As one of the five internal organs of the human body, the liver is closely related to the body's normal metabolism, detoxification, blood coagulation, and other processes. The liver participates in the body's immunity, it is an indispensable important organ for maintaining the body's life. In the study of liver diseases, a suitable cell model is one of the important tools. However, due to the difficulties in obtaining conventional liver cells, high culture failure, and high cost of culture, the development of liver disease research has been limited. Therefore, liver cell lines with simple culture conditions and stable genetic backgrounds have become a new favorite in liver research. Huh-7 is one of the most common liver cancer line.
The Huh-7 cell line was established by
Nakabayshi H., and Sato, J. in 1982. It is a cancer cell line derived from a
highly differentiated hepatocyte derived from the liver tumor of a 57-year-old
Japanese man. Most Huh-7 cells show epithelial-like morphology and have a
chromosome number between 55 and 63. Moreover, these cells are highly
heterogeneous.
Hepatitis virus research: Huh-7 is highly
sensitive to the hepatitis C virus (HCV). So far, Huh-7 and its derived cell
lines are the only cell lines that can effectively replicate the hepatitis C
virus (HCV), so Huh-7 It is often used as a model for studying HCV. It can be
used to screen drug candidates against hepatitis C virus and develop new drugs
against hepatitis C virus.
2. Xenograft cell model: The HuH-7 cells
can be used as the CDX model of human hepatocellular carcinoma in a mouse model
that enables pre-clinical tumor growth inhibition studies targeting kinase
inhibitors (e.g. BZG-4000), FGFR4, anti-EGFRvIII antibodies and other novel
anti-tumor growth therapeutics (e.g. sorafenib, silibinin).
3. Drug research: HuH-7 cell line can be
applied to study the drug efficacy and metabolism of liver cancer drugs, and to
explore the molecular mechanism of drugs.
Applying CRISPR/Cas9 to knock out
Huh-7's key host factors for viral replication and exploring key genes for
coronavirus replication
CypA (cyclosporin A binding protein) is an
important host factor for replication of many RNA viruses. In addition, some
studies showed that the replication of some viruses depends on CypA to varying
degrees. These studies used different viruses, cell lines, and experimental
designs, making it hard to compare one to another. Scientists have discovered
the CypA dependence of three single-stranded sense RNA viruses that can
replicate in Huh-7 cells, namely equine arteritis virus (EAV), human
coronavirus (HCoV-229E) and Middle East respiratory syndrome coronavirus ( MERS-CoV).
They compared the replication of these viruses, which were in the same parent
Huh-7 cells or in the CypA gene knockout Huh-7 cells edited by CRISPR/Cas9
technology.
The sgRNAs targeting CypA, CypB, CypC, and
CypD were transferred into Huh-7 cells by nuclear transfection, and positive
cell pools were obtained after screening. Cyp KO Huh-7 cell pool was infected
with MERS-CoV (B), HCoV-229E (C), or EAV (D), with 0.01 MOI. The plaque method
was to determine virus production at 48h p.i. (B, C) or 32h p.i. (D). Among all
four CypKO cell pools, the titer of MERS-CoV and HCoV-229E remained unchanged
(B and C). After being infected in the Huh-7 CypA KO cell pool, the EAV virus
titer decreased by 2-logs but did not vary in other knockout cell pools. The
result proved that CypA did play an important role in the replication of EAV.
Since the Huh7 CypA-KO cell pool may have
low levels of CypA expression residue, which is still sufficient to support
normal levels of MERS-CoV and HCoV-229E replication. In this case, obtaining
Huh7 CypA-KO monoclonals would be necessary. Different clones were chosen for
target site amplification and sequencing verification, after which
CypA-knockout positive clones were selected. Both wild-type Huh-7 cells and
CypA-KO Huh-7 clones #1 and #2 were infected by MERS-CoV, HCoV-229E or EAV. In
these two CypA-KO cell clones, the inactivation of CypA expression
significantly reduced MERS-CoV replication (approximately 300%). Interestingly,
in these two clones, there was no effect on HCoV-229E lacking CypA (D).
However, for EAV, a ~3-log decrease in virus production (E) was observed, which
showed a 10-fold stronger inhibitory effect compared to the previous Huh-7
CypA-KO cell pool.
In summary, there was no difference in the
replication of MERS-CoV, HCoV-229E and EAV in the CypB-KO, CypC-KO or CypD-KO
cell pools, which indicated that the replication of these viruses does not
depend on CypB, CypC Or CypD in Huh-7 cells. However, similar to CypA, we
cannot rule out the possibility that a very small amount of Cyp is still
sufficient to support virus replication effectively. The knock-out of CypA
reduced EAV production by about 3-log, while the titers of MERS-CoV progeny decreased by about
3-fol, Also, HCoV-229E replication remained the same. This study showed that
the replication of different single-stranded sense RNA viruses has significant
differences in CypA dependence.
CRISPR/Cas9-mediated gene knockout and
point mutation in Huh-7 cell model facilitate the study of the impact of
different genetic differences on drug metabolism
In vitro studies of drug metabolism and
related gene mutations often use freshly isolated or frozen human/animal liver
cells; however, primary liver cells are probably not the best choice because
they require liver collection and are expensive. Additionally, primary liver
cells are not immortalized , which leads to large differences between different
kinds of the cells. In most cases, the cell lines are identical in genome.
Therefore, researchers developed a CRISPR/Cas9 modified human hepatocyte cell
line so as to continuously study the effects of genetic variation on drug
metabolism. To study the effects of CYP3A5 mutations on the metabolism of two
enzyme substrates, the sedative or anesthetic midazolam (MDZ) and the
immunosuppressant tacrolimus (Tac).
About 50% of oral drugs are metabolized by
CYP3A4 and CYP3A5, which are the most abundant in the liver have highly
variable expression. The loss of function of CYP3A5*3 (rs776746) allele is very
common among Caucasians. Tac has a comparatively lower metabolic rate than
those with CYP3A5*1 genotype. However, the CYP3A5*1 allele is abundant in
African Americans who have rapid metabolism of MDZ, Tac, and other drugs.
Therefore, CYP3A5 genotype is vital to determine the appropriate dose of drugs.
To present, no commercial liver cell line
has been diploid on chromosome 7 and can express CYP3A5*1. Huh-7 cell line can
convert substrate MDZ to its metabolite hydroxylated 1-OH-MDZ and 4-OH-MDZ
through CYP3A4 activity, though they are not effective in the metabolism of MDZ
because of their identity as homozygote to the CYP3A5*3 allele. Therefore, it
is necessary to develop a liver cell line that can simulate the rapid metabolic
process of drugs that are related to the CYP3A5*1 genotype.
The gRNA, Cas9 and ssODN were
co-transformed into Huh-7 cells by nuclear transfection method, followed by
monoclonal selection. Different clones were selected for target site
amplification and sequencing verification, while positive clones with gene
knockout were selected. By knocking out or point-mutating the splice junction
of the Exon-3B of CYP3A5*3, three CYP3A5*1 cell lines were obtained.
Compared with WT Huh-7, CYP3A5*1/*3sd (heterozygous KO),
CYP3A5*1/*1dd (homozygous KO) or CYP3A5*1/*3pm (point mutation) express
CYP3A5*1 mRNA, Both CYP3A5 mRNA and protein expression increased. Therefore,
through the CRISPR/Cas9 technology, the *3 genotype was successfully
transformed into the *1 genotype, thereby activating the expression of CYP3A5
in the Huh-7 cell line. This cell model can accelerate preclinical drug
development, save time and money, and more accurately predict drug metabolism,
pharmacokinetics, toxicity, and efficacy in different populations or genotypes.
Using CRISPR/Cas9 to knockin GFP to the
Nanog in Huh-7 cells, revealing the reasons for gender differences in the
incidence of hepatocellular carcinoma
Hepatocellular carcinoma (HCC) is a common
malignant tumor, and its morbidity has obvious gender differences ---- the
inclination to men. Studies have shown that the androgen/androgen receptor
signal axis is related to the incidence of various hormone-related tumors such
as prostate cancer and cervical cancer. As an important place for androgen
metabolism, the liver has a high level of androgen in its microenvironment.
Hepatocellular carcinoma seems to have a close relationship with the
androgen/androgen receptor signal axis.
Cancer Stem Cells (CSCs) are closely
related to the occurrence and metastasis of tumors. Their ability to
self-renewal and unlimited proliferation is a key factor in cancer development.
Studies have revealed that the pluripotency factor Nanog is involved in
maintaining the dryness of CSCs. However, it is unclear whether the
androgen/androgen receptor signal axis affects the dry maintenance of HCC cells
through Nanog-related pathways.
The researchers found that the expression
of the androgen receptor is very high in liver cancer tissues and is related to
Nanog. Subsequently, the endogenous Nanog of huh7 cells was labeled with GFP by
CRISPR/Cas9, which confirmed the co-localization of the androgen receptor and
Nanog in HCC cells. The gRNA, Cas9, and Donor were co-transformed into huh-7
cells by nuclear transfection, followed by drug screening and monoclonal
cultures selection. Different clones were chosen for target site amplification
and sequencing, after which positive clones with homozygous knock-in were
selected.
Through subsequent in vitro experiments,
the researchers proved that the signal axis can promote the stemness of HCC
cells, which would be achieved in a Nanog-dependent manner. By activating the
transcription, this effect can be blocked by androgens Or AR degradation
enhancer.
These studies show that the
androgen/androgen receptor signaling axis provides evidence for the inhibition
of this axis in HCC therapy by affecting the stemness of tumor cells, which
also offers a possible way for the suppression of axons in the treatment of
liver cancer.
CRISPR-U™ efficiently modify genes in
liver cell lines
CRISPR-U ™ is an exclusive technology
independently developed by Ubigene Bioscience for gene editing cell lines. By
optimizing gene editing vectors and processes, the efficiency in gene-cutting
and recombination of CRISPR-U ™ is 10 times higher than the conventional
CRISPR/Cas9 technology. We are capable of customizing genetically-modified (KO,
KI, and point mutation) liver cell lines as you desire and satisfying various needs
in gene editing.
References:
1. de Wilde A H,
Zevenhoven-Dobbe J C, Beugeling C, et al. Coronaviruses and arteriviruses
display striking differences in their cyclophilin A-dependence during
replication in cell culture[J]. Virology, 2018, 517: 148-156.
2. Dorr C R, Remmel
R P, Muthusamy A, et al. CRISPR/Cas9 genetic modification of CYP3A5* 3 in HuH-7
human hepatocyte cell line leads to cell lines with increased midazolam and
tacrolimus metabolism[J]. Drug Metabolism and Disposition, 2017, 45(8):
957-965.
3. Jiang L, Shan J,
Shen J, et al. Androgen/androgen receptor axis maintains and promotes cancer
cell stemness through direct activation of Nanog transcription in
hepatocellular carcinoma[J]. Oncotarget, 2016, 7(24): 36814.
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