Invest Clin 62(4): 316 - 324, 2021 https://doi.org/10.22209/IC.v62n4a03
Corresponding author: Farnoosh Ebrahimzadeh. Department of Internal Medicine, Faculty of Medicine, Mashhad
University of Medical Sciences, Mashhad, Iran. Email: ebrahimzadehf@mums.ac.ir
Drug-disease interactions of differentially
expressed genes in COVID-19 liver samples:
an in-silico analysis
Suzan Omar Rasool1, Ata Mirzaei Nahr2, Sania Eskandari3, Milad Hosseinzadeh4,
Soheila Asoudeh Moghanloo5 and Farnoosh Ebrahimzadeh6
1Department of Clinical Pharmacy, College of Pharmacy, University of Duhok, Kurdistan
Region, Iraq.
2School of Medical Sciences and Health Services, Tabriz University of Medical Sciences,
Tabriz, Iran.
3Department of Genetic, Tabriz Branch, Islamic Azad University, Tabriz, Iran.
4School of Medical Sciences and Health Services, Zabol University of Medical Sciences,
Zabol, Iran.
5Department of Genetic Enginering, Marvdasht Branch, Islamic Azad University,
Marvdasht.
6Department of Internal Medicine, Faculty of Medicine, Mashhad University of Medical
Sciences, Mashhad, Iran.
Key words: COVID-19; liver; cytochrome P450; gene expression.
Abstract. While COVID-19 liver injuries have been reported in various stud-
ies, concerns are raised about disease-drug reactions in COVID-19 patients. In
this study, we examined the hypothesis of gene-disease interactions in an in-silico
model of gene expression to seek changes in cytochrome P450 genes. The Gene
Expression Omnibus dataset of the liver autopsy in deceased COVID-19 patients
(GSE150316) was used in this study. Non-alcoholic fatty liver biopsies were used
as the control (GSE167523). Besides, gene expression analysis was performed us-
ing the DESeq/EdgeR method. The GO databases were used, and the paths were
set at p<0.05. The drug-gene interaction database (DGIdb) was searched for in-
teractions. According to the results, 5,147 genes were downregulated, and 5,122
genes were upregulated in SARS-CoV-2 compared to healthy livers. Compared
to the cytochromes, 34 cytochromes were downregulated, while 4 cytochromes
were upregulated among the detected differentially expressed genes (DEG).
The drug-gene interaction database (DGIdb) provided a list of medications with
potential interactions with COVID-19 as well as metacetamol, phenethyl iso-
cyanate, amodiaquine, spironolactone, amiloride, acenocoumarol, clopidogrel,
Drug disease interaction of genes in COVID-19 liver 317
Vol. 62(4): 316 - 324, 2021
Interacciones fármaco –enfermedad de genes diferencialmente
expresados en muestras de hígado de COVID-19:
un análisis in-silico.
Invest Clin 2021; 62 (4): 316-324
Palabras clave: COVID-19; hígado; citocromo P450; expresión génica.
Resumen. Mientras que se han informado sobre lesiones hepáticas por
COVID-19 en diversos estudios, las preocupaciones se elevan acerca de las re-
acciones enfermedad-fármaco en los pacientes con COVID-19. En este estudio,
investigamos la hipótesis de las interacciones gen-enfermedad en un modelo
in-silico de la expresión génica para buscar los cambios en los genes del citocro-
mo P450. En este estudio se utilizó el conjunto de datos Ómnibus de la Expre-
sión Génica de la autopsia hepática en los pacientes fallecidos por COVID-19
(GSE150316). Las biopsias de hígado graso no alcohólico se utilizaron como
controles (GSE167523). Además, el análisis de la expresión génica se realizó
mediante el método DESeq / EdgeR. Se utilizaron las bases de datos GO y las
rutas fueron ajustadas en p <0,05. La base de datos de la interacción fármaco-
gen (DGIdb) fue investigada para las interacciones. Según los resultados, 5.147
genes se regularon a la baja y 5.122 genes se regularon al alza en el SARS-CoV-2
en comparación con los hígados sanos. En comparación con los citocromos, 34
citocromos se regularon a la baja, mientras que 4 citocromos fueron regulados
al alza entre la expresión de los genes detectados diferencialmente (DEG). La
base de datos de la interacción fármaco-gen (DGIdb) proporcionó una lista
de medicamentos con las interacciones potenciales con COVID-19, así como
con metacetamol, fenetilo isocianato, amodiaquina, espironolactona, amilori-
da, acenocumarol, clopidogrel, fenprocoumon, trimipramina, fenazepam, etc.
También, los compuestos dietéticos de isoflavonas, valeriana y cumarina, así
como el metabolismo de la cafeína han mostrado tener posibles interacciones
con la enfermedad COVID-19. Nuestro estudio demostró que los niveles de la
expresión de los genes del citocromo P450 podrían quedar alterados siguiendo
COVID-19. Además, se recomienda utilizar una lista de fármaco-enfermedad
interacción para evaluar en las consideraciones clínicas en otros estudios adi-
cionales.
Received: 15-05-2021 Accepted: 06-07-2021
phenprocoumon, trimipramine, phenazepam, etc. Besides, dietary compounds of
isoflavones, valerian, and coumarin, as well as caffeine metabolism were shown to
have possible interactions with COVID-19 disease. Our study showed that expres-
sion levels of cytochrome P450 genes could get altered following COVID-19. In
addition, a drug-disease interaction list is recommended to be used for evalua-
tions in clinical considerations in further studies.
318 Rasool et al.
Investigación Clínica 62(4): 2021
INTRODUCTION
COVID-19 manifestations in the liver
have been recently reported. According to
available evidence, 2-11% of COVID-19 pa-
tients develop liver disease. In 14-53% of the
cases, abnormal levels of alanine aminotrans-
ferase (ALT) and aspartate aminotransferase
(AST) have been seen during progression of
the disease (1). In mild cases of COVID-19,
liver damage is often transient and can re-
turn to its normal state without any special
treatment. However, patients with severe CO-
VID-19 disease appear to have more severe
liver function disorders (2). Liver damage in
patients with SARS-CoV-2 infection could be
directly due to viral infection of liver cells (3)
and immune-mediated inflammations, such
as cytokine storm. In addition, liver damage
could be due to toxicity of prescribed medi-
cations for COVID-19 (4). In patients with
critical forms of COVID-19, it may lead to
liver failure (5, 6). Many concerns have been
raised about the possibility of significant dis-
ease-drug interactions in COVID-19 patients
through modulations of Cytochrome P450s,
as Ghiaty et al. reported (7). Human cyto-
chrome P450 enzymes are monooxygenases
playing a decisive role in the synthesis of
cholesterol, steroids, and other lipids, as well
as in detoxification and metabolism of drugs
and environmental chemicals. Any changes
in expression of the cytochrome P450 gene
or its post-transcriptional level might dys-
regulate its function (8). The cytochrome
P450 enzyme is responsible for metabolizing
a wide range of internal and external organic
compounds. Besides, many drug compounds
involved in treatment are substrates for this
enzyme. This study aims to examine the hy-
pothesis of gene-disease interactions in an
in-silico model of gene expressions to seek
changes in cytochrome P450 genes.
MATERIALS AND METHODS
We conducted a meta-analysis of Gene
Expression Omnibus (GEO) data on the livers
of COVID-19 patients. Datasets of COVID-19
patients were searched using the keywords
of “COVID-19”, “SARS-CoV-2”, and “new
Coronavirus” through a GEO search. The
GEO databases were chosen from 25 avail-
able sources based on the inclusion criterion
that was available gene expression data of the
livers of COVID-19 individuals. Based on the
similarities to the COVID-19 datasets chosen,
control datasets were quarried. Accordingly,
raw read counts (Illumina platforms) of liver
autopsy in deceased COVID-19 patients of
the GSE150316 GEO dataset were included
with three samples in this study. Besides,
GSE167523 samples of humans’ non-alco-
holic fatty liver disease were used as controls.
Gene expression analysis was performed
using the DESeq/EdgeR method, via iDEPR-
Shiny software (9). Lowly expressed genes
were excluded from the dataset through
data processing. Next, gene IDs were con-
verted to a similar format and data were log
transformed for PCA analysis. Besides, dif-
ferentially expressed genes (DEGs) were de-
tected using the DESeq2 package with the
false detection threshold of (FDR) < 0.1 and
a change equal and higher than 2.
To identify important biological pathways
based on common genes affected in the two
datasets, GO databases were used, with the
paths of p <0.05, according to hypergeomet-
ric analysis, having been reported as affected
paths. To identify biological pathways involved
in the studied disease, the drug-gene interac-
tion database (DGIdb) and GO were used. To
interpret the list of the genes based on GO
databases, hypergeometric statistic tests were
used to read the GO pathways and to build a
gene expression regulation network.
Drug disease interaction of genes in COVID-19 liver 319
Vol. 62(4): 316 - 324, 2021
RESULTS
Processing
A total of 26,364 genes were evalu-
ated in 10 samples with the settings of the
counts per million reads mapped (CPM) =
0.5. The difference between replicates in the
SARS-CoV-2 samples compared to healthy
livers showed a significant alteration to the
expression of hundreds of genes in SARS-
CoV-2 infected livers versus the control sam-
ples based on the analysis of the principal
components (PCA) that explained for 67% of
the variance difference between SARS-CoV-2
and control samples (Fig. 1A). Accordingly,
SARS-CoV-2 led to an extensive transcrip-
tional response in the liver (Fig. 1B).
Differentially expressed genes
Finally, 5,147 and 5,122 genes were
detected to have been downregulated and
upregulated, respectively, in SARS-CoV-2
compared to healthy livers (Fig. 2A). Next,
differentially expressed genes that were sig-
nificantly downregulated were subjected to
enrichment analysis based on the GO data-
base. The 10 most significant pathways in
both down- and up-regulated genes are list-
ed in Table I.
Drug-gene interactions
Cytochromes in the livers of COVID-19
patients were examined and quarried. Ac-
cording to the results, 34 cytochromes of CY-
P2E1, CYP3A4, CYP2C9, CYP1A2, CYP2C8,
CYP2A6, CYP4A11, CYP4F2, CYP4A22, CY-
P2C18, CYP8B1, CYP2A7, CYP4F3, CYP7A1,
CYP2C19, CYP2B6, CYP1A1, CYP2D7,
CYP4F11, CYP27A1, CYP3A43, CYP51A1,
CYP4F22, CYP4F12, CYP3A5, CYP26A1,
CYP39A1, CYP11A1, CYP4V2, CYP3A7,
CYP17A1, CYP3A7, CYP3A7-CYP3A51P, and
CYP21A2 were downregulated among the
detected DEGs (Table II). In contrast, 4 cy-
tochromes of CYP4B1, CYP2D6, CYP24A1,
and CYP4F29P were upregulated.
The drug-gene interaction database
(DGIdb) was quarried. As Table II shows,
drugs related to these cytochromes were
extracted. Besides, drug-gene interactions
with the interaction score of higher than 1
were included.
Fig. 1. (A) Principal components (PCA) analysis; (B) Heatmap diagram.
320 Rasool et al.
Investigación Clínica 62(4): 2021
Fig. 2. (A) Volcano plot of differentially expressed genes.
TABLE I
GO DATABASE PATHWAY ENRICHMENT.
Upregulated Downregulated
Number of Genes P-value Number
of Genes
Pathways P-value Number
of Genes
Anatomical structure
morphogenesis
6.3E-71 806 Small molecule
metabolic process
2.7E-155 973
Movement of cells or
subcellular component
1.3E-68 677 Organic acid
metabolic process
7.1E-109 617
Locomotion 1.4E-57 587 Carboxylic acid
metabolic process
7.1E-109 580
Circulatory system
development
2.3E-55 387 Oxoacid metabolic
process
1.6E-107 608
Biological adhesion 6.8E-54 505 Oxidation-reduction process 6.9E-104 552
Cell adhesion 2.1E-53 502 Catabolic process 9.4E-84 1049
Cell motility 2.1E-53 531 Organic substance
catabolic process
9.1E-79 900
Cell migration 3.8E-52 487 Small molecule
biosynthetic process
3.2E-76 386
Regulation of developmental
process
4E-52 754 Lipid metabolic
process
2.3E-75 643
Anatomical structure
formation involved in
morphogenesis
5.1E-51 393 Cellular catabolic
process
3.1E-75 918
Drug disease interaction of genes in COVID-19 liver 321
Vol. 62(4): 316 - 324, 2021
DISCUSSION
This study showed that the function of
the cytochrome P450 genes could get al-
tered following COVID-19. A comparison of
normal liver cells and SARS-CoV-2-infected
hepatic cells showed a decreased expres-
sion level of some of the cytochrome P450
genes. Detoxification is a phenomenon that
eliminates toxins from the body, which oc-
curs in two phases. Accordingly, phase 1 is
catalyzed by cytochrome p450. Products pro-
duced in phase 1 are mainly active oxygen
and compounds causing damage to organs.
These compounds are inactivated by phase
2 enzymes. More than 75% of detoxification
occurs in the liver; however, it occurs in the
intestinal mucosa in some cases.
According to Relats et al. (34), numer-
ous food products react with cytochrome
P450 enzyme-metabolized substances of DG-
Idb. Quarries also showed significant inter-
TABLE II
DRUG-GENE INTERACTIONS.
Symbol log2 Fold
Change
Adjusted
P-value
Drug name (Interaction Score) [reference]
CYP2E1 -16.15 1.70E-50 METACETAMOL (5.55) (10)
VALERIAN (2.77) (11)
PERFLUBRON(5.55)(12)
PHENETHYL ISOCYANATE(5.55)(13)
BRADANICLINE(1.39)(14)
ISOFLAVONE(1.85)(15)
CYP3A4 -13.89 4.04E-40 –
CYP2C9 -13.35 3.14E-35 –
CYP1A2 -12.71 2.62E-28 –
CYP2C8 -12.55 1.67E-45 AMODIAQUINE (2.36) (16-17)
CERIVASTATIN (1.77)(18-19)
CYP2A6 -11.84 1.01E-15 COUMARIN (4.21) (20)
CAFFEINE (4.08) (21)
LETROZOLE (9.57) (22)
3-FORMYLINDOLE (5.32) (23)
CHEMBL1770735 (5.32) (24)
IFOSFAMIDE (2.07) (25)
CYP4A11 -11.62 7.24E-39 SPIRONOLACTONE (1.68)[None found]
AMILORIDE (2.13)[None found]
CYP4F2 -10.97 2.68E-24 ACENOCOUMAROL (23.92) (26)
CLOPIDOGREL (1.2) [ None found]
PAFURAMIDINE MALEATE (7.97)[None found]
PHENPROCOUMON (3.42)(27)
CYP4B1 +10.32 9.33E-12 THALIDOMIDE (1.82) (28-29)
CYP2D6 +6.322 1.77E-03 SPARTEINE(1.84)(30)
CYP24A1 +6.25 2.58E-02 LUNACALCIPOL (12.76) [None found]
CHEMBL255088 (4.25) [None found]
TELAPREVIR (4.25) (31)
DEFERASIROX (3.83) (32)
CALCITRIOL (2.32) (33)
322 Rasool et al.
Investigación Clínica 62(4): 2021
actions with some nutrients, while its clini-
cal significance is ambiguous.
Our search at DGIdb showed possible
effects of COVID-19 on isoflavones, valerian,
coumarin, and caffeine metabolism. Most of
nutrients could be inhibitors of cytochromes.
Accordingly, they reduce metabolic activity
of the cytochrome P450 enzyme.
Medications listed in Table II were found
to have interactions with cytochrome P450 en-
zymes. However, these results require further
clinical research to confirm such interactions.
Our results support the idea of disease-drug in-
teractions in COVID-19 patients.
The most significant interactions were
found to be those of CYP4F2 with acenocou-
marol, with the interaction score of 23.92
followed by letrozole with the interaction
score of 9.57.
On the other hand, with the advent of CO-
VID-19, many people may seek herbal, supple-
mentary, or dietary treatments as there is no
definitive treatment for COVID-19 (11). Our
study found some consistency with the in-vivo
study of the Gurley et al. (11), which showed
interactions of the black cohosh and valerian
with human cytochromes of P450, 1A2, 2D6,
2E1, and 3A4/5 phenotypes.
Limitations of the study
While most similar control datasets
were in non-alcoholic fatty liver disease, the-
re could be some bias towards results of the
study as non-alcoholic fatty liver may have
different forms of gene expression with com-
pletely healthy samples. Besides, lots of con-
founding factors could be effective as results
of various studies show that genetic poly-
morphisms might affect the body’s response
to COVID-19 (35,36).
The present study was a comprehensi-
ve analysis of COVID-19 disease-gene inte-
ractions that could contribute to adverse
effects. The identified differentially expres-
sing genes in this study might contribute to
interactions with COVID-19 and present a
drug-disease-interaction list to be conside-
red for further realistic clinical research.
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