Properties of cyclic nucleotide phosphodiesterase from plasma membranes of rat synaptosomes at early stages of acute radiation injury

Phosphodiesterase of cyclic nucleotides from membranes of rat brain synaptosomes hydrolyzes cAMP and cGMP; the maximal rate of cAMP hydrolysis is 2.5 times higher than the values of the analogous index for GMP. The enzyme is found to be activated by calmodulin. A different direction of changes in the rate of cAMP and cGMP hydrolysis is observed 1 h after total X-ray irradiation. The process of cAMP hydrolysis by phosphodiesterase is characterized by positive cooperativity which is also shown after irradiation and for the process of cGMP hydrolysis. It is established that enzyme inhibition by the reaction product takes place both in control and after irradiation.     

Diverse directional changes of cGMP relative to cAMP in E. coli.

The relationships of the changes of cAMP and cGMP concentrations in $\text{E. coli}$ varied as a function of experimental conditions. (1) Cells starved for carbon source for a short time period had high cAMP and low cGMP concentrations. Addition of carbon source (succinate, glucose or α-methyl glucoside) led to a decrease in cAMP and an increase in cGMP (bi-directional change). (2) Washed cells starved for glucose for long time periods had low cAMP levels which did not change on glucose addition. Addition of succinate or glucose to such cells led to a transient increase in cGMP levels (uncoupled change). The cGMP concentration peaked at 15 minutes or 1 hour after glucose or succinate addition, respectively. (3) Sham shift-up experiments (addition of α-methyl glucoside to cultures growing in succinate) in $\text{E. coli}$ 1100 and CA 8000 showed decreases in cGMP levels in both strains; however, cAMP levels increased in the former (bi-directional change) and decreased in the latter (unidirectional change).     

Structure and rearrangements in the carboxy-terminal region of SpIH channels

Hyperpolarization-activated cyclic nucleotide-modulated (HCN) ion channels regulate the spontaneous firing activity and electrical excitability of many cardiac and neuronal cells. The modulation of HCN channel opening by the direct binding of cAMP underlies many physiological processes such as the autonomic regulation of the heart rate. Here we use a combination of X-ray crystallography and electrophysiology to study the allosteric mechanism for cAMP modulation of HCN channels. SpIH is an invertebrate HCN channel that is activated fully by cAMP, but only partially by cGMP. We exploited the partial agonist action of cGMP on SpIH to reveal the molecular mechanism for cGMP specificity of many cyclic nucleotide-regulated enzymes. Our results also elaborate a mechanism for the allosteric conformational change in the cyclic nucleotide-binding domain and a mechanism for partial agonist action. These mechanisms will likely extend to other cyclic nucleotide-regulated channels and enzymes as well.     

Changes in the cyclic nucleotides of rat thyroid, pituitary and plasma caused by methylthiouracil treatment.

Changes in the content of cyclic nucleotides (cAMP and cGMP) and related enzyme activities were observed in the rat thyroid, pituitary and plasma during the prolonged increase of endogenous TSH produced by treatment with methylthiouracil (MTU). Experiments were performed after 4 weeks treatment with MTU. The wet weight and cAMP content per wet weight of the thyroid increased 3 and 1.4 times respectively, but cGMP showed a slight decrease. Pituitary weight increased 1.3 times, but cAMP and cGMP content did not change. The cAMP level in plasma also increased about 1.3 times, but cGMP did not increase. The cAMP-phosphodiesterase activity in the thyroid, pituitary and plasma was increased 1.9, 1.4 and 1.3 times respectively after MTU treatment, while cGMP-phosphodiesterase showed no significant change. ATPase activity in the thyroid and pituitary was also increased more than 1.5 times after MTU treatment, while 5'-nucleotidase activitity decreased remarkably. These data indicate that the metabolism of the cyclic nucleotide system in the thyroid is stimulated by TSH.     

Hyperkalemia, hyperglycemia, and plasma levels of cyclic AMP and cyclic GMP induced by portal vein injection of cyclic nucleotides and their butyryl derivatives into dogs

The levels of serum potassium, blood glucose, and plasma adenosine cyclic 3':5'-monophosphate (cAMP) and guanosine cyclic 3':5'-monophosphate (cGMP) were studied after the portal vein injection of cyclic nucleotides and their derivatives, (cAMP, cGMP, N6, O2'-dibutyryl adenosine 3':5'-monophosphate (DBcAMP), N6-monobutyryl adenosine cyclic 3':5'-monophosphate (NMBcAMP), and O2'-monobutyryl adenosine cyclic 3':5'-monophosphate (OMBcAMP), into dogs. Dose-related hyperglycemic responses were observed after the injection of DBcAMP (1-8 mg/kg). Transient and prominent hyperkalemia and hyperglycemia were caused by the injection of DBcAMP, NMBcAMP, and OMBcAMP (4 mg/kg). The hyperkalemic response was highest with NMBcAMP (1.22 mequiv./L), followed by OMBcAMP (0.64), DBcAMP (0.54), cGMP (0.47), and cAMP (0.41), whereas the hyperglycemic response was highest with NMBcAMP (146 mg/100 mL), followed by DBcAMP (93.6), OMBcAMP (77.1), and cAMP (56.0), and there was only a slight change with cGMP (28.4) compared with the control. The plasma level of cAMP was maximal with DBcAMP (1.92 nmol/mL), followed by NMBcAMP (1.28) and OMBcAMP (0.76), whereas the plasma levels of cGMP showed no evident change, except that caused by DBcAMP (0.27). Of the cyclic nucleotides tested, NMBcAMP was found to be most potent in causing both hyperkalemia and hyperglycemia. Based on these results, possible correlations between hyperkalemia, hyperglycemia, and plasma levels of cAMP and cGMP are discussed.     

Effects of radioprotectors on the cAMP and cGMP systems

Summary The sulphur-containing radioprotectors mercaptoethylamine (MEA), aminoethylisothiourea (AET), 2-aminothiazoline, 4-oxo-2-aminothiazoline, and S-S-3-oxapentane-1,5-diisothiourea, and the radioprotective biogenic amines serotonin, histamine, and dopamine, caused the elevation of cAMP content and intensified the rate of cAMP-dependent protein phosphorylation in tissues of animals following intraperitoneal injection at radioprotective doses. Biogenic amines stimulated the adenylate cyclase activity in membrane preparations from liver, spleen, and small-intestine mucosa; sulphur-containing radioprotectors caused no such effects. None of the radioprotectors affected cAMP and cGMP phosphodiesterases in vitro. AET and MEA inhibited guanylate cyclase in vitro, whereas serotonin and dopamine stimulated the enzyme. A biphasic change in the level of cGMP was observed in tissues after the administration of MEA and AET (more than 2-fold fall by 1–3 min after the administration of drug and 1.4-fold rise after 15–20 min); serotonin and dopamine caused a slow rise in the cGMP level; the cAMP/cGMP ratio in liver showed biphasic changes in level during the 20 min following injection of serotonin.The data obtained support the conclusion that the action of radioprotectors on cellular metabolism in animals may be mediated by the cAMP system. The reciprocal regulation of radioresistance by cAMP and cGMP is unlikely to exist.     

Cyclic nucleotides during chondrogenesis: concentration and distribution in vivo and in vitro

This study correlates endogenous levels of cAMP and cGMP with their immunohistochemical localization during chondrogenic differentiation of C57B1/6J mouse limb mesenchyme in vivo and in vitro. A transient decrease in cGMP but not cAMP was found from days 12 to 13 in vivo correlating with early stages of chondrogenesis in the developing limb. Intracellular levels of both cAMP and cGMP in high density limb mesenchyme cultures increased 25% after 24 hr in culture when aggregate and nodule formation was detectable. When cells were seeded at different initial plating densities to delay the onset of aggregate and nodule formation, increased levels of intracellular cAMP correlated temporally with the appearance of nodules. Both cyclic AMP and cGMP were immunohistochemically localized in perichondrial cells and chondrocytes in vivo and in vitro. Therefore, (1) cAMP levels correlated temporally with the appearance of chondrogenic cells and (2) cAMP and cGMP were immunohistochemically localized to chondrogenic cells. These data indicate that fluctuations of both cAMP and cGMP levels may be involved in limb cartilage differentiation. Although increases in both nucleotides were found to correlate with the onset of chondrogenesis in vitro, in vivo data suggest that the amount of cAMP relative to cGMP rather than the absolute amount of an individual cyclic nucleotide may be more significant in modulating differentiation.     

Cyclic GMP and cyclic AMP induced changes in control and hypertrophic cardiac myocyte function interact through cyclic GMP affected cyclic-AMP phosphodiesterases.

We tested the hypothesis that the negative functional effects of cyclic GMP (cGMP) would be greater after increasing cyclic AMP (cAMP), because of the action of cGMP-affected cAMP phosphodiesterases in cardiac myocytes and that this effect would be altered in left ventricular hypertrophy (LVH) produced by aortic valve plication. Myocyte shortening data were collected using a video edge detector, and O2 consumption was measured by O2 electrodes during stimulation (5 ms, 1 Hz, in 2 mM Ca2+) from control (n = 7) and LVH (n = 7) dog ventricular myocytes. cAMP and cGMP were determined by a competitive binding assay. cAMP was increased by forskolin and milrinone (10(-6) M). cGMP was increased with zaprinast and decreased by 1H-[1,2,4]oxadiazolo[4,3-a]quinoxilin-1-one (ODQ) both at 10(-6) and 10(-4) M, with and without forskolin or forskolin + milrinone. Zaprinast significantly decreased percent shortening in control (9 +/- 1 to 7 +/- 1%) and LVH (10 +/- 1 to 7 +/- 1%) myocytes. It increased cGMP in control (36 +/- 5 to 52 +/- 7 fmol/10(5) myocytes) and from the significantly higher baseline value in LVH (71 +/- 12 to 104 +/- 18 fmol/10(5) myocytes). ODQ increased myocyte function and decreased cGMP levels in control and LVH myocytes. Forskolin + milrinone increased cAMP levels in control (6 +/- 1 to 15 +/- 2 pmol/10(5) myocytes) and LVH (8 +/- 1 to 18 +/- 2 pmol/10(5) myocytes) myocytes, as did forskolin alone. They also significantly increased percent shortening. There were significant negative functional effects of zaprinast after forskolin + milrinone in control (15 +/- 2 to 9 +/- 1%), which were greater than zaprinast alone, and LVH (12 +/- 1 to 9 +/- 1%). This was associated with an increase in cGMP and a reduction in the increased cAMP induced by forskolin or milrinone. ODQ did not further increase function after forskolin or milrinone in control myocytes, despite lowering cGMP. However, it prevented the forskolin and milrinone induced increase in cAMP. In hypertrophy, ODQ lowered cGMP and increased function after forskolin. ODQ did not affect cAMP after forskolin and milrinone in LVH. Thus, the level of cGMP was inversely correlated with myocyte function. When cAMP levels were elevated, cGMP was still inversely correlated with myocyte function. This was, in part, related to alterations in cAMP. The interaction between cGMP and cAMP was altered in LVH myocytes.     

Cyclic nucleotide metabolism during lymphocyte transformation. I. Enzymatic mechanisms in changes in cAMP and cGMP concentration in Balb/c mice.

Balb/c mouse spleen lymphocytes incubated from 0 to 30 min with the mitogen, lipopolysaccharide (LPS), were examined for alterations in concentration of cGMP and cAMP using radioimmunoassay. An optimal concentration of LPS, 10 μg/10⁶ cells/ml, caused an increase in the cGMP concentration which reached a maximum of 53% above control values 10 min after the addition of LPS. cAMP concentration also increased, showing two peaks, the first after 5 min to 32% above control values and the second after 30 min to 52% above control values. Although these changes in cyclic nucleotide concentration are small in comparison with other studies, they demonstrate that consistent and statistically significant data are obtained following transformation by a mitogen at its optimal concentration rather than at a concentration that causes maximum cyclic nucleotide changes. Enzymatic mechanisms were also investigated in order to explain the changes in cyclic nucleotide concentration during Balb/c mouse splenocyte transformation that were reported earlier. In cells incubated with LPS, the specific activity of adenylate cyclase increased more than twofold within 10 min, while there was no change in guanylate cyclase activity. Furthermore, cyclic nucleotide phosphodiesterase activity for both cAMP and cGMP increased by more than 20% over control values. These results explain the observed increase in cAMP, but not cGMP. It was demonstrated that cAMP was capable of inhibiting cGMP degradation by cyclic nucleotide phosphodiesterase by as much as 70%. The same is true for the effect of cGMP on cAMP degradation. LPS tended to inhibit the latter with no effect on the former. The relative affect was shown to be dependent on the cGMP/cAMP ratio. Therefore, it is proposed that the elevation in cGMP concentration observed early in lymphocyte activation occurs as a consequence of the inhibition by each cyclic nucleotide on the hydrolysis of the other.     

The effect in vivo of alterations in gonadotropins and cyclic nucleotides on oocyte maturation in the hamster

The temporal relationship of changes in cAMP and cGMP to oocyte maturation was examined in proestrous hamsters (day 4). The first series of experiments showed, in normal cycling hamsters, an increase in cAMP and a decrease in cGMP at 1400 h shortly after the rise in LH with oocyte maturation beginning at 1800 h. When a second group of animals was injected with phenobarbital at 1200 h to block the LH surge, no significant change occurred in either cyclic nucleotide and oocyte maturation was prevented. In the second series of experiments single injections of either saline, hCG (30 IU), LH (10 micrograms) or FSH (10 micrograms) were given each to a group of animals at 0900 h on day 4. Animals were killed at five time intervals between 15 min and 3 h following the injection. LH and hCG stimulated a simultaneous increase in cAMP and decline in cGMP. The injection of FSH, however, did not cause an increase in cAMP but still produced a sharp decline in cGMP. Oocyte maturation occurred at 3 h in those animals injected with gonadotropins. Animals injected with saline showed neither cyclic nucleotide changes nor oocyte maturation. When cAMP and cGMP levels were expressed as a ratio (cAMP/cGMP) a significant increase occurred in the normal cycling animals and in those injected at 0900 h with gonadotropins. Phenobarbital and saline injected control animals showed no significant increase in the cAMP/cGMP ratio and no oocyte maturation. The results of these experiments and previous studies by this investigator indicate that cGMP may play an important role in oocyte maturation in the hamster prior to the LH surge. Since, in the presence of gonadotropins, the cAMP/cGMP ratio increases prior to oocyte maturation, it may be that the cyclic nucleotide ratio is also of importance in this process. Previous work by Hubbard and Terranova (1) has shown that guanosine 3':5' cyclic monophosphate (cGMP), can inhibit spontaneous maturation of hamster oocytes in vitro. This inhibitory action was dose dependent and overcome by LH. The cGMP-mediated inhibition occurred only in cumulus-enclosed oocytes, while adenosine 3':5' cyclic monophosphate (cAMP) inhibited spontaneous maturation in both cumulus-enclosed and denuded oocytes. The results of this study suggested that cGMP may play a role in inhibiting oocyte maturation prior to the LH surge. LH, the initiator of oocyte maturation, has also been shown in the intact proestrous rat and hamster to cause a decrease in cGMP at the same time that cAMP is rising (2,3).(ABSTRACT TRUNCATED AT 400 WORDS)     

A transient rise in cyclic AMP levels following chemotactic stimulation of neutrophil granulocytes.

A short transient rise of cyclic AMP is observed within 1 minute after primary stimulation of neutrophils with chemotactic serum peptides containing classical anaphylatoxin (CAT). A second administration of these peptides after two minutes failed to produce a second peak of cAMP. Human serum albumin (HSA) which has chemokinetic but no chemotactic activities did not change cAMP levels. There was no significant change in cGMP levels within 1 minute following stimulation of rabbit neutrophils with chemotactic peptides or HSA.     

Effects of cGMP and sodium nitroprusside on odor responses in turtle olfactory sensory neurons

The effects ofcGMP and sodium nitroprusside (SNP) on odor responses in isolatedturtle olfactory neurons were examined. The inward current induced bydialysis of a mixture of 1 mM cAMP and 1 mM cGMP was similar to thatinduced by dialysis of 1 mM cAMP or 1 mM cGMP alone. After the neuronswere desensitized by the application of 1 mM cGMP, 3 mM8-(4-chlorophenylthio)-cAMP, a membrane-permeable cAMP analog, did notelicit any current, indicating that both cAMP and cGMP activated thesame channel. Extracellular application of SNP, a nitric oxide (NO)donor, evoked inward currents in a dose-dependent manner. However,application of SNP did not induce any currents after desensitization ofthe cGMP-induced currents, suggesting that SNP-induced currents aremediated via the cGMP-dependent pathway. Application of thecAMP-producing odorants to the neurons induced a large inward currenteven after neurons were desensitized to a high concentration of cGMP orSNP. These results suggest that the transduction pathway independent ofcAMP, cGMP, and NO also contributes to the generation of odor responsesin addition to the cAMP-dependent pathway.

     

Levodopa-induced dyskinesias are associated with transient down-regulation of cAMP and cGMP in the caudate-putamen of hemiparkinsonian rats: Reduced synthesis or increased catabolism?

Second messenger cAMP and cGMP represent a key step in the action of dopamine that modulates directly or indirectly their synthesis. We aimed to verify whether levodopa-induced dyskinesias are associated with changes of the time course of levodopa/dopamine stimulated cAMP and cGMP levels, and/or with changes of their catabolism by phosphodiesterase activity in rats with experimental hemiparkinsonism. Microdialysis and tissue homogenates of the striatal tissues demonstrated that extracellular and intracellular cAMP/cGMP levels were lower in dyskinetic animals during the increasing phase of dyskinesias compared to eukinetic animals, but cAMP/cGMP levels increased in dyskinetic animals during the phase of decreasing and extinction of dyskinesias. Dyskinesias and the abnormal lowering of striatal cGMP and cAMP after levodopa were prevented by pretreatment with the multipotent drug amantadine, outlining the inverse relationship of cAMP/cGMP to dyskinesias. Moreover, dyskinetic animals showed higher striatal hydrolyzing cGMP-phosphodiesterase but not hydrolyzing cAMP-phosphodiesterase activity, suggesting that low cGMP but not cAMP levels could be due to increased catabolism. However, expressions of isozyme phosphodiesterase-1B and -10A highly and specifically located in the basal ganglia were not changed after levodopa in dyskinetic and eukinetic animals: accordingly, selective inhibitors of phosphodiesterase-1B and -10A were ineffective on levodopa dyskinesias. Therefore, the isozyme(s) expressing higher cGMP-phosphodiesterase activity in the striatum of dyskinetic animal should be determined. These observations suggest that dopamine-mediated processes of synthesis and/or degradation of cAMP/cGMP could be acutely impaired in levodopa dyskinesias, opening new ways to understanding physiopathology and treatment.     

Diurnal rhythms in cyclic nucleotide metabolism in Helix nervous system.

Concentrations of cAMP (cyclic adenosine 3',5'-monophosphate) and cGMP (cyclic guanosine 3',5'-monophosphate), in ganglia from the garden snail Helix pomatia, vary considerably over the course of the day. There is a maximum in the concentration of both cyclic nucleotides between 08:00 and 12:00 (lights on 06:00 to 18:00), with the cAMP maximum occurring slightly later than that in cGMP. In addition there can be several smaller maxima in cAMP and cGMP levels; the timing of these can be markedly different from experiment to experiment, with cAMP and cGMP sometimes in and sometimes out of phase with each other. This pattern is observed in Helix which had been activated from the dormant state 4-6 days earlier, but is not present in dormant or in long-active animals. The cyclic nucleotide rhythm can be seen in ganglia maintained in organ culture, and persists for at least 24 hours after removal of the tissue from the animal. There appears to be little change in the level of basal or NaF-stimulated adenylate cyclase activity in Helix ganglia over the course of the day. On the other hand, both cAMP and cGMP phosphodiesterase activities exhibit rhythms which are consistent with the rhythms in cAMP and cGMP concentrations.     

Cyclic nucleotides in goats' milk: changes with physiological state

Concentrations of cAMP and cGMP were measured in mammary secretions of goats. [cAMP] and [cGMP] increased during late pregnancy. At the onset of copious milk secretion, [cGMP] decreased while [cAMP] increased further. After the cessation of milking in late lactation, [cGMP] increased and [cAMP] tended to decrease. During withdrawal of food for 48 hr, the rate of milk secretion fell, [cGMP] increased and [cAMP] decreased; the changes were reversed on re-feeding. During temporary inhibition of milk secretion by intramammary treatment with colchicine, [cGMP] increased while [cAMP] decreased. It is concluded that cyclic nucleotide concentrations in milk change with physiological state.     

Anoxia-induced changes in reactive oxygen species and cyclic nucleotides in the painted turtle

The Western painted turtle survives months without oxygen. A key adaptation is a coordinated reduction of cellular ATP production and utilization that may be signaled by changes in the concentrations of reactive oxygen species (ROS) and cyclic nucleotides (cAMP and cGMP). Little is known about the involvement of cyclic nucleotides in the turtle’s metabolic arrest and ROS have not been previously measured in any facultative anaerobes. The present study was designed to measure changes in these second messengers in the anoxic turtle. ROS were measured in isolated turtle brain sheets during a 40-min normoxic to anoxic transition. Changes in cAMP and cGMP were determined in turtle brain, pectoralis muscle, heart and liver throughout 4 h of forced submergence at 20–22°C. Turtle brain ROS production decreased 25% within 10 min of cyanide or N₂-induced anoxia and returned to control levels upon reoxygenation. Inhibition of electron transfer from ubiquinol to complex III caused a smaller decrease in [ROS]. Conversely, inhibition of complex I increased [ROS] 15% above controls. In brain [cAMP] decreased 63%. In liver [cAMP] doubled after 2 h of anoxia before returning to control levels with prolonged anoxia. Conversely, skeletal muscle and heart [cAMP] remained unchanged; however, skeletal muscle [cGMP] became elevated sixfold after 4 h of submergence. In liver and heart [cGMP] rose 41 and 127%, respectively, after 2 h of anoxia. Brain [cGMP] did not change significantly during 4 h of submergence. We conclude that turtle brain ROS production occurs primarily between mitochondrial complexes I and III and decreases during anoxia. Also, cyclic nucleotide concentrations change in a manner suggestive of a role in metabolic suppression in the brain and a role in increasing liver glycogenolysis.     

Diurnal rhythms in cyclic nucleotide metabolism in Helix nervous system

Concentrations of cAMP (cyclic adenosine 3′,5′-monophosphate) and cGMP (cyclic guanosine 3′,5′-monophosphate), in ganglia from the garden snail Helix pomatia, vary considerably over the course of the day. There is a maximum in the concentration of both cyclic nucleotides between 08:00 and 12:00 (lights on 06:00 to 18:00), with the cAMP maximum occurring slightly later than that in cGMP. In addition there can be several smaller maxima in cAMP and cGMP levels; the timing of these can be markedly different from experiment to experiment, with cAMP and cGMP sometimes in and sometimes out of phase with each other. This pattern is observed in Helix which had been activated from the dormant state 4–6 days earlier, but is not present in dormant or in long-active animals. The cyclic nucleotide rhythm can be seen in ganglia maintained in organ culture, and persists for at least 24 hours after removal of the tissue from the animal. There appears to be little change in the level of basal or Na Fstimulated adenylate cyclase activity in Helix ganglia over the course of the day. On the other hand, both cAMP and cGMP phosphodiesterase activities exhibit rhythms which are consistent with the rhythms in cAMP and cGMP concentrations.     

Elevated cyclic GMP concentrations during estrogen induced differentiation of the chick oviduct.

The levels of cGMP and cAMP in the chick oviduct were evaluated during estrogen-induced differentiation and growth at two different stages of development. In the differentiating oviduct cGMP levels were found to change markedly. Tissue concentrations were elevated 35-fold by 2 hr after primary stimulation and about 3-fold at later time intervals. In contrast, constant levels of cGMP were observed during growth of the differentiated oviduct after secondary stimulation. cAMP concentrations were not or very little changed during differentiations and secondary stimulation of the oviduct. Our data suggest that elevated cGMP levels represent an active signal for the differentiative response of the chick oviduct to estrogens.     

Role of cyclic nucleotides in modulating ovarian hCG action.

The role of cyclic nucleotides in mediating hormonally responsive adenylate cyclase and cAMP-dependent protein kinase was examined in vivo and in vitro when pseudopregnant rats were injected with hCG. Intracellular ovarian levels of cAMP increased, as expected, but no change in cGMP concentrations was observed. However, both cGMP and cAMP activated ovarian CDPK holoenzyme in vitro but cGMP had a lower affinity. The subunits of hCG were without effect. Even though cGMP and cAMP dissociate partially purified ovarian CDPK holoenzyme in vitro, the receptor sites of the regulatory subunit of CDPK would appear to be relatively specific for cAMP. Moreover, cGMP probably does not mediate hCG action in vivo.     

Effect of agents for the chemical prevention of radiation sickness on the cyclic nucleotide content in the bone marrow of mice

The effect of different chemical compounds on the cAMP/cGMP ratio in the bone marrow of mice and radioresistance of animals has been studied. It has been shown that all compounds possessing radioprotective properties give rise to the cAMP/cGMP ratio in the bone marrow of mice. No changes in cAMP and cGMP level were noted after the administration of nonradioprotective substances. The maximal radioprotective effect coincide in time with the largest increase of the cAMP/cGMP ratio. The injection of radioprotectors at different doses demonstrate clearly that only at radioprotective doses the increase in the cAMP/cGMP ratio takes place. The administration of some substances 2, 15 and 60 min after the irradiation of mice shows that the radioprotective effect, though modest, was evident only in one case of elevated cAMP/cGMP ratio (the injection of 2-Mercaptoethylamine 2 min after the irradiation). Evident radioprotective effect occurs at the cAMP/cGMP ratio of about 170-200%; the ratio of about 130-140% corresponds to small radioprotection.