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review article
Review
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pISSN- · eISSN-
https://doi.org/-/JCP-
Non-canonical vs. Canonical Functions of Heme
Oxygenase-1 in Cancer
Achanta Sri Venakata Jagadeesh1, Xizhu Fang2, Seong Hoon Kim2, Yanymee N. Guillen-Quispe3, Jie Zheng2,
Young-Joon Surh1,2, Su-Jung Kim3
1
Cancer Research Institute, Seoul National University, 2Research Institute of Pharmaceutical Sciences, College of Pharmacy,
Seoul National University, 3Department of Molecular Medicine and Biopharmaceutical Sciences, Graduate School of Convergence
Science and Technology, Seoul National University, Seoul, Korea
Heme oxygenase-1 (HO-1) is a critical stress-responsive enzyme that has antioxidant and anti-inflammatory functions. HO-1
catalyzes heme degradation, which gives rise to the formation of carbon monoxide (CO), biliverdin, and iron. The upregulation of
HO-1 under pathological conditions associated with cellular stress represents an important cytoprotective defense mechanism by
virtue of the anti-oxidant properties of the bilirubin and the anti-inflammatory effect of the CO produced. The same mechanism is
hijacked by premalignant and cancerous cells. In recent years, however, there has been accumulating evidence supporting that the
upregulation of HO-1 promotes cancer progression, independently of its catalytic activity. Such non-canonical functions of HO-1 are
associated with its interaction with other proteins, particularly transcription factors. HO-1 also undergoes post-translational modifications that influence its stability, functional activity, cellular translocation, etc. HO-1 is normally present in the endoplasmic reticulum,
but distinct subcellular localizations, especially in the nucleus, are observed in multiple cancers. The nuclear HO-1 modulates the
activation of various transcription factors, which does not appear to be mediated by carbon monoxide and iron. This commentary
summarizes the non-canonical functions of HO-1 in the context of cancer growth and progression and underlying regulatory mechanisms.
Key Words Heme oxygenase-1, Cancer, Protein-protein interaction, Post-translational modification
INTRODUCTION
Heme oxygenase-1 (HO-1) was first characterized in 1968
as a heme degradative enzyme by Tenhunen and colleagues
[1]. Later on, many studies investigated the inducers of
HO-1 such as heme, heavy metals, hydrogen peroxide, UV,
hyperthermia, hyperoxia, sulfhydryl reagents, inflammatory
cytokines, modified lipids, and growth factors [2-4]. The heme
degradation catalyzed by HO-1 gives rise to release of carbon monoxide, biliverdin, and iron. Carbon monoxide and
iron have anti-oxidant [5], anti-apoptotic [6], and anti-inflammatory activity [7].
Human HO-1 comprises 288 amino acids of which 22
hydrophobic residues are present in the C-terminus [8]. The
structure of HO-1 with its bound substrate, heme, has been
refined in a crystal form; the heme-binding pocket is formed
by two helices termed as proximal and distal helices [9]. In
general, HO-1 is anchored to smooth endoplasmic reticulum
through a C-terminal transmembrane domain, while the rest
of the molecule is cytoplasmic. Endoplasmic reticulum anchored HO-1 faces the cytosol [10,11]. Alternatively, induction
by heme and hypoxia promotes HO-1 translocation to plasma
membrane [12,13], nucleus [14], and mitochondria [15]. The
resistance to oxidative stress often observed in cancer cells
is, in part, attributable to the upregulation of HO-1. The HO-1
overexpression correlates with poor prognosis in several
malignancies. These include breast cancer [16], renal cancer [17], hepatocellular carcinoma [18], melanoma [19], and
pancreatic cancer [20]. The upregulation of HO-1 is associated with cancer cell growth, resistance to anticancer therapy
invasiveness, metastasis, angiogenesis, and metabolic reprogramming (Fig. 1).
Besides its canonical role in heme degradation as part of
cellular cytoprotection, HO-1 directly regulates the signaling
Received March 11, 2022, Revised March 23, 2022, Accepted March 23, 2022
Correspondence to Su-Jung Kim, E-mail:-, https://orcid.org/-
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright © 2022 Korean Society of Cancer Prevention
J Cancer Prev 27(1):7-15, March 30, 2022
Jagadeesh et al.
Biliverdin reductase
O2
NADPH
2+
Fe
HO-1
ROS
CO
Heme
2+
Fe
Sustaining
proliferative
signals
Biliverdin
Bilirubin
Evading growth
suppressors
Deregulating cellular
metabolism
Avoiding immune
destruction
Enabling
replicative
immortality
Resisting
cell death
Tumer promoting
inflammation
Genome instability
and mutation
Inducing
angionenesis
Activation of
invasion and
metastasis
molecules and events [21-23]. The overexpression of HO-1
in melanoma activates the B-Raf-extracellular signal-regulated kinases (ERK) pathway, thereby stimulating the proliferative signals [24]. HO-1 induces autophagy via the PI3K/AKT
signaling pathway, which contributes to pharmorubicin resistance in breast cancer cells [25]. HO-1 promotes the survival
signals in renal cancer cells by modulating apoptosis and autophagy regulating molecules [26]. Further, HO-1 induces the
epithelial-mesenchymal transition by upregulating expression
of metastatic marker genes, snail and twist in prostate cancer
[27]. This mini-review highlights the non-canonical functions
of HO-1 in the context of regulating redox balance and promoting cancer progression though a canonical mechanism is
also involved to some extent.
CANONICAL MECHANISM
Carbon monoxide
As one of the by-products of HO-1, carbon monoxide can
mediate various canonical signaling events involved in promoting tumorigenesis and contribute to poor prognosis in
various cancers [28]. Carbon monoxide is a diffusible gas
that regulates the synthesis of angiogenic mediators such as
VEGF, interleukin 8 (IL-8), and stromal cell-derived factor 1,
as shown in Figure 2 [29]. Carbon monoxide also functions
as a second messenger that activates soluble guanylyl cyclase followed by cyclic-GMP production, enhancing cellular
proliferation [28]. It also modulates the soluble p38 mito8
J Cancer Prev 27(1):7-15, March 30, 2022
Figure 1. Hallmarks of cancer modulated by heme oxygenase-1 (HO1). HO-1 degrades heme to produce
carbon monoxide, iron, and biliverdin.
Besides this canonical function, HO-1
is involved in manifestation of cancer
hallmarks. HO-1 activates a number of
oncogenic events involved in cancer
cell growth, survival, and progression.
ROS, reactive oxygen species.
A
Figure 2. Canonical functions of heme oxygenase-1 (HO-1). HO-1
catalyzes the breakdown of heme, resulting in the formation of carbon
monoxide (CO), iron, and biliverdin. CO stimulates VEGF production
which promotes angiogenesis. Iron promotes ferroptosis and may play
a role in cancer progression. IL-8, interleukin-8; SDF-1, stromal cell-derived factor.
gen-activated protein kinase (MAPKs), ERK, and c-Jun N-terminal kinase signaling pathways in cancer cells [28].
Iron
Iron is the only metallic by-product of heme degradation catalyzed by HO-1. Iron is essential for various biological process-
Non-canonical Functions of Heme Oxygenase-1
es such as oxygen transport, oxidative phosphorylation, DNA
biosynthesis, and xenobiotic metabolism [30]. Iron undergoes
transition between ferric (Fe3+) and ferrous (Fe2+) ion via oxidation-reduction reactions [30]. The ferrous iron is stored in
ferritin, and the ferritin-bound iron is degraded by autophagy.
The iron released during autophagy-mediated ferritin degradation induces ferroptosis [31].
Iron recycling and homeostasis are among the physiological functions of HO-1, but iron overproduction also plays a
role in pathological conditions. Intracellular iron levels are
maintained by ferroportin and transferrin receptor [32]. Excessive HO-1 expression decreases ferroportin 1 expression, or
increased transferrin receptor expression enhances the labile
iron pool, resulting in ferroptosis induction [32]. In the cytosol,
iron accumulates in the form of ferrous ion as a consequence
of heme degradation by HO-1. The ferrous ion reduces hydrogen peroxide to form hydroxyl radical (HO⋅) via the Fenton
reaction [33]. The increase in hydroxyl radical formation can
cause genomic instability, oxidative DNA damage, and destruction of other biomolecules. The induction of ferroptosis,
mitophagy, and ferritinophagy is attributable to overloaded
iron (Fig. 2) [34]. Ferroptosis is a regulated cell death primarily caused by iron-mediated oxidative damage to the cell
membrane [34]. Hemin and carbon monoxide releasing molecule (CORM), but not biliverdin or bilirubin, accelerate ferroptosis induced by Erastin [35]. Additionally, hemin and CORM
induce HO-1 expression and increase membranous lipid peroxidation in the presence of Erastin. Thus, HO-1 is required for
iron-dependent lipid peroxidation associated with ferroptosis
[35]. The excessive iron accumulated in mitochondria contributed to the proliferation, migration and invasion of osteosarcoma, as well as stimulation of the Warburg effect [36].
NON-CANONICAL MECHANISM
An emerging hypothesis suggests that the biological and cellular functions of HO-1 may in part relate to specific subcellular compartmentalization, and/or may transcend the catalytic
breakdown of heme, with certain effector functions that are
independent of its enzymatic reaction products [37].
Protein-protein interactions
The HO-1 protein was first crystallized in 1990 [9]. It contains
a heme-binding pocket at distal and proximal helices, and
C-terminus contains a hydrophobic tail that is essential for
membrane binding [38]. It also contains hydrophilic polar residues that regulate oncogenic signaling pathways. The protein-protein interactions were evaluated in clusters by mass
spectroscopy and bioinformatics tools.
The protein-protein interactions dictate stability [39], oligomerization [40], and subcellular localization [41] of HO-1 as
well as its functions. It is generally accepted that heat shock
proteins, functioning as chaperones for tumor antigens, elicit
tumor-specific adaptive immune responses [42]. CD91 is a
receptor for some heat shock proteins, including HSP70 and
GP96 [43]. Based on the HO-1 amino acid sequence homology with Hsp70, CD91 was suggested as a putative binding
partner of HO-1 [44]. The HO-1 sequence homology was
analyzed using Patch Dock molecular docking algorithm and
Fire Dock analysis against CD91 [23]. There are polar residues found in HO-1 including Glu63, Tyr78, Glu81, Glu82,
His84, Lys86, Glu90, Gln91, and Gln102 [23]. The polar residues found in CD91 are Arg571, Thr576, Thr536, Arg553,
Trp556, and Ser565 [23]. Hydrogen bond interactions are observed between Glu90 (HO-1) and Gly571 (CD91), between
Glu63 (HO-1) and Thr576 (CD91), and between Gln102 (HO1) and Thr536 (CD91). Furthermore, hydrophobic-hydrophobic interactions are observed between Tyr55, Val59 (HO1) and Val535 (CD91) [23]. Salt bridges are found between
Lys177 (HO-1) and Glu332 (CD91) [23].
Self-assembly to form dimers and higher oligomers is a
common phenomenon in many membrane proteins, such as
receptors, enzymes, neurotransmitter transporters, and ion
channels, in which oligomerization is crucial for their proper
cellular localization and function [40]. The stabilization of
HO-1 through oligomerization in the endoplasmic reticulum
was investigated [40]. HO-1 forms dimers/oligomers in the
endoplasmic reticulum, which was not observed with a truncated HO-1 lacking the C-terminal transmembrane sequence
(amino acids 266-285) [40]. As Trp 270 within the transmembrane sequence is conserved in vertebrate HO-1, it may contribute to a strong thermodynamic force in the interface and
plays a prime role in the oligomeric state of HO-1. By utilizing
a molecular modeling, Trp 270 was predicted as a potential
interfacial residue of transmembrane α-helices essential for
protein-protein interactions. The W270N mutation significantly reduced microsomal HO-1 catalytic activity [40]. The decreased Fluorescence Resonance Energy Transfer (FRET)
assay efficiency indicates that the W270N mutation appears
to disrupt the oligomeric state. These findings indicate that
oligomerization is critical for the HO-1 stability and function.
Cleavage of C-terminal transmembrane segment facilitates
the nuclear translocation of HO-1 and cancer progression. In
HeLa and H1299 cells, overexpression of a truncated HO-1
lacking the transmembrane sequence promoted proliferation,
migration, and invasion of these cancer cells [45]. Inhibiting
nuclear localization of truncated HO-1 abolished its tumorigenic effect [46]. In alveolar macrophages, the endoplasmic
resident HO-1 translocates to the plasma membrane and
binds to the caveolin scaffolding domain of caveolin [47].
The association of HO-1 with STAT3 in prostate cancer
hampers the nuclear localization of STAT3. Thus, HO-1 interaction inhibits the androgen receptor/STAT3 signaling pathway [48]. 14-3-3 family proteins interact with HO-1, thereby
enhancing its stability and activating the STAT3 signaling
pathway in hepatocellular carcinoma [39]. The cholesterol-induced hypoxia triggers the association of HO-1 with emopamil-binding protein and activates the AKT signaling pathway
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9
Jagadeesh et al.
[49]. The LNCaP prostate cancer cells express the truncated
28-kDa HO-1 that is predominantly localized in the nucleus
as a complex with nuclear factor-erythroid factor 2-related
factor 2 (Nrf2) [50]. Notably, nuclear HO-1 rescued Nrf2 from
glycogen synthase kinase 3 beta (GSK3β)-mediated degradation. Further, cells enriched with nuclear HO-1 exhibited a
significant increase in transcription of Nrf2 target genes, such
as NAD(P)H:quinone oxidoreductase and glucose 6-phosphate dehydrogenase [50]. Thus, the preferential activation
of cytoprotective mechanisms through stabilization of Nrf2 by
nuclear HO-1 confers long-term tolerance to oxidative injury
and cell survival of cancer as well as cells. HO-1 interacts
with glucocorticoid receptors, which is responsible for the
poor prognosis of prostate cancer [51]. The acetylation of
nuclear HO-1 by p300/CREB-binding protein (CBP) histone
acetyltransferase facilitates its interaction with Jun D, leading
to transcriptional activation of AP-1 [45]. The resulting acetylated HO-1 enhanced growth, migration, and invasiveness of
HeLa and H1299 cells, and xenograft tumor growth and metastasis [45].
Post-translational modification
The post-translational modifications represent the key covalent conjugation of proteins. Phosphorylation, acetylation, and
ubiquitination are the major post-translational modifications.
The principal post-translational modifications of HO-1 and
their functional significance are summarized below.
1) Phosphorylation
Phosphorylation is one of the most important post-translational modifications observed in diverse pathophysiologic
conditions. It regulates cancer signaling pathways by modulating the activity or stability of target proteins, their interaction
with other proteins, subcellular localization, etc. [52]. Based
on screening the proteomic data by mass spectrometry, the
serine 229 residue of HO-1 was found to be a putative site
phosphorylated by TANK binding kinase-1 [53]. Salinas et al.
[54] found Ser 188 as the potential site for phosphorylation of
HO-1 by AKT/PKB. The phosphorylation sites of HO-1 were
predicted by utilizing by in silico bioinformatic tools and public
databases such as the human protein database (https://www.
hprd.org/). There are about five sites of serine/threonine-proline phosphorylation (Table 1). HO-1 is likely to be phosphor-
ylated by diverse kinases including AKT, Src kinase, GSK3β,
casein kinase 1, ERK, and other MAPKs.
2) Acetylation
Acetylation is another important post-translational modification that regulates the various cellular processes. It influences
the protein dynamics such as protein folding, stability, and
localization [55]. The HO-1 acetylated by p300/CBP interacts
with Jun D at Lys 243 and induces AP-1 transcriptional activity [45]. To explore global acetylation of HO-1, we utilized
an algorithm Group-based Prediction System (GPS). We
evaluated the potent internal acetylation, using a computational approach called GPS-based prediction of acetylation
on internal lysines (PAIL). It evaluates the possible histone
acetyltransferases through a BLOSUM 64, amino acid substitution matrix. The algorithm compares the query sequence
to an experimental acetylation of a known peptide [56]. As a
result, we estimate that among the possible acetylated sites,
Lys 143 and Lys 149 are more potential acetylation sites of
HO-1 (Table 2). The residues were measured based on a
high score with a specific threshold (http://pail.biocuckoo.org/
online.php).
Table 2. The prediction of acetylated sites by GPS-PAIL database
Peptide
Position
Score
Threshold
DLSEALKEATKEV
ALKEATKVHTQA
VTRDGFKLVMASL
PEELHRKAALEQD
AMQRYVKRLHEVG
SGGQVLKKIAQKA
GGQVLKKIAQKAL
LKKIAQKALDLPS
ASATKFKQLTRSR
RVIEEAKTAFLLN
RQRASNKVQDSAP
VETPRGKPPLNTR
-
-
-
GPS, Group-based Prediction System; PAIL, prediction of
acetylation on internal lysines. K refers the site for Nε-lysine
acetylation. Higher score indicates the higher probability of
acetylation.
Table 1. The prediction of consensus phosphorylation of HO-1 using experimentally curated functional WW domains in phosphorylation
site data base
Position in query
protein
Sequence in query
protein
Corresponding motif described in the literature
Features of motif described in the literature
-
SP
SP
TP
TP
TP
[pS/pT]P
[pS/pT]P
[pS/pT]P
[pS/pT]P
[pS/pT]P
WW domain binding motif
WW domain binding motif
WW domain binding motif
WW domain binding motif
WW domain binding motif
HO-1, heme oxygenase-1; S, serine; T, threonine; P, proline; WW, proline rich short sequence.
10
J Cancer Prev 27(1):7-15, March 30, 2022
Non-canonical Functions of Heme Oxygenase-1
3) Ubiquitination
Ubiquitination is a universal post-translational modification,
mediated through ubiquitin conjugation at a specific lysine
residue of the target protein destined to be degraded by 28S
proteasomes. It regulates cellular processes such as DNA
repair, inflammation, and endocytosis [57]. Ubiquitination is a
critical post-translational modification for destabilizing a protein and regulating various cancer signaling pathways. The
translocation in renal carcinoma, chromosome 8 (TRC8), an
E3 ubiquitin ligase, interacts with HO-1 and ubiquitinates it,
and the lack of trc8 stabilizes HO-1 and elevates its expression, promoting the tumor progression [58]. We implemented
the Bayesian decision theory algorithm [59] to investigate
potential ubiquitinated residues of HO-1. As a result, it was
predicted that Lys 18, Lys 116, Lys 149, and Lys 153 might
be potential sites for ubiquitination of HO-1 (Table 3). This
computational prediction is useful to analyze more diligent
outcomes (http://bdmpub.biocuckoo.org/prediction.php).
Sub-cellular localization
HO-1 was initially purified as a 32-kDa microsomal protein
mainly found in the smooth endoplasmic reticulum. However, HO-1 can also translocate into the plasma membrane,
mitochondria, and nucleus under some stress conditions
[12,60,61]. Caveolin 1 is a scaffolding protein and the main
component of flask-shaped plasma membrane invaginations
called caveolae. HO-1 binds to caveolin 1, and thereby induces the polarization of M1 to M2 macrophages and downregulates IL-6 and other inflammatory cytokines [47]. The
mitochondrial translocation of HO-1 induces mitophagy and
promotes ferroptosis in breast cancer cells [32]. A 28-kDa
HO-1 protein with truncation of the C-terminal amino acids
lacking the membrane-bound domain was found in the nucleus [41,46].
Table 3. The prediction of ubiquitinated sites in HO-1 by BDT
algorithm
Peptide
Position
Score
Threshold
QDLSEALKEATKEVH
EALKEATKEVHTQAE
QVTRDGFKLVMASLY
FPEELHRKAALEQDL
PAMQRYVKRLHEVGR
LSGGQVLKKIAQKAL
SGGQVLKKIAQKALD
VLKKIAQKALDLPSS
PNIASATKFKQLYRS
QRVIEEAKTAFLLNI
LRQRASNKVQDSAPV
PVETPRGKPPLNTRS
-
-
-
HO-1, heme oxygenase-1; BDT, Bayesian decision theory; K:
Lysine residues potentially ubiquitinylated. Higher score indicates
the higher probability of ubiquitination.
1) Mitochondrial HO-1
Mitochondria is one of the key generators of reactive oxygen
species. HO-1 translocates to the mitochondria in a truncated
form. The mitochondrial HO-1 accumulates in the presence
of cellular stress such as smoking, oxidative stress, and hypoxia [15,60,62]. Mitochondrial HO-1 induces mitophagy and
ferroptosis in breast cancer cells treated with BAY117085, an
NF-κB inhibitor [32]. Mitochondrial HO-1 accumulation alters
mitochondrial protein profiles, regulates redox potential, and
promotes tumorigenesis [15].
2) Nuclear HO-1
HO-1 is prone to undergo intramembrane proteolysis which
facilitates its migration from the endoplasmic reticulum to
the nucleus to promote cancer growth and invasiveness regardless of its enzymatic activity [45]. The transmembrane
sequence region of HO-1 is located at the carboxyl end,
and HO-1 is subjected to proteolytic cleavage to produce a
truncated form that consists of 237 amino acids and 28 kDa
fragments [41]. Although bioinformatic analysis predicted a
monopartite nuclear localization sequence at position 111 and
a bipartite nuclear localization sequence at position 196 for
HO-1, it is unknown whether an importin-related mechanism
mediates nuclear HO-1 import [23]. On the other hand, a lysine-rich region is highly homologous to a nuclear export motif on the HO-1 protein, and its function establishes through
interaction with chromosomal maintenance region protein 1
[41].
While devoid of heme-degrading activity, nuclear HO-1 has
been considered as a regulator of nuclear transcription factors [37]. For instance, the HO-1 protein in the nucleus inhibits DNA binding activity of NF-κB while activating core-binding
protein (CBF), Brain-specific homeobox/POU domain protein
3, and AP-2 transcription factors [41]. Interestingly, depending
on the type of stimulus, truncated HO-1 can either protect or
kill cells. For example, both full-length HO-1 and truncated
HO-1 expression protect cells from death when exposed to
oxidative conditions [41].
Sacca et al. [61] reported that nuclear HO-1 might be involved in the development of prostate cancer. The truncated
HO-1 promotes autophagy, thereby inducing chemoresistance in Her2 targeted therapy [63]. The truncated HO-1
acetylated by p300/CBP in nucleus interacts with JunD and
stimulates AP-1 transcriptional activity in H1299 and HeLa
cells, promoting their growth and migration [45]. The expression and subcellular localization of HO-1 increased with tumor progression in a mouse model of squamous cell carcinoma and head and neck squamous cell carcinoma [64]. Taken
together, these findings suggest that aberrant HO-1 overexpression in head and neck squamous cell carcinoma and its
nuclear localization is associated with malignant progression.
Birrane et al. [65] have reported that cigarette smoke-induced
nuclear translocation of HO-1 promotes the secretion of
VEGF in prostate cancer cells.
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Jagadeesh et al.
The DNA G4 quadruplexes (G4) structures comprise the
members of helicase superfamilies such as SF1, Pif1, or SF2,
RecQ, Fanconi anemia group J protein, Bloom syndrome
protein, and Werner syndrome protein [66]. The G4 structures are key regulators of oncogenes and cancer driving
genes such as c-MYC , K-RAS , PDGF-A , and VEGF-A [67].
The nuclear HO-1 interacts with G4 structures, and thereby
promotes genome instability and DNA damage responses
[68]. The proximal ligation assay data verifies the interaction
between HO-1 and quadruplex DNA [68].
Clinical significance of HO-1
Nuclear HO-1 has been shown to be expressed aberrantly
in many cancers. HO-1 is localized in the nuclear compartment of metastatic prostate cancer but not in benign prostatic
hypertrophy [61]. Similarly, HO-1 immunoreactive protein is
detected in the nucleus of malignant head and neck cancer;
nuclear localization of HO-1 is associated with tumor progression of head and neck squamous cell carcinomas [64].
HO-1 bound to an Nrf2 immunoreactive fragment and altered cellular metabolism by preferentially inducing specific
Nrf2 downstream genes such as glucose-6-phosphate dehydrogenase. The LNCaP prostate cancer cells are constitutively enriched with the 28-kDa truncated form of HO-1 that
resides in the nucleus as a complex with Nrf2 [50]. Nuclear
HO-1 stabilizes Nrf2 by protecting it from GSK3β-mediated
degradation. As a result, it is associated with an increase in
resistance to glucose deprivation, implying a preference for
the hexose monophosphate shunt pathway [50]. The nuclear
retention and activation of Nrf2 induce transcriptional regulation of antioxidant enzymes and may enable a feed forward
adaptive reprogramming for recovery and a survival advantage of cancer cells under oxidative stress [50].
Though HO-1 overexpression plays a role in tumor progression, it also has an opposite function in some cancer
cells. STAT3 mediates the activation of the androgen receptor which is a key step in the development of prostate cancer.
Elguero et al. [48] demonstrated that the HO-1 protein could
interact with STAT3 and enhance the cytoplasmic retention of
this transcription factor, leading to repression of its transcriptional activity in prostate cancer cells. Given that STAT3 regulates cell proliferation, migration, and invasion via androgen
receptor signaling involved in inflammation and angiogenesis,
blockage of STAT3-androgen receptor axis by HO-1 through
direct interaction with STAT3 represents a novel function
for HO-1 in prostate cancer, beyond its conventional role in
heme degradation [48].
Another mechanism by which HO-1 modulates tumor
growth and progression may involve suppression of NF-κB
activation and subsequent transcription of angiogenic as well
as inflammatory genes, particularly those encoding VEGF,
HIF-1α, and α5β1 integrin [69]. These findings propose HO-1
as a novel modulator of the angiogenic switch in prostate
cancer [69]. So clinical application of HO-1 inhibitors or inducers/activators is controversial due to its dual functions in
proliferation and progression of cancer cells.
CONCLUSION AND FUTURE PERSPECTIVES
Carbon monoxide and iron accumulated during HO-1-mediated heme degradation play a pivotal role in signal transduction
in various malignancies. The upregulation of carbon monoxide production promotes angiogenesis in several cancers.
The iron mediates mitophagy, ferroptosis, and ferritinophagy,
that modulate cancer development and progression.
The non-canonical mechanisms underlying oncogen-
Heme
ROS
HO-1
Ac
JunD
HO-1
p300/
CBP
Figure 3. The non-canonical functions of heme oxygenase-1 (HO-1) involved in the cancer progression. HO-1 localizes in the smooth endoplasmic reticulum. However, HO-1 can also translocate into plasma membrane, mitochondria, and nucleus. HO-1 is cleaved by a proteolytic enzyme
and translocated into the nucleus with nuclear localization sequence. Truncated HO-1 interacts with G-quadruplex and enhances gene instability. The
truncated HO-1 acetylated by p300/CBP in the nucleus interacts with JunD and enhances tumor progression. ROS, reactive oxygen species; CO,
carbon monoxide; CBP, CREB-binding protein; TMS, transmembrane sequence; NLS, nuclear localization signal; Cav-1, Caveolin 1.
12
J Cancer Prev 27(1):7-15, March 30, 2022
Non-canonical Functions of Heme Oxygenase-1
ic functions of HO-1 include protein-protein interactions,
post-translational modifications, and sub-cellular localization
(Fig. 3). HO-1 binds to other proteins and activates signaling
pathways involved in growth, survival, migration, invasion,
and metastasis of cancer cells. The post-translational modification of HO-1, such as acetylation, ubiquitination, and phosphorylation, modulates the stability function, and sub-cellular
localization of this enzyme. The translocation of HO-1 into the
nucleus modulates activity of transcription factors and their
regulators involved in tumorigenesis.
We investigated potential residues for principal post-translational modifications of HO-1 by using in silico techniques.
The proteomics analysis can also facilitate prediction of putative sites for post-translational modification in HO-1. The
non-canonical mechanisms of HO-1 merit further investigations as a novel therapeutic target.
FUNDING
This research was supported by a Basic Science Research
Program (2021R1I1A1A-) and the BK21 FOUR Program -) from the National Research Foundation (NRF), Ministry of Science and ICT, Republic of Korea.
CONFLICTS OF INTEREST
5.
6.
7.
8.
9.
10.
11.
No potential conflicts of interest were disclosed.
ORCID
Achanta Sri Venakata Jagadeesh,
https://orcid.org/-
Xizhu Fang, https://orcid.org/-
Seong Hoon Kim, https://orcid.org/-
Yanymee N. Guillen-Quispe,
https://orcid.org/-
Jie Zheng, https://orcid.org/-
Young-Joon Surh, https://orcid.org/-
Su-Jung Kim, https://orcid.org/-
12.
13.
14.
15.
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