Ethanol activates immune response in lymphoblastoid cells.

paper Primary Public

Authors: McClintick, Jeanette N; Tischfield, Jay A; Deng, Li; Kapoor, Manav; Xuei, Xiaoling; Edenberg, Howard J
Year: 2019
Journal: Alcohol (Fayetteville, N.Y.)
PMID: 30639126
DOI: 10.1016/j.alcohol.2019.01.001
PMCID: PMC6616005

The short-term effects of alcohol on gene expression in brain tissue cannot directly be studied in humans. Because neuroimmune signaling is altered by alcohol, immune cells are a logical, accessible choice to study and may provide biomarkers. RNAseq was used to study the effects of 48-h exposure to ethanol on lymphoblastoid cell lines (LCLs) from 20 alcoholic subjects and 20 control subjects. Ethanol exposure resulted in differential expression of 4456 of the 12,503 genes detectably expressed in the LCLs (FDR [false discovery rate] ≤ 0.05); 52% of these showed increased expression. Cells from alcoholic subjects and control subjects responded similarly. The genes whose expression changed fell into many pathways: NFκB, neuroinflammation, IL6, IL2, IL8, and dendritic cell maturation pathways were activated, consistent with increased signaling by NFκB, TNF, IL1, IL4, IL18, TLR4, and LPS. Signaling by Interferons A and B decreased, as did EIF2 signaling, phospholipase C signaling, and glycolysis. Baseline gene expression patterns were similar in LCLs from alcoholic subjects and control subjects. At relaxed stringency (p < 0.05), 465 genes differed, 230 of which were also affected by ethanol. There was a suggestion of compensation because baseline differences (no ethanol) were in the opposite direction of differences due to ethanol exposure in 78% of these genes. Pathways with IL8, phospholipase C, and α-adrenergic signaling were significant. The pattern of expression was consistent with increased signaling by several cytokines, including interferons, TLR2, and TLR3 in alcoholics. Expression of genes in the cholesterol biosynthesis pathway, including the rate-limiting enzyme HMGCR, was lower in alcoholic subjects. LCLs show many effects of ethanol exposure, some of which might provide biomarkers for alcohol use disorders. Identifying genes and pathways altered by ethanol can aid in interpreting which genes within loci identified by GWAS might play functional roles.

#	Section	Preview
20	Results and Discussion — Effects of ethanol treatment	(LPS) was also listed as a putative regulator, although the LCLs were not exposed to LPS, indicating…
21	Results and Discussion — Effects of ethanol treatment	Among genes affected by ethanol treatment, STXBP1 (syntaxin binding protein 1), PEA15…
22	Results and Discussion — Effects of ethanol treatment	We examined other datasets to look for converging evidence supporting a potential role for the genes…
23	Results and Discussion — Effects of ethanol treatment	the LCLs (Supplemental Table S1). Some genes show evidence from several of these analyses. For…
24	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	Baseline expression differences between LCLs derived from AD subjects vs. controls could result…
25	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	Among the genes that differed at baseline, 230 were affected by ethanol, 180 of which differed in…
26	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	Some genes that differ between AD and controls have prominent roles in brain function and were…
27	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	in the COGA sample (Wetherill et al., 2015). FYB, FYN binding protein, is associated with the innate…
28	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	Two genes with large differences between untreated cells from AD vs. control subjects are involved…
29	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	The 465 nominally significant genes mapped to sixty-seven pathways (Supplemental Table S5).…
30	Results and Discussion — Baseline differences between LCLs from alcohol-dependent and control subjects	Among the 465 genes, expression differences between alcohol-naïve rats from 5 selectively bred…
31	Conclusions	The results of this study provide additional data on genes potentially linked either to the…
32	Conclusions	This study shows that ethanol exposure induces many changes in LCLs, including a robust immune…

Name	Type
AA	cohort
ADH1B	gene
AD subjects	cohort
Affymetrix HGU133plus2 GeneChip™ local	drug
African American	cohort
alcohol	phenotype
alcohol and nicotine codependence local	phenotype
alcohol dependence	phenotype
alcoholism	phenotype
alcohol-naïve animals local	cohort
alcohol-treated cells local	cohort
Alcohol Use	phenotype
Alcohol Use Disorder	phenotype
alcohol use disorders	phenotype
ALDH2	gene
Alzheimer's disease	phenotype
amygdala	anatomy
ANA local	cohort
animals	cohort
apoptosis	phenotype
Array local	cohort
ASB2 local	gene
Asian	cohort
AUD	phenotype
AUDIT	phenotype
AUTS2	gene
bipolar disorder	phenotype
brain	anatomy
cannabis use	phenotype
CASZ1	gene
CBLN3 local	gene
central core of the amygdala local	anatomy
chemokine local	drug
CHL1 local	gene
cholesterol biosynthesis	phenotype
CHRNA5	gene
Chrnb1	gene
CLIC2 local	gene
cocaine	phenotype
COGA sample	cohort
Collaborative Study on the Genetics of Alcoholism (COGA)	cohort
control	cohort
control individuals	cohort
controls	cohort
control subjects	cohort
CYP51A1 local	gene
dorsal raphe nucleus	anatomy
Dynabeads mRNA DIRECT Micro Kit local	drug
EBV-transformed-lymphocytes (LCLs) local	cohort
EIF1AY local	gene
ethanol consumption	phenotype
European ancestry	cohort
Excessive alcohol local	phenotype
fetal bovine serum	drug
forebrain	anatomy
FOXA3 local	gene
frontal cortex	anatomy
FYB local	gene
genes	gene
glutamine	drug
GRM8	gene
GSE52553 local	cohort
GTEx	cohort
GTEx v7	cohort
Had1 local	cohort
Had2 local	cohort
high drinking lines local	cohort
high-drinking rats local	phenotype
hippocampus	anatomy
HMGCR	gene
human brain	anatomy
humans	cohort
IDI1 local	gene
IGF1	gene
IL10	gene
IL1B	gene
IL6	gene
immune stimulation local	phenotype
Interferons local	gene
interferon signaling local	phenotype
interleukin local	drug
Interleukins local	gene
JAK local	gene
Kcna1	gene
Lad1 local	cohort
Lad2 local	cohort
LCLs	cohort
Life Technologies	drug
lipopolysaccharide	drug
lithium	drug
low-drinking rats local	phenotype
LPS	drug
lymphoblastoid cell lines	cohort
medial pre-frontal cortex local	anatomy
MREG	gene
MUC13 local	gene
myelin	phenotype
NFκB	gene
NHGRI-EBI GWAS catalog	cohort
nicotine	drug
NPDC1 local	gene
NPNT	gene
NP rats	cohort
NRXN3	gene
nucleus accumbens	anatomy
nucleus accumbens shell	anatomy
opioid	drug
PEA15 local	gene
periaqueductal grey local	anatomy
phospholipase C	drug
post-mortem brain tissue from alcoholics local	cohort
postmortem human brain tissue local	anatomy
P rats	cohort
response to trauma local	phenotype
RNAseq local	cohort
RPMI 1640 medium local	drug
rs113497429 local	variant
rs17514104 local	variant
rs73222599 local	variant
rs73222600 local	variant
SASH1	gene
seizure-induced neuronal injury local	phenotype
sex	phenotype
SIX3	gene
SLC35F3 local	gene
SNP	cohort
SOLiD 5500xl DNA sequencer local	drug
SOLiD™ EZBead™ System local	drug
SOLiD™ Total RNAseq kit local	drug
sP local	cohort
SSTR2 local	gene
SSTR3 local	gene
ST3GAL1 local	gene
STAT3	gene
striatum	anatomy
STXBP1 local	gene
synaptophilin local	gene
SYNGR1	gene
Synpo	gene
SYT11 local	gene
TANC1 local	gene
TIE1 local	gene
TLR	gene
Tlr4	gene
TLRs local	gene
TMOD2 local	gene
TNF	gene
TNFRSF10A local	gene
TNFα	drug
TP53	gene
Trail	drug
TSPAN5	gene
unipolar depression	phenotype
ventral hippocampus	anatomy
ventral tegmental area	anatomy
voluntary ethanol consumption	phenotype
WFDC2 local	gene
white matter	anatomy

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In this knowledge base

Title	Year	PMID
Integrated single-cell multiomic profiling of caudate nucleus suggests key mechanisms in alcohol use disorder.	2025	41083468
RNA alternative splicing impacts the risk for alcohol use disorder.	2023	37217680
Multi-omics signatures of alcohol use disorder in the dorsal and ventral striatum.	2022	35523767

External

Title	Authors	Journal	Year	Link
Integrated single-cell multiomic profiling of caudate nucleus suggests key mechanisms in alcohol use disorder.	Green NC et al.	—	2025	→
Next-generation biomarkers for alcohol consumption and alcohol use disorder diagnosis, prognosis, and treatment: A critical review.	Clark SL et al.	—	2025	→
DNA-PK and ATM drive phosphorylation signatures that antagonistically regulate cytokine responses to herpesvirus infection or DNA damage.	Justice JL et al.	—	2024	→
5. Collaborative Study on the Genetics of Alcoholism: Functional genomics.	Gameiro-Ros I et al.	—	2023	→
Immunomodulatory effects of Isochrysis galbana incorporated diet on Oreochromis sp. (red hybrid tilapia) via Sera-<sup>1</sup>H NMR metabolomics study.	Ahamad Bustamam MS et al.	—	2023	→
RNA alternative splicing impacts the risk for alcohol use disorder	Liu Y et al.	—	2023	—
RNA alternative splicing impacts the risk for alcohol use disorder.	Li R et al.	—	2023	→
Transcriptome-wide gene-gene interaction associations elucidate pathways and functional enrichment of complex traits.	Evans LM et al.	—	2023	→
Multi-omics signatures of alcohol use disorder in the dorsal and ventral striatum.	Zillich L et al.	—	2022	→
RNA biomarkers for alcohol use disorder.	Ferguson LB et al.	—	2022	→
A pan-cancer analysis revealed the role of the SLC16 family in cancer.	Li J et al.	—	2021	→
Acute alcohol withdrawal and recovery in men lead to profound changes in DNA methylation profiles: a longitudinal clinical study.	Witt SH et al.	—	2020	→
Effects of chronic intermittent ethanol exposure and withdrawal on neuroblastoma cell transcriptome.	McClintick JN et al.	—	2020	→
Monocarboxylate Transporters (SLC16): Function, Regulation, and Role in Health and Disease.	Felmlee MA et al.	—	2020	→
Ethanol and its metabolites: update on toxicity, benefits, and focus on immunomodulatory effects.	Le Daré B et al.	—	2019	→