintenance in protein kinase C (PKC) mediated preconditioning. We used a 15 min pre-incubation period, with 1 mumol/l exogenous norepinephrine (NE) to pharmacologically precondition isolated, superfused rat trabeculae against contractile dysfunctioning following 120 min of metabolic inhibition (MI, in 2 mmol/l CN- containing Tyrode without glucose at 1 Hz stimulation frequency). Contractile recovery was studied during a subsequent 60 min recovery period (RP, in glucose containing Tyrode at 0.2 Hz). Tyrode was gassed with 95%, O2/ 5% CO2 and kept at a constant temperature of 24 degrees C. Force and intracellular free calcium ([Ca2+]i) were monitored throughout the experimental protocol; [Ca2+]i was measured using fura-2. Pretreatment with NE (group NE-I) significantly increased the fraction of trabeculae that resumed to contract during RP, from 36 +/- 13% (mean +/- S.E.M.) in controls to 82 +/- 10% (P < 0.05). In correspondence with this, NE-pretreatment increased the proportion of trabeculae in which the Ca2+ rise from the onset of rigor development during MI was attenuated. After 40 min of MI [Ca2+]i in the failing control, as well as failing group NE-I, trabeculae (1.08 +/- 0.20 and 1.51 +/- 0.26 mumol/l, respectively) was increased significantly compared to the mean value registered in the recovering preparations of these groups (0.34 +/- 0.04 mumol/l: P < 0.05). Specific inhibition of PKC with 2 mumol/l chelerythrine (group NE-IV) almost completely blocked the protection induced by NE-pretreatment, including its protective action against Ca2+ overload, i.e. the fraction of trabeculae that resumed to contract during RP returned to untreated control level (46 +/- 11%: P < 0.05 v group NE-I). Also in this case [Ca2+]i in the failing group NE-IV trabeculae after 40 min of MI was increased substantially, compared to the value measured in the recovering preparations (4.75 +/- 1.00 and 0.60 +/- 0.08 mumol/ l, respectively). The relative importance of both alpha-adrenergic and beta-adrenergic receptor pathways in this preconditioning-like effect of NE-pretreatment, was investigated using specific blockers. The results point to an alpha 1-adrenergic receptor mediated signaling mechanism, which enhances PKC-dependent control of [Ca2+]i from the onset of rigor development during MI.

The effect of hyperosmolality on the rate of heat production of quiescent trabeculae isolated from the rat heart.

We have measured the rate of heat production of isolated, quiescent, right ventricular trabeculae of the rat under isosmotic and hyperosmotic conditions, using a microcalorimetric technique. In parallel experiments, we measured force production and intracellular calcium concentration ([Ca2+]i). The rate of resting heat production under isosmotic conditions (mean +/- SEM, n = 32) was 100 +/- 7 mW (g dry wt)-1; it increased sigmoidally with osmolality, reaching a peak that was about four times the isosmotic value at about twice normal osmotic pressure. The hyperosmotic thermal response was: (a) abolished by anoxia, (b) attenuated by procaine, (c) insensitive to verapamil, ouabain, and external calcium concentration, and (d) absent in chemically skinned trabeculae bathed in low-Ca2+ "relaxing solution." Active force production was inhibited at all osmolalities above isosmotic. Passive (tonic) force increased to, at most, 15% of the peak active force developed under isosmotic conditions while [Ca2+]i increased, at most, 30% above its isosmotic value. We infer that hyperosmotic stimulation of resting cardiac heat production reflects, in large part, greatly increased activity of the sarcoplasmic reticular Ca2+ ATPase in the face of increased efflux via a procaine-inhibitable Ca(2+)-release channel.

Exposure of energy-depleted rat trabeculae to low pH improves contractile recovery: role of calcium.

The beneficial effect of low pH during cardiac ischemia on reperfusion injury has often been attributed to its energy-saving effect due to inhibition of contraction. The role of low pH on Ca2+ accumulation and muscle tension was assessed in energy-depleted tissue by changing the pH of the medium from 7.4 to 6.2 at onset of rigor development during metabolic inhibition (MI), i.e., in the energy-depleted phase. Cytosolic free Ca2+ ([Ca2+]i) and intracellular H+ (pHi) were measured in rat trabeculae at 20 degrees C with fura 2 and 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein, respectively, and tension was recorded. The preparations were energy depleted by stimulation at 1 Hz in glucose-free Tyrode solution with 2 mM NaCN. Rigor developed within 20 min, indicating energy depletion. Resting [Ca2+]i was followed during 50 min (group I) or 100 min (group II) of rigor, and recovery was followed for 60 min in glucose-containing Tyrode solution at 0.2-Hz stimulation. Resting [Ca2+]i rose within 50 min (group I) but stabilized in the 50- to 100-min period (group II). All preparations from group I (n = 5) resumed contraction in the recovery period but in group II (n = 10) 70% failed to recover, and [Ca2+]i remained elevated compared with those that recovered. An extracellular pH of 6.2, resulting in similar pHi, from onset of rigor development (group III) led to only a modest rise in [Ca2+]i during the 100-min rigor period, and all preparations resumed contraction after approximately 3 min in normal medium. ATP was very low in all groups at the end of MI but was still significantly lower in group II than in groups I and III. A beneficial energy-sparing effect of low pH during the rigor phase can therefore not be excluded. We conclude that 1) the capacity of trabeculae to recover from MI depends on the time period and magnitude of the [Ca2+]i rise in the energy-depleted phase and 2) low pH in energy-depleted trabeculae protects against Ca overload, improving recovery after normalization of perfusion conditions.