Selective peripheral regulation of noradrenaline and adrenaline release by nitric oxide

Cardiovascular responses to electrical stimulation of sympathetic nerves in the pithed mouse

The pithed rat model has been used extensively to study peripheral cardiovascular responses to electrical stimulation of the sympathetic nervous system, as pithing eliminates central and reflex effects. However, since the transgenic mouse has become a standard and economical model organism, an electrically stimulated pithed mouse would facilitate a variety of studies. We have developed surgical techniques, drug doses and stimulation parameters for an electrically stimulated pithed mouse to study peripheral sympathetic nerve effects on blood pressure. Similar to the pithed rat, the pithed mouse showed voltage and frequency-dependent blood pressure responses to a pulsed train of electrical stimuli. In addition, alpha-adrenergic stimulation with phenylephrine gave a marked systolic pressor response, while the beta2 agonist salbutamol lowered diastolic blood pressure. Furthermore, pithed transgenic mice unable to synthesize catecholamines in adrenergic cells displayed smaller pressor responses than pithed control mice. In summary, the electrically stimulated pithed mouse can be used to study peripheral effects of the sympathetic system on cardiovascular dynamics unencumbered by central responses.

Sex difference in norepinephrine surge in response to psychological stress through nitric oxide in rats

Psychological stress elevates blood pressure through sympathetic nerve activation. This pressor response is supposedly associated with cardiovascular events. We investigated a sex difference in the pressor response and norepinephrine surge to cage-switch stress in rats. Wistar male and female rats were catheterized for blood pressure monitoring and blood sampling. Six days post-surgery, the rats were exposed to the cage-switch stress and blood samples were collected at rest and 30 min after the start of the stress. The stress-induced pressor response was greater in the male than in the female rats. The stress significantly increased the norepinephrine level in the male, but not in the female rats. Pre-treatment with N(G)-nitro-l-arginine methyl ester (L-NAME), a nitric oxide (NO) synthase inhibitor, attenuated the norepinephrine response significantly in the male rats. There was no sex difference in the endothelial NO synthase expression in the gastrocnemius muscle. However the phosphorylation at serine 1177, a marker for eNOS activation, was higher in the male than in the female rats. These results suggest that NO is involved in the norepinephrine surge to psychological stress in the male rats, but not in the female rats. This is the first report on a sex difference in the norepinephrine surge in response to psychological stress through NO, in association with pressor response.

Paradoxes of immunosuppression in mouse models of withdrawal

Previously, our laboratory showed that either abrupt (AW) or precipitated withdrawal (PW) from morphine led to profound suppression of murine splenic antibody responses to sheep red blood cells at 24 h post-withdrawal. In the present studies, we examined the immune mechanisms mediating suppression at that time point. A co-culture method was used to examine whether cells from withdrawn mice had (1) a deficit in function and/or (2) contained populations of suppressor cells. To examine the first hypothesis, cells from normal mice were co-cultured with cells from withdrawn mice in a 1:3 ratio (normal/withdrawn). To test the second hypothesis, the ratio was reversed. The results were paradoxical. Co-culture of cells in a 1:3 ratio showed that spleen cells from withdrawn mice had a deficit in macrophage function. Spleen cells from withdrawn mice also showed decreased mRNA levels of IL-1beta, IL-1-Ra, and TNF-alpha and a suppression of co-stimulatory molecule expression. To examine the second hypothesis, cells were co-cultured in a 3:1 ratio (normal/withdrawn). In this paradigm, spleen cells from abrupt withdrawn mice were shown to contain populations of both suppressor macrophages and B-cells. In vivo experiments carried out on mice 24 h post-withdrawal showed increased sensitivity to the lethal effects of LPS and increased production of TNF-alpha, implying a state of macrophage activation. Thus evidence for both suppressed and activated macrophages has been obtained in mice 24 h after abrupt withdrawal from morphine.

Nitric oxide decreases the biological activity of norepinephrine resulting in altered vascular tone in the rat mesenteric arterial bed

Nitric oxide (NO) reacts with catecholamines resulting in their deactivation. In this study, we demonstrated that coincubation of NO donors with sympathetic neurotransmitters decreased the amount of norepinephrine detected but not ATP or neuropeptide Y (NPY). Furthermore, we found that the ability of norepinephrine to increase perfusion pressure in the isolated perfused mesenteric arterial bed of the rat was attenuated by the incubation of norepinephrine with the NO donor diethylamine NONOate. Conversely, the vasoconstrictive ability of NPY and ATP was unaffected by incubation with NONOate. Periarterial nerve stimulation in the presence of the NO synthase (NOS) inhibitor Nω-nitro-l-arginine methyl ester (l-NAME) resulted in an increase in both perfusion pressure response and norepinephrine levels. This was prevented by l-arginine, demonstrating that the effects of l-NAME were indeed specific to the inhibition of NOS. To confirm that NO was not altering the release of norepinephrine from the sympathetic nerve via presynaptic activation of guanylate cyclase, we repeated the experiments in the presence of the guanylate cyclase inhibitor 1H-[1,2,4]oxadiazolo[4,3-a]-quinoxaloine-one (ODQ). Unlike l-NAME, ODQ infusion did not increase norepinephrine overflow, demonstrating that modulation of norepinephrine by NO at the vascular neuroeffector junction of the rat mesenteric vascular bed is not the result of presynaptic guanylate cyclase activation. These results demonstrate that, in addition to being a direct vasodilatator, NO can also alter vascular reactivity at the sympathetic neuroeffector junction in the rat mesenteric bed by deactivating the vasoconstrictor norepinephrine.