PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
2553385-4	1989	Stimulatory effects on erythropoietin response are observed with the addition of compounds affecting the cAMP level such as forskolin, phosphodiesterase inhibitor and cholera toxin only in the presence of erythropoietin.	Cyclic AMP	105-109	erythropoietin	Mus musculus	23-37	
2465166-6	1989	In initial experiments, cAMP levels in cells stimulated with either recombinant Epo or recombinant IL-3 were monitored.	Cyclic AMP	24-28	erythropoietin	Mus musculus	80-83	
2465166-10	1989	The regulatory effects of cAMP on Epo- and IL-3-stimulated cell growth were next examined.	Cyclic AMP	26-30	erythropoietin	Mus musculus	34-37	
2465166-11	1989	It was found that whereas Epo-stimulated growth was markedly inhibited by cAMP-enhancing agents, IL-3-stimulated growth was relatively resistant and inhibited only by high doses of these agents.	Cyclic AMP	74-78	erythropoietin	Mus musculus	26-29	
25500291-0	2015	Erythropoietin activates the phosporylated cAMP [adenosine 3"5" cyclic monophosphate] response element-binding protein pathway and attenuates delayed paraplegia after ischemia-reperfusion injury.	Cyclic AMP	43-47	erythropoietin	Mus musculus	0-14	
25500291-0	2015	Erythropoietin activates the phosporylated cAMP [adenosine 3"5" cyclic monophosphate] response element-binding protein pathway and attenuates delayed paraplegia after ischemia-reperfusion injury.	Cyclic AMP	49-84	erythropoietin	Mus musculus	0-14	
25500291-3	2015	We hypothesized that EPO induces the CREB (cAMP [adenosine 3"5" cyclic monophosphate] response element-binding protein) pathway and neurotrophin production in the murine spinal cord, attenuating functional and cellular injury.	Cyclic AMP	43-47	erythropoietin	Mus musculus	21-24	
25500291-3	2015	We hypothesized that EPO induces the CREB (cAMP [adenosine 3"5" cyclic monophosphate] response element-binding protein) pathway and neurotrophin production in the murine spinal cord, attenuating functional and cellular injury.	Cyclic AMP	49-84	erythropoietin	Mus musculus	21-24	
18621143-3	2008	The blood plasma erythropoietin level increased after the injection of N6-2-O-dibutyladenosine-3",5"-cyclic monophosphate into adenosine 3",5"-cyclic monophosphate (cAMP) at a dose of 500 mg/kg.	Cyclic AMP	127-163	erythropoietin	Mus musculus	17-31	
18621143-3	2008	The blood plasma erythropoietin level increased after the injection of N6-2-O-dibutyladenosine-3",5"-cyclic monophosphate into adenosine 3",5"-cyclic monophosphate (cAMP) at a dose of 500 mg/kg.	Cyclic AMP	165-169	erythropoietin	Mus musculus	17-31	
18621143-4	2008	A peak of erythropoietin induction was observed 3 h after the injection of cAMP.	Cyclic AMP	75-79	erythropoietin	Mus musculus	10-24	
9364843-0	1997	[Establishment and characterization of a renal carcinoma cell line producing erythropoietin (effects of cyclic AMP on erythropoietin production in vitro)].	Cyclic AMP	104-114	erythropoietin	Mus musculus	77-91	
9364843-0	1997	[Establishment and characterization of a renal carcinoma cell line producing erythropoietin (effects of cyclic AMP on erythropoietin production in vitro)].	Cyclic AMP	104-114	erythropoietin	Mus musculus	118-132	
2171931-3	1990	cAMP-elevating agents, such as forskolin and 3-isobutyl-1-methyl-xanthine, caused spontaneous erythroid differentiation, and these agents showed the stimulatory effects on erythropoietin- or Me2SO-induced differentiation.	Cyclic AMP	0-4	erythropoietin	Mus musculus	172-186	
2171931-5	1990	The intracellular cAMP level was rapidly increased by addition of erythropoietin but not by Me2SO.	Cyclic AMP	18-22	erythropoietin	Mus musculus	66-80	
2171931-6	1990	These observations suggest that erythroid differentiation induced by erythropoietin is mediated, at least in part, through the cAMP-dependent pathway.	Cyclic AMP	127-131	erythropoietin	Mus musculus	69-83	
2553385-4	1989	Stimulatory effects on erythropoietin response are observed with the addition of compounds affecting the cAMP level such as forskolin, phosphodiesterase inhibitor and cholera toxin only in the presence of erythropoietin.	Cyclic AMP	105-109	erythropoietin	Mus musculus	205-219	
2553385-5	1989	cAMP analogues themselves show no stimulatory effect on TSA8 cells, nor does erythropoietin increase cAMP level in the cells.	Cyclic AMP	101-105	erythropoietin	Mus musculus	77-91	
2553385-6	1989	Thus, it is suggested that cAMP does not act as a direct second messenger for signal transduction through erythropoietin receptors, but as a stimulator of the erythropoietin receptor pathway and/or as a second messenger in combination with the receptor pathway.	Cyclic AMP	27-31	erythropoietin	Mus musculus	106-120	
2553385-6	1989	Thus, it is suggested that cAMP does not act as a direct second messenger for signal transduction through erythropoietin receptors, but as a stimulator of the erythropoietin receptor pathway and/or as a second messenger in combination with the receptor pathway.	Cyclic AMP	27-31	erythropoietin	Mus musculus	159-173	
163577-0	1975	The role of renal adenosine 3",5"-monophosphate in the control of erythropoietin production.	Cyclic AMP	18-47	erythropoietin	Mus musculus	66-80	
163577-2	1975	Studies in rates reveal a temporal relationship between renal cyclic AMP levels and plasma titers of erythropoietin.	Cyclic AMP	62-72	erythropoietin	Mus musculus	101-115	
163577-3	1975	In addition, cobalt increases the activity of an erythropoietin-generating enzyme (renal erythropoietic factor) with maximal enzyme activity occurring after the rise in cyclic AMP levels but before the increase in erythropoietin titers.	Cyclic AMP	169-179	erythropoietin	Mus musculus	49-63	
163577-9	1975	These results suggest that cyclic AMP plays a significant role in the renal production of erythropoietin following cobalt administration.	Cyclic AMP	27-37	erythropoietin	Mus musculus	90-104	
163577-11	1975	Cyclic AMP then activates a protein kinase which subsequently stimulates renal erythropoietic factor to generate erythropoietin.	Cyclic AMP	0-10	erythropoietin	Mus musculus	113-127	
164670-3	1975	These studies confirm earlier reports of the effects of cyclic AMP in increasing radioactive iron incorporation into red cells and further indicate that this change is associated with an absolute increase renal cyclic AMP concentrations probably stimulate erythropoiesis as a consequence of increased kidney production of erythropoietin.	Cyclic AMP	211-221	erythropoietin	Mus musculus	322-336