PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
10956052-0	2000	Cholesterol efflux to high-density lipoproteins and apolipoprotein A-I phosphatidylcholine complexes is inhibited by ethanol: role of apolipoprotein structure and cooperative interaction of phosphatidylcholine and cholesterol.	Ethanol	117-124	apolipoprotein A1	Homo sapiens	52-70	
10956052-5	2000	In this paper, we show that ethanol significantly inhibited cholesterol efflux from fibroblasts to HDL and to apolipoprotein A-I (apoA-I) complexed with phosphatidylcholine (PC).	Ethanol	28-35	apolipoprotein A1	Homo sapiens	110-128	
10956052-5	2000	In this paper, we show that ethanol significantly inhibited cholesterol efflux from fibroblasts to HDL and to apolipoprotein A-I (apoA-I) complexed with phosphatidylcholine (PC).	Ethanol	28-35	apolipoprotein A1	Homo sapiens	130-136	
10956052-6	2000	Ethanol significantly inhibited binding of PC to apoA-I, inhibited incorporation of cholesterol only when apoA-I contained PC, and did not alter incorporation of cholesterol into HDL.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	49-55	
10956052-6	2000	Ethanol significantly inhibited binding of PC to apoA-I, inhibited incorporation of cholesterol only when apoA-I contained PC, and did not alter incorporation of cholesterol into HDL.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	106-112	
10956052-7	2000	ApoA-I structure was altered by ethanol as monitored by steady-state fluorescence polarization of tryptophan residues.	Ethanol	32-39	apolipoprotein A1	Homo sapiens	0-6	
10956052-9	2000	In addition, effects of ethanol on apoA-I suggest that pre-beta-HDL or lipid-free apoA-I may be more perturbed by ethanol than mature HDL, and such effects may be pathophysiological with respect to the process of reverse cholesterol transport in heavy drinkers and alcoholics.	Ethanol	24-31	apolipoprotein A1	Homo sapiens	35-41	
10956052-9	2000	In addition, effects of ethanol on apoA-I suggest that pre-beta-HDL or lipid-free apoA-I may be more perturbed by ethanol than mature HDL, and such effects may be pathophysiological with respect to the process of reverse cholesterol transport in heavy drinkers and alcoholics.	Ethanol	114-121	apolipoprotein A1	Homo sapiens	35-41	
10956052-9	2000	In addition, effects of ethanol on apoA-I suggest that pre-beta-HDL or lipid-free apoA-I may be more perturbed by ethanol than mature HDL, and such effects may be pathophysiological with respect to the process of reverse cholesterol transport in heavy drinkers and alcoholics.	Ethanol	114-121	apolipoprotein A1	Homo sapiens	82-88	
10591709-8	1999	An experimental dose of 30 g of ethanol a day increased concentrations of high density lipoprotein cholesterol by 3.99 mg/dl (95% confidence interval 3.25 to 4.73), apolipoprotein A I by 8.82 mg/dl (7.79 to 9.86), and triglyceride by 5.69 mg/dl (2.49 to 8.89).	Ethanol	32-39	apolipoprotein A1	Homo sapiens	165-183	
1335218-6	1992	Exposure of HepG2 and Hep3B cells to ethanol resulted in an increase of accumulation of apoA-I (15%-45% over control) in a dose-dependent manner (from 5 to 50 mM) of ethanol over a 24-hr period.	Ethanol	37-44	apolipoprotein A1	Homo sapiens	88-94	
8732781-0	1996	Effect of ethanol on the synthesis and secretion of apoA-I- and apoB-containing lipoproteins in HepG2 cells.	Ethanol	10-17	apolipoprotein A1	Homo sapiens	52-58	
8732781-11	1996	In contrast to the short-term effect of ethanol, long-term incubation with ethanol resulted in a dose-dependent increase in the secretion of newly synthesized apoA-I without significantly affecting that of apoB-100.	Ethanol	75-82	apolipoprotein A1	Homo sapiens	159-165	
8732781-12	1996	The increase in apoA-I secretion was evident at 0.05% ethanol and reached a maximum of 77% at 0.5% ethanol.	Ethanol	54-61	apolipoprotein A1	Homo sapiens	16-22	
8732781-12	1996	The increase in apoA-I secretion was evident at 0.05% ethanol and reached a maximum of 77% at 0.5% ethanol.	Ethanol	99-106	apolipoprotein A1	Homo sapiens	16-22	
8732781-13	1996	These observations indicate that in HepG2 cells the effect of ethanol on the production of apoA-I- and apoB- containing lipoproteins is both time- and dose-dependent and is different in these two apolipoproteins.	Ethanol	62-69	apolipoprotein A1	Homo sapiens	91-97	
8912458-2	1996	Apolipoprotein A-I (apoA-I was isolated from precipitates obtained by cold ethanol fractionation of human plasma.	Ethanol	75-82	apolipoprotein A1	Homo sapiens	0-18	
8912458-2	1996	Apolipoprotein A-I (apoA-I was isolated from precipitates obtained by cold ethanol fractionation of human plasma.	Ethanol	75-82	apolipoprotein A1	Homo sapiens	20-26	
8332287-0	1993	Ethanol stimulates apo A-1 secretion in human hepatocytes: a possible mechanism underlying the cardioprotective effect of ethanol.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	19-26	
8332287-0	1993	Ethanol stimulates apo A-1 secretion in human hepatocytes: a possible mechanism underlying the cardioprotective effect of ethanol.	Ethanol	122-129	apolipoprotein A1	Homo sapiens	19-26	
8332287-1	1993	Ethanol stimulates synthesis of the high-density lipoprotein (HDL) protein apo A-1 in cultured human hepatocytes.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	75-82	
8332287-3	1993	Enhanced activity of a reverse cholesterol transport pathway mediated by increased hepatic apo A-1 synthesis may explain why epidemiological studies show a relationship between ethanol consumption and lower incidence of coronary heart disease.	Ethanol	177-184	apolipoprotein A1	Homo sapiens	91-98	
1335218-6	1992	Exposure of HepG2 and Hep3B cells to ethanol resulted in an increase of accumulation of apoA-I (15%-45% over control) in a dose-dependent manner (from 5 to 50 mM) of ethanol over a 24-hr period.	Ethanol	166-173	apolipoprotein A1	Homo sapiens	88-94	
1834916-7	1991	Ethanol intake caused an increase in the serum levels of both Lp A-I and Lp A-I:A-II, the former explaining one third of the total increase of apo A-I.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	143-150	
1640859-0	1992	Ethanol stimulates apolipoprotein A-I secretion by human hepatocytes: implications for a mechanism for atherosclerosis protection.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	19-37	
1640859-4	1992	Using highly specific antibodies, we have found that ethanol increases apo A-I secretion and the incorporation of radiolabeled leucine into apo A-I by human hepatocytes (Hep-G2 cells).	Ethanol	53-60	apolipoprotein A1	Homo sapiens	71-76	
1640859-4	1992	Using highly specific antibodies, we have found that ethanol increases apo A-I secretion and the incorporation of radiolabeled leucine into apo A-I by human hepatocytes (Hep-G2 cells).	Ethanol	53-60	apolipoprotein A1	Homo sapiens	140-145	
1640859-5	1992	In addition, we have found that apo A-I molecules induced by ethanol have the ability to efflux cholesterol from human fibroblasts in vitro, and that apo A-I mass directly correlates with cholesterol efflux levels.	Ethanol	61-68	apolipoprotein A1	Homo sapiens	32-37	
1640859-5	1992	In addition, we have found that apo A-I molecules induced by ethanol have the ability to efflux cholesterol from human fibroblasts in vitro, and that apo A-I mass directly correlates with cholesterol efflux levels.	Ethanol	61-68	apolipoprotein A1	Homo sapiens	32-39	
1640859-6	1992	At 10, 20, and 100 mmol/L, ethanol stimulated apo A-I secretion by 130%, 136%, and 162% of control, respectively (control, 3.71 micrograms apo A-I/micrograms DNA), also stimulating the incorporation of 3H-leucine into newly synthesized apo A-I by 115%, 131%, and 159% of control (control, 111 cpm/micrograms DNA/h).	Ethanol	27-34	apolipoprotein A1	Homo sapiens	46-51	
1640859-6	1992	At 10, 20, and 100 mmol/L, ethanol stimulated apo A-I secretion by 130%, 136%, and 162% of control, respectively (control, 3.71 micrograms apo A-I/micrograms DNA), also stimulating the incorporation of 3H-leucine into newly synthesized apo A-I by 115%, 131%, and 159% of control (control, 111 cpm/micrograms DNA/h).	Ethanol	27-34	apolipoprotein A1	Homo sapiens	139-144	
1640859-6	1992	At 10, 20, and 100 mmol/L, ethanol stimulated apo A-I secretion by 130%, 136%, and 162% of control, respectively (control, 3.71 micrograms apo A-I/micrograms DNA), also stimulating the incorporation of 3H-leucine into newly synthesized apo A-I by 115%, 131%, and 159% of control (control, 111 cpm/micrograms DNA/h).	Ethanol	27-34	apolipoprotein A1	Homo sapiens	139-144	
1640859-7	1992	The ethanol-induced apo A-I from Hep-G2 cells (incubated with 0, 10, 20, and 100 mmol/L ethanol) effluxed 2%, 14%, 16%, and 32% label (per h/mL incubation medium), respectively.	Ethanol	4-11	apolipoprotein A1	Homo sapiens	20-25	
1640859-7	1992	The ethanol-induced apo A-I from Hep-G2 cells (incubated with 0, 10, 20, and 100 mmol/L ethanol) effluxed 2%, 14%, 16%, and 32% label (per h/mL incubation medium), respectively.	Ethanol	88-95	apolipoprotein A1	Homo sapiens	20-25	
1640859-9	1992	This data indicates that the cardioprotective role of moderate ethanol intake in humans is mediated by its stimulatory action on hepatic apo A-I secretion, thus defining the physiological basis for increased plasma apo A-I levels in vivo.	Ethanol	63-70	apolipoprotein A1	Homo sapiens	137-142	
1640859-9	1992	This data indicates that the cardioprotective role of moderate ethanol intake in humans is mediated by its stimulatory action on hepatic apo A-I secretion, thus defining the physiological basis for increased plasma apo A-I levels in vivo.	Ethanol	63-70	apolipoprotein A1	Homo sapiens	215-220	
2502043-3	1989	Through the use of urea, chloroform, and ethanol in appropriate concentrations, apolipoproteins A-I and A-II were isolated by a simple extraction technique avoiding time-consuming ultracentrifugation.	Ethanol	41-48	apolipoprotein A1	Homo sapiens	80-108	
2502043-1	1989	Apolipoproteins A-I and A-II were isolated from precipitates obtained by cold ethanol fractionation of human plasma.	Ethanol	78-85	apolipoprotein A1	Homo sapiens	0-28	
2502043-6	1989	Apolipoprotein A-I obtained by the cold ethanol method activated lecithin-cholesterol acyltransferase to the same extent as apolipoprotein A-I prepared by the classical flotation method.	Ethanol	40-47	apolipoprotein A1	Homo sapiens	0-18	
2650924-4	1989	Hep G2 cells when grown in ethanol-containing medium for 14-28 days manifested increased HDL-binding capacity; apolipoprotein-A1 secretion was increased by ethanol but apolipoprotein B secretion was not affected.	Ethanol	27-34	apolipoprotein A1	Homo sapiens	111-128	
2650924-4	1989	Hep G2 cells when grown in ethanol-containing medium for 14-28 days manifested increased HDL-binding capacity; apolipoprotein-A1 secretion was increased by ethanol but apolipoprotein B secretion was not affected.	Ethanol	156-163	apolipoprotein A1	Homo sapiens	111-128	
6810694-7	1982	Apo A-I level was unrelated to age, but increased with ethanol consumption and decreased with adiposity.	Ethanol	55-62	apolipoprotein A1	Homo sapiens	0-7	
3365983-4	1988	At baseline, ethanol consumption was found to be positively associated with triglycerides, HDL-C, and Apo-A1 and negatively associated with LDL-C/LDL-B.	Ethanol	13-20	apolipoprotein A1	Homo sapiens	102-108	
3933859-3	1985	Mean synthesis of Apo A-I and B were increased, respectively, from 12.6 and 13.7 mg/kg per day in the absence of ethanol to 18.8 and 17.1 mg/kg/day after 2 wk of ethanol intake.	Ethanol	113-120	apolipoprotein A1	Homo sapiens	18-31	
3933859-3	1985	Mean synthesis of Apo A-I and B were increased, respectively, from 12.6 and 13.7 mg/kg per day in the absence of ethanol to 18.8 and 17.1 mg/kg/day after 2 wk of ethanol intake.	Ethanol	162-169	apolipoprotein A1	Homo sapiens	18-31	
3933859-4	1985	Fractional catabolic rates for Apo A-I and B increased respectively from 0.204 and 0.340 in the period without ethanol to 0.266 and 0.372 after ethanol.	Ethanol	111-118	apolipoprotein A1	Homo sapiens	31-44	
3933859-4	1985	Fractional catabolic rates for Apo A-I and B increased respectively from 0.204 and 0.340 in the period without ethanol to 0.266 and 0.372 after ethanol.	Ethanol	144-151	apolipoprotein A1	Homo sapiens	31-44	
6782187-4	1980	Delipidation with ether/ethanol produced a decrease of apolipoprotein A-I values in both methods as compared to treatment with tetramethyl urea.	Ethanol	24-31	apolipoprotein A1	Homo sapiens	55-73	
32563265-0	2020	Ethanol-mediated upregulation of APOA1 gene expression in HepG2 cells is independent of de novo lipid biosynthesis.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	33-38	
32563265-6	2020	RESULTS: Ethanol stimulated ApoA1 protein (both cytoplasmic and secreted) and APOA1 RNA levels in HepG2 cells in a dose sensitive way, with ~ 50% upregulation at 100 mM ethanol in the medium.	Ethanol	9-16	apolipoprotein A1	Homo sapiens	28-33	
32563265-6	2020	RESULTS: Ethanol stimulated ApoA1 protein (both cytoplasmic and secreted) and APOA1 RNA levels in HepG2 cells in a dose sensitive way, with ~ 50% upregulation at 100 mM ethanol in the medium.	Ethanol	9-16	apolipoprotein A1	Homo sapiens	78-83	
32563265-6	2020	RESULTS: Ethanol stimulated ApoA1 protein (both cytoplasmic and secreted) and APOA1 RNA levels in HepG2 cells in a dose sensitive way, with ~ 50% upregulation at 100 mM ethanol in the medium.	Ethanol	169-176	apolipoprotein A1	Homo sapiens	28-33	
32563265-14	2020	CONCLUSION: This study has verified the previously reported upregulation of APOA1 by exposure of HepG2, but not Caco-2 cells, to ethanol in the culture medium.	Ethanol	129-136	apolipoprotein A1	Homo sapiens	76-81	
32563265-17	2020	The results reported here suggest that the proximal signaling molecule leading to increased APOA1 gene expression in response to ethanol exposure may be free acetate or acetyl-CoA.	Ethanol	129-136	apolipoprotein A1	Homo sapiens	92-97	
32563265-18	2020	TAKE HOME: Upregulation of ApoA1 gene expression in hepatoma cells in culture, upon exposure to moderate ethanol concentrations in the medium, occurs at the level of RNA and is not dependent on new cholesterol or fatty acid synthesis.	Ethanol	105-112	apolipoprotein A1	Homo sapiens	27-32	
24912423-11	2014	As supplement in PLCs, nHDL3 or apoA-I from Fraction IV of plasma ethanol fractionation have the potential to improve PLC quality to prolong storage.	Ethanol	66-73	apolipoprotein A1	Homo sapiens	32-38	
32223124-3	2020	Here, we show that a dHDL-relevant complex can also be prepared by gently mixing 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) and apoA-I or its mutants in ethanol/H2O solutions containing urea in the order of a few molar, and then incubating the mixture at the gel-liquid crystalline phase transition temperature in test tubes.	Ethanol	161-168	apolipoprotein A1	Homo sapiens	136-142	
15686978-14	2005	Ethanol extraction may also not be advisable in all other situations known to be associated with a rise in apolipoprotein A-1 turnover.	Ethanol	0-7	apolipoprotein A1	Homo sapiens	107-125