PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
26522131-0	2016	Exercise-induced lactate accumulation regulates intramuscular triglyceride metabolism via transforming growth factor-beta1 mediated pathways.	Lactic Acid	17-24	transforming growth factor, beta 1	Rattus norvegicus	90-122	
22790566-0	2012	Blood lactate functions as a signal for enhancing fatty acid metabolism during exercise via TGF-beta in the brain.	Lactic Acid	6-13	transforming growth factor, beta 1	Rattus norvegicus	92-100	
22790566-4	2012	administration of lactate to anesthetized rats caused an increase in blood lactate similar to that observed after a 21 m/min running exercise and increased the level of active TGF-beta in CSF.	Lactic Acid	18-25	transforming growth factor, beta 1	Rattus norvegicus	176-184	
22790566-7	2012	lactate administration in this study were mediated, at least in part, by TGF-beta in the brain.	Lactic Acid	0-7	transforming growth factor, beta 1	Rattus norvegicus	73-81	
7795846-12	1995	Despite TGF-beta 1 stimulating a fourfold increase in lactic acid, the consequent increase in culture medium acidity did not account for the inhibitory effects of TGF-beta 1 on mineralization.	Lactic Acid	54-65	transforming growth factor, beta 1	Rattus norvegicus	8-18	
26522131-5	2016	Intramuscular acute injection of lactate increased TGF-beta1 and ATGL abundance in the gastrocnemius muscle and there were a significant increase in Muscle TGF-beta1 and ATGL abundance after 5 weeks of HIIT/lactate treatment.	Lactic Acid	33-40	transforming growth factor, beta 1	Rattus norvegicus	51-60	
26522131-6	2016	These results indicate that exercise-induced lactate accumulation regulates intramuscular triglyceride metabolism via transforming growth factor-beta1 mediated pathways during post-exercise recovery from strenuous exercise.	Lactic Acid	45-52	transforming growth factor, beta 1	Rattus norvegicus	118-150